JNDA Journal of Nepal Dental Association Vol. 10, No. 2, July-December, 2009
Transcription
JNDA Journal of Nepal Dental Association Vol. 10, No. 2, July-December, 2009
This Journal is an open access journal and can be accessed in www.jnda.com.np Journal of Nepal Dental Association (JNDA) ISSN 2091-0142 Vol. 10, No. 2, July-December, 2009 JNDA Journal of Nepal Dental Association Vol. 10, No. 2, July-December, 2009, Pages 81-165 PDCH UCMS-CODS MBKDCH BPKIHS Dallu-15, Kathmandu Tel: 4270954 Mobile: 9841371770 (Niranjan), 9841489580 (Sanjeev) Remember us for Dental Equipments and Materials We deal in • 3M-ESPE, Dental Chairs & Equipments • Ortho materials, All kinds of Dental materials and Surgical Equipments ISSN 2091-0142 Vol. 10, No. 2, July-December, 2009 JNDA Journal of Nepal Dental Association Biannual Peer Reviewed Dental Journal Published by Supported by PDCH UCMS-CODS MBKDCH This Journal is an open access journal and can be accessed in www.jnda.com.np BPKIHS JNDA Journal of Nepal Dental Association EDITORIAL BOARD Chief Editor Dr. Siddharth Dixit Section Editors Dr. Suprabhat Shrestha, Orthodontics Dr. Rita Singh, Periodontics Dr. Bandana Koirala, Pedodontics Dr. Punam Basnet Dixit, Conservative Dentistry & Endodontics Dr. Jyotsna Rimal, Oral Medicine & Radiology Dr. Dipak Thapa, Prosthodontics & Maxillofacial Prosthetics Dr. Sudeep Acharya, Oral & Maxillofacial Surgery Dr. Ashish Shrestha, Community Dentistry Editorial Advisors Dr. Praveen Mishra, MOE Dr. Tri Ratna Manandhar, BPKIHS Dr. Basanta K Shrestha, IOM Dr. Surendra Man Shrestha, PDCH Dr. Binod Acharya, KDCH Dr. Pranay Khanal, MBKDCH Dr. Hemant Kumar Halwai, UCMS-CODS Dr. Lonim Prasai Dixit, NDA Dr. Sameer Aryal, NDA Managing Editor Dr. Shyam K Maharjan NDA EXECUTIVE COMMITTEE 20082010 President Dr. Suraj Ram Bhakta Mathema Vice President Dr. Sachin Agrawal General Secretary Dr. Lonim Prasai Dixit Treasurer Dr. Sameer Aryal Joint Secretary Dr. Niranjan Sharma Members Dr. Rima Shrestha Dr. Suraj Gurung Dr. Pravindra Adhikari Dr. Samriddhi Vaidya International Advisors Dr. Mohan Baliga, India Dr. Sagun Chengappa, Australia Dr. Sergei B Dmitrienko, Russia Publication Assistant Mr. Khagendra P Bhattarai E-mail: [email protected] [email protected] [email protected] Website: www.jnda.com.np Journal of Nepal Dental Association (JNDA) is published biannually and distributed by Nepal Dental Association (NDA). The statements or opinions expressed in this Journal are the personal views of authors and do not represent the official views of JNDA editorial board or NDA. Publication of an advertisement or other products mentioned in JNDA should not be construed as an endorsement of the product or the manufacturer’s claims. © Copyright by JNDA All rights reserved. Permission to reproduce any material published in this Journal should be obtained from the Chief Editor, JNDA. Publisher Nepal Dental Association Nagpokhari P.O. Box: 21506 Kathmandu, Nepal Tel: 977-1-2120450 E-mail:[email protected] Website: www.nda.org.np Printed at Hisi Offset Printers (P.) Ltd. Jamal, Setodurbar Phone: 977-1-4226416 E-mail: [email protected] Computer Layout Mr. Aman Shrestha E-mail: [email protected] Contents Vol. 10, No. 2, July-December, 2009 Editorial Systemic antibiotics and periodontal diseases 81-83 Singh R Original Articles Applicability of Bolton’s tooth size ratio for Nepalese population 84-87 Jaiswal AK, Paudel KR Comparative evaluation of dimensional accuracy of addition silicone and condensation silicone impression materials: An invitro study 88-96 Joshi PR, Bhat GS, Shenoy V Assessment of periodontal status of rural Nepalese population using the community periodontal index 97-104 Pradhan S, Bhat MK Spectrophotometric analysis of shade duplication of various recent ceramic system used for porcelain fused to a metal crown: An invitro study 105-109 Das DK , Dong CX, Singh SK, Roy J Dental arch length and arch symmetry analysis of Nepalese permanent dentition 110-114 Shrestha RM, Bhattarai P Co-relation between the pattern of impaction of mandibular third molars with their associated pathologies 115-118 Nyachhyon P, Mahat A Comparison of duration of orthodontic treatment with and without extraction among orthodontic patients 119-121 Bhattarai P, Shrestha RM, Mishra P Metronidazole for the prevention of dry socket after removal of impacted mandibular third molar in Nepalese patients 122-124 Pant N Case Notes Calcium hydroxide in management of large periapical lesion 125-127 Dixit PB, Acharya S, Prajapati I Goldenhar syndrome: A report of a rare case 128-130 Dali M, Chacko V, Rao A Use of toothbrush in maxillofacial surgery 131-132 Sagtani A, Sybil D Non surgical endodontic retreatment following surgical endodontic failure: A case report 133-136 Gautam S, Thapa A, Pai ARV, Kundabala M Pyogenic granuloma associated with bone loss: A case report 137-139 Singh VP, Nayak DG, Upoor AS Orthodontic mini implant: Versatile application for clinical enhancement 140-146 Xia CS, Ding Y, Kafle D Endodontic management of trumatized immature nonvital permanent anterior teeth: A case report 147-150 Pradhan RJ Review Articles The dental applications of titanium and its alloys: A review 151-157 Rodrigues S, Shenoy V, Shetty T, Jain N Management of obstructive sleep apnea using oral appliances: A Review (Part I) 158-161 Kavitha PR, P Vivek, Bhat S Management of obstructive sleep apnea using oral appliances: A Review (Part II) Kavitha PR, P Vivek, Bhat S JNDA Guidelines 162-165 Nepal Dental Associatio Association n and FDI celebrates World Oral Health Day o on n 12th September 2009 NDA welcomes all doctors to be a part of the 11th Annual Dental Conference held on 12th September 2009 at Hotel Hyatt Regency and Post Conference CDE by Professor James L Gutmann (Jointly organized by NDA and Dentsply Academy) on 13th September 2009 at Hotel Radisson, Kathmandu, Nepal Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 81-83 Editorial Systemic antibiotics and periodontal diseases Singh R Associate Professor, People’s Dental College & Hospital, Nayabazar position in both medicine and dentistry if used with care and prescribed appropriately. Dr. Robert Genco once made the profound statement that we were ‘at the end of the beginning of research into human periodontal diseases’ (13th International Congress on Periodontal Research, Osaka Japan, 1992). Despite huge advances in the last 18 years, we still remain at the end of the beginning, rather than at the beginning of the end. Although a tremendous amount of effort has been expended over the past 30 years to elicit the causative agents of periodontitis, rarely has a single bacterial species been directly linked to periodontal diseases as its single etiologic factor. Management of severe types of periodontitis should not rely solely on systemic antibiotics but upon a combination of mechanical debridement possibly in conjunction with surgery, subgingival administration of antiseptics by dental professionals and patients, patients’ oral hygiene efforts and effective and safe systemic antibiotics in certain cases. There is currently strong enough evidence to implicate three microorganisms as etiologic agents of periodontal diseases: A. actinomycetemcomitans, Porphyromonas gingivalis and Tannerella forsythia. Periodontitis can and does occur in the absence of any of the aforementioned three identifiable periodontal pathogens. Associative evidence has linked a number of different bacterial species with destructive disease like Prevotella intermedia, Fusobacterium nucleatum, Eikenella corrodens, Campylobacter rectus, Eubacterium nodatum, Peptostreptococcus micros, and various spirochetes. There is some recent evidence that implicates certain viral agents e.g. cytomegalovirus, Epstein–Barr virus, papillomavirus, and herpes simplex virus, may have a role in the initiation of periodontitis, most likely by affecting the host response to the bacterial challenge. Nevertheless, the primary host challenge and disease initiator continues to appear bacterial in nature. Mechanical debridement remains the cornerstone of periodontal treatment. This is an absolutely essential step in any form of periodontal therapy and is often sufficient to control the progress of periodontal disease in a majority of patients. However, for some patients, mechanical instrumentation of the infected area is not sufficient to control disease progression. Failure to obtain a favorable response may be due to inadequacy of the host’s immune response, the ability of the pathogen(s) to escape, either by invading gingival tissue or finding shelter in an unreachable site, limited access, instrument availability, operator skill, or a host of other possible factors. Nonsurgical scaling and root planing may remove subgingival Campylobacter rectus, but is frequently ineffective against Porphyromonas gingivalis, Prevotella intermedia, Bacteroides forsythus, staphylococci and enteric rods, and may not significantly reduce Actinobacillus actinomycetemcomitans1. Often, incorporation of an appropriate chemotherapeutic agent in conjunction with mechanical instrumentation provides an additional antimicrobial effect offering increased opportunity to control disease. Role of Systemic Antibiotics in Periodontal Diseases Systemic antibiotics enter the periodontal tissues and the periodontal pocket via serum and can affect organisms outside the reach of cleaning instruments or topical antiinfective chemotherapeutics. Systemic antibiotic therapy can also potentially suppress periodontal pathogens residing on the tongue or other oral surfaces, thereby delaying subgingival recolonization of pathogens2. Systemic antibiotics may even be required for eradication of periodontal infections by A. actinomycetemcomitans and other pathogens. Actively progressing periodontitis Antibiotics, defined, as naturally occurring or synthetic organic substances that, in low concentrations, inhibit or kill selective microorganisms, are particularly useful in combating severe periodontal infections. The wholesale misuse of these drugs has led to the emergence of resistant strains. Antibiotics are valuable and, in some instances, life saving drugs. They can only retain this 81 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 to conventional therapy6. However, due to its propensity for severe adverse effects, clindamycin-HCl should only be prescribed following culture and sensitivity testing. Many microorganisms continue to demonstrate sensitivity to tetracyclines, particular doxycycline and minocycline. The use of subantimicrobial doxycycline as an adjunct to mechanical instrumentation with or without the adjunctive use of an antibiotic should be a consideration. The inhibition of the inflammatory process and the downregulation of matrix metalloproteinases may provide a quicker return to periodontal health7. is virtually always associated with specific bacterial infections and often requires the adjunctive use of systemic antibiotic therapy. Single drug therapies with penicillins, tetracyclines, metronidazole or clindamycin have been used frequently in periodontal practice. However, since periodontitis lesions often harbor a mixture of pathogenic bacteria, drug combination therapies have gained increased importance3. Valuable combination therapies include metronidazole–amoxicillin for A. actinomycetemcomitans and various anaerobic periodontal infections and metronidazole–ciprofloxacin for mixed anaerobic and enteric rod/Pseudomonas periodontal infections. The tetracyclines have the additional advantage of inhibiting collagenases. Comprehensive treatment of periodontitis is very different from the treatment of most bacterial infections. It is important to realize that growth of bacteria in pure cultures is very foreign to the way that the vast majority of bacteria naturally grow. Growth of bacteria in the biofilm is very different than the growth of a single pure culture in a test tube or on an agar plate. The aggregation of bacteria in a biofilm impairs the diffusion or may even inactivate antimicrobial agents. High concentrations of the active ingredient are needed before a beneficial effect can be expected. Biofilm experiments indicate that the necessary minimum inhibitory concentrations of antimicrobial agents are at least 50 times (or even 210,000 times) higher than for bacteria growing under planktonic conditions8. There is no single periodontal therapeutic regimen that will provide a beneficial response for all patients. It is very unlikely that there ever will be. Prescription of systemic antibiotic therapy in periodontics should be based upon scientific data and not upon personal biases. Empirical antibiotic therapy may be used for periodontal diseases with known microbial causes, such as acute necrotizing ulcerative gingivitis, which is caused by anaerobic organisms and can be cured by metronidazole, and early localized aggressive periodontitis, mostly involving A. actinomycetemcomitans, which can be controlled or eradicated by systemic metronidazole–amoxicillin combination therapy. The evidence available suggests that disadvantages and safety aspects of systemic antimicrobial use in the management of periodontal diseases significantly outweigh the benefits. Antibiotic prescribing should be the exception rather than the rule and, in the majority of cases, only considered after conventional therapies have been unsuccessful. Recommendations for periodontal anti-infective therapy will undoubtedly be continually revised along with the development of even better understanding of the pathogenic periodontal microbiota and the availability of new and more effective drugs to control or possibly cure periodontal infections. Wherever microbiological testing is unavailable, metronidazole–amoxicillin combination therapy (250– 500 mg of each, three times daily for 8 days) may be a reasonable antibiotic first choice in periodontics. The metronidazole–amoxicillin combination is an appropriate choice in about 70% of advanced periodontitis patients4. However, the metronidazole–amoxicillin combination does not affect Pseudomonas or enteric gram-negative rods that inhabit approximately 14% of advanced periodontitis lesions. The combination of metronidazole and ciprofloxacin (500 mg of each, twice daily for 8 days) can cure anaerobic, enteric rod and A. actinomycetemcomitans periodontal infections and promote subgingival overgrowth of streptococci able to inhibit gram-negative pathogens5. References The evidence seems to favor the use of metronidazole/ amoxicillin. However, this is not a panacea for all patients. Metronidazole has a number of unpleasant side effects that are not well tolerated by some patients. Amoxicillin is definitely contraindicated in patients with penicillin hypersensitivities. Potentially pathogenic bacteria, such as E. corrodens, may be resistant to both metronidazole and amoxicillin. Other antibiotics clearly provide significant benefits for specific situations. ClindamycinHCl remains effective against classic gram-negative anaerobic rods associated with periodontitis refractory J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 82 1. Renvert S, Wikström M, Dahlén G, Slots J, Egelberg J. On the inability of root debridement and periodontal surgery to eliminate Actinobacillus actinomycetemcomitans from periodontal pockets. J Clin Periodontol 1990; 17: 351–5. 2. Edwardsson S, Bing M, Axtelius B, Lindberg B, Söderfeldt B, Attström R. The microbiota of periodontal pockets with different depths in therapy-resistant periodontitis. J Clin Periodontol 1999; 26: 143–52. 3. Slots J. Systemic antibiotics in periodontics (Am Acad Periodontol position paper). J Periodontol 1996; 67: 831–8. 4. MJAMP, van Winkelhoff AJ, Douqué NH, Steures RWR, de Graaff J. Microbiological and clinical effects of metronidazole and amoxicillin in Actinobacillus actinomycetemcomitans-associated periodontitis. A 2year evaluation. J Clin Periodontol 1994; 21: 107–12. 5. Slots J, Feik D, Rams TE. In vitro antimicrobial sensitivity of enteric rods and pseudomonads from advanced adult periodontitis. Oral Microbiol Immunol 1990; 5: 298–301. 6. Gordon J, Walker C, Lamster I, West T, Socransky S, Seiger M, Fasciano R. Efficacy of clindamycin hydrochloride in refractory periodontitis: 12-months results. J Periodontol 1985; 56 (Suppl.): 75–80. 83 7. McCulloch CAG, Birek P, Overall CM, Aitken S, Lee W, Kulkarni Randomized controlled trial of doxycycline in the prevention of recurrent periodontitis in high risk patients: antimicrobial activity and collagenase inhibition. J Clin Periodontol 1990; 17: 616–22. 8. Anwar H, Strap J, Costerton J. Establishment of aging biofilms: possible mechanism of bacterial resistance to antimicrobial therapy. Antimicrob Agents Chemother 1992; 36: 1347–51. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 84-87 Original Article Applicability of Bolton’s tooth size ratio for Nepalese population Jaiswal AK1, Paudel KR2 Lecturer, CODS, Universal College of Medical Sciences, Bhairahwa, 2Lecturer, Kathmandu Medical College & Teaching Hospital, Sinamangal, Kathmandu 1 Abstract Objectives: To test the applicability of Bolton’s method for use in Nepalese population and to compare the reliability of present values against those of most commonly used values. Materials and methods: The sample consisted of 60 Nepalese males and 60 females (total 120 subjects) aged between 17 to 23 years. Subjects without any previous orthodontic treatment, fully erupted permanent teeth, and with no dental anomalies were included in this study. The measurements of mesio-distal widths of teeth were made on dental cast using digital caliper. Sample t test was used whenever necessary and the mean, range, and standard deviation were calculated for the anterior ratio and overall ratio. The measured values were compared with Bolton’s original values. Results: The mean anterior “6” ratio for Nepalese subjects was found to be 79.46 with a standard deviation of 2.60. The values ranged from 68.75 to 89.17. The mean overall “12” ratio for Nepalese subjects was found to be 92.42 with a standard deviation of 1.80. The values ranged from 85.93 to 98.68. Conclusion: Mean anterior tooth width ratios between Nepalese male and female samples were statistically significant but mean overall tooth width ratios between Nepalese male and female were not statistically significant. These findings suggest that a large number of Nepalese subjects presenting for orthodontic treatment possess a Bolton’s tooth size discrepancy that may influence treatment goals and results. Key words: Tooth size ratio, Bolton’s analysis, Digital caliper Introduction Prediction of accurate space has prime role in diagnosis and treatment planning in Orthodontics. According to Proffit and Fields1, space analysis should be done accurately before any Orthodontic treatment. Tooth size discrepancy is defined as a disproportion among the sizes of individual teeth1. In order to achieve optimal occlusion, ideal intercuspation, normal overjet and overbite, maxillary to mandibular tooth width ratios must be proportional in size. Bolton2 in 1958 evaluated 55 cases with excellent occlusions and developed Bolton’s tooth size ratio for six anterior teeth and the overall ratio for twelve teeth. Since differences in tooth size have been reported with ethnic groups9-12, most of the practitioners now disagree to apply the methods developed from the different ethnic groups. The Bolton’s tooth size ratio develops from white population (Caucasians), so its reliability is still questionable when applied to different ethnic groups13,14. So, it’s necessary to test the applicability of Bolton’s tooth size ratio for Nepalese population to make accurate diagnosis and treatment planning. The objectives of the present study were to: Similarly many authors have evaluated factors associated with differences in the tooth width ratios. The relationship between malocclusion type and tooth size proportions has been reported3-8. 1. Determine the Bolton’s ratios for Nepalese subjects. 2. Determine the sexual differences in tooth size between Nepalese males and females. Correspondence Dr. Alok Kumar Jaiswal, Lecturer, CODS, Universal College of Medical Sciences, Bhairahwa E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 84 Maximum 10 pairs of casts were measured per day to avoid errors by eye fatigue. All measurements were done directly from unsoaped plaster models. Maximum mesiodistal width of each tooth was measured and recorded to 0.1mm. All measurements were taken perpendicular to the long axis of the tooth with the caliper beak entering the interproximal area from the buccal or occlusal side15. Repeated measurements were performed to minimize the possible errors. Intra-examiner reliability was predetermined at 0.2mm as mentioned by Bishara et al11. Bishara11,17 recommended that measurements that varied by 0.2mm or less to be averaged and remeasurement was done for measurements that varied more than 0.2 mm and the three measurements were averaged. 3. Compare the ethnic difference in tooth size between Nepalese and Caucasians. Materials and methods The samples for this study were collected from the CODS,Universal College of Medical Sciences,Bhairahwa, Nepal. A random sampling technique was used. The subjects were informed appropriately and informed consent was obtained. The samples included dental impressions obtained from the students of the dental and medical sciences. Total 120 subjects were selected (60 males and 60 females). In spite of the ethnic diversity in the Nepalese population, we considered there was low error in sample selection, because the students selected for medical studies came from different parts of Nepal. The mean, range, standard deviations were calculated for the size of teeth. The Bolton anterior ratio and the Bolton overall ratio were calculated and tabulated. Inclusion criteria were, native Nepalese with Nepalese phenotypical characteristics such as brown skin color, black hair and eye color ranging from brown to black, age ranging from 17-23 years and all permanent teeth erupted(except third molar). Exclusion criteria were subjects with proximal or occlusal wear, interproximal caries or restorations, crowding, spacing or diastema, any cross bite, any over retained deciduous tooth, missing permanent tooth, deep carious tooth, any hypoplasia or dental anomalies and any past history of orthodontic treatment15,16. Results The results are summarized in Table 1 to 3. Table 1 reports the mean, range, and standard deviation of the anterior and overall ratio in the Nepalese male and female subjects. Table 1 suggests there was significant difference between sexes for the anterior ratio (P=0.0089), but there was no significant difference for overall ratio (P= 0.88) The alginate impressions were made by the well trained dentists of CODS, Universal College of Medical Sciences, Bhairahwa, Nepal. The impressions were poured using dental plaster. Starrett digital caliper (0-150mm, 799A6/150, Starrett tools (Suzhou) Co. Ltd., China) providing measurements to ± 0.01mm was used to measure the mesio-distal dimension of all teeth. The teeth measured included the mandibular and maxillary permanent incisors, mandibular and maxillary permanent canines, mandibular and maxillary first and second premolars, mandibular and maxillary permanent first molars. All measurements were made by single investigator. The combined male and female anterior ratio and overall ratio were calculated and tabulated in Table 2. The mean anterior “6” ratio for Nepalese subjects was found to be 79.46 with a standard deviation of 2.60. The values ranged from 68.75 to 89.17. The mean overall “12” ratio for Nepalese subjects was found to be 92.42 with a standard deviation of 1.80. The values ranged from 85.93 to 98.68 (Table 3). Table 1: Tooth size ratio of male and female in the Nepalese population Ratio Male Range Female Mean SD Range Mean SD P Anterior Ratio 73.70 89.17 80.44 3.52 68.75 87.05 78.48 4.47 0.0089* Overall Ratio 85.93 98.68 92.46 2.72 86.60 97.54 92.38 2.89 0.8808 SD, Standard deviation; *significant P value (P <0.05) Table 2: Tooth size ratio male and female combined for Nepalese population Mean SD Anterior Ratio Ratio 68.75 Range 89.17 79.46 2.60 Overall Ratio 85.93 98.68 92.42 1.80 85 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Table 3: Parameters obtained in the present study compared to the Bolton parameters Ratio Range Nepalese Mean Caucasian SD Nepalese Caucasian Nepalese Caucasian Anterior Ratio 68.75 89.17 74.5 80.4 79.46 77.2 2.60 1.65 Overall Ratio 85.93 98.68 87.5 94.8 92.42 91.3 1.80 1.91 Discussion The Bolton sample was obtained from 55 subjects with excellent occlusion; 44 were orthodontically treated2. In present sample, all subjects were untreated and some had mild malocclusions. Therefore, a direct statistical comparison between groups is disputable. Nepalese population. Although such an analysis may appear to be time consuming, the benefits would seem to outweigh this minor inconvenience by allowing more efficient diagnosis of problems, more specific treatment planning, and good success rate in achieving optimal occlusions. Although in some studies the reported differences with Bolton’s ratios were statistically significant, the clinical relevance is questionable. Originally, Bolton2 suggested that a ratio greater than 1 SD from his reported mean values indicated a need for diagnostic consideration. More recently, a clinically significant tooth width ratio discrepancy has generally been defined as 2 SD outside Bolton’s published mean ratio3,4,12. Limitations Further studies based on larger sample size, are required to confirm the applicability of the results of the present study. Further study is required to test the applicability of Bolton values on Nepalese population having different types of Angle’s malocclusion. By using the above definition, an anterior ratio below 73.9 or above 80.5 and overall ratio below 87.5 or above 95.1 would be considered as clinically significant. High prevalence rate of an anterior tooth size discrepancy more than 2 SD above Bolton’s mean was found for Nepalese subjects (Table 3). Although the mean values of Nepalese subjects in this study and those of the Bolton study are nearly same, the ranges and standard deviations of the Nepalese subjects significantly larger. Similar findings were found by Crosby and Alexander3. Acknowledgments I would like to thank Prof. Dr. J. N. Sinha for his kindness and support and Dr. Rahul, Dr. Reshu, Dr. Rama, Dr. Bikash and Dr. Barsha who helped me with the sample collection. References If cases with ratios greater than 2 SD away from Bolton’s values truly represent a significant discrepancy, then a large number of Nepalese subjects present with relative tooth sizes that could potentially cause problems in attaining an optimal occlusal relationship. Conclusions Mean anterior tooth width ratios between male and female samples were statistically significant but mean overall tooth width ratios between male and female were not statistically significant. These findings suggest that a large number of Nepalese subjects presenting for orthodontic treatment possess a Bolton’s tooth size discrepancy that may influence treatment goals and results. In both the overall ratios and the anterior ratio, the range and standard deviation were varied in the present study than in Bolton’s study. Thus it is probably necessary to do precise space analysis based on our own data to make an accurate diagnosis and treatment plan for orthodontics in J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 86 1. Proffit W. Contemporary Orthodontics.4th ed. St. Louis: Mosby; 2007. p.195-201. 2. Bolton A. Disharmony in tooth size and its relation to the analysis and treatment of malocclusion. Angle Orthod. 1958; 28:113–30. 3. Crosby DR, Alexander CG. The occurrence of tooth size discrepancies among different malocclusion groups. Am J Orthod Dentofacial Orthop. 1989; 95:457–61. 4. Freeman JE, Maskeroni AJ, Lorton L. Frequency of Bolton tooth-size discrepancies among orthodontic patients. Am J Orthod Dentofacial Orthop 1996;110:24-7. 5. Lavelle CL. Maxillary and mandibular tooth size in different racial groups and in different occlusal categories. Am J Orthod 1972; 61:29-37. 6. Arya BS, Savara BS, Thomas D, Clarkson Q. Relation of sex and occlusion to mesiodistal tooth size. Am J Orthod 1974; 66:479-86. 7. Doris JM, Bernard BW, Kuftinec MM, Stom D. A biometric study of tooth size and dental crowding. Am J Orthod 1981;79: 326-36. 8. Ta TA, Ling JY, Hagg U. Tooth-size discrepancies among different occlusion groups of southern Chinese children. Am J Orthod Dentofacial Orthop 2001;120:556-8. 9. Buschang PH, Demirjian A, Cadotte L. Permanent mesiodistal tooth size of French-Canadians. J Can Dent Assoc 1988;54:441-4. 13. Tong H, Chen D, Xu L, Liu P. The effect of premolar extractions on tooth size discrepancies. Angle Orthod 2004;74:508–11. 10. Smith SS, Buschang PH, Watanabe E. Inter-arch tooth size relationships of 3 populations: “does Bolton’s analysis apply?.” Am J Orthod Dentofacial Orthop 2000; 117:16974. 14. Al-Khateeb SN, Abu Alhaija ES. Tooth size discrepancies and arch parameters among different malocclusions in a Jordanian sample. Angle Orthod 2006;76:459–65. 15. 11. Bishara SE, Jakobsen JR, Abdallah EM, Fernandez Garcia A. Comparisons of mesiodistal and buccolingual crown dimensions of the permanent teeth in three populations from Egypt, Mexico, and the United States. Am J Orthod Dentofacial Orthop 1989;96:416-22. Legovic M, Novosel A, Legovic A. Regression equations for determining mesio-distal crown diameters of canines and premolars. Angle Orthod. 2003;73:3:314–8. 16. Bernabé E, Flores-Mir C. Are the lower incisors the best predictors for the unerupted canine and premolars sums? An analysis of a Peruvian sample. Angle Orthod. 2005; 75:202-7. 17. Bishara SE, Fernandez Garcia A, Jakobsen JR, Fahl JA. Mesio-distal crown dimensions in Mexico and the United States. Angle Orthod. 1986;56:315-23. 12. Santoro M, Ayoub ME, Pardi VA, Cangialosi TJ. Mesiodistal crown dimensions and tooth size discrepancy of the permanent dentition of Dominican Americans. Angle Orthod 2000;70:303-7. 87 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 88-96 Original Article Comparative evaluation of dimensional accuracy of addition silicone and condensation silicone impression materials: An invitro study Joshi PR1, Bhat GS2, Shenoy V3 1 Prosthodontist, Nepal Police Hospital, Kathmandu, 2Principal, Vyas Dental College, Jodhpur, India, 3Professor and HOD, Department of Prosthodontics and Maxillofacial Prosthetics, Manipal College of Dental Sciences, Karnataka, India. Abstract Background: Amongst the silicone impression materials, the addition silicones are superior in accuracy and dimensional stability. These days a wide range of condensation silicones are marketed with claims of equally good results as addition silicones. Aims and objectives: To evaluate and compare the time dependent dimensional accuracy and stability of addition silicone and condensation silicone impression materials. Materials and methods: Two addition-cured silicones (Reprosil, Dentsply/ Caulk, USA and Express XT, 3M ESPE, Germany) and two condensation-cured silicones (Speedex, Coltene Whaledent, USA and Zetaplus, Zhermack, Italy) were evaluated. A stainless steel master die simulating a three unit fixed partial denture preparation was fabricated. For each brand of the impression material, 6 impressions were made and cast poured immediately. The impressions were repeatedly poured at 1 h, 24 h, 48 h and 16 8 h. Interpreparation dimension and occlusogingival dimension were measured in the recovered stone dies (Type IV, Kalrock) using a travelling microscope calibrated to an accuracy of 0.001 cm. Results: i) the addition silicone impression materials were superior in accuracy and dimensional stability in comparison to condensation silicone; ii) at 1 hour of pour, all the materials tested seemed to have comparable accuracy and dimensional stability; iii) the gypsum dies produced from the successive pours of all the tested impression materials were generally larger in interpreparation distance and smaller in occlusogingival dimension than the stainless steel master die, with the addition silicone demonstrating the smallest change. Conclusion: The addition silicones have better dimensional accuracy and stability than condensation silicones. An impression made from condensation silicone should be poured as soon as possible. Key words: Accuracy, Addition silicone, Condensation silicone, Impression materials Introduction Accurate replication of tooth preparations and their arch positions require impression materials that exhibit good dimensional stability1. Nonaqueous elastomeric impression materials, or elastomers, were developed as an alternative to natural rubber during World War II. There are currently four basic types of elastomeric impression materials in use in the dental profession: (1) polysulfide, (2) condensation polymerizing silicone, (3) addition polymerizing silicone and (4) polyether. a longer period of time. Other disadvantages of the polysulfides include the need to use custom-made rather than stock trays due to a greater chance of distortion, a bad odor, a tendency to run down the patient’s throat due to lower viscosity and the lead dioxide materials that stain clothing. The polyether being hydrophilic absorbs water or fluids. It is a rigid material with high modulus of elasticity which makes it extremely difficult to remove from undercut areas. High cost, short working and setting time and high stiffness after setting limit their use2. The polysulfides are good in surface detail reproduction but they are dimensionally unstable when stored for Polyvinyl siloxanes are highly accurate, have little dimensional change after setting, moderately short Correspondence Dr. Pramod Raj Joshi, Nepal Police Hospital, Maharajgunj, Kathmandu, Nepal E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 88 distance of 1.947 cm and ii) occlusogingival dimension (height) of 0.794 cm. working and setting time and excellent recovery from deformation on removal3,4,4,5,6,7. The addition silicones have overcome the disadvantage of polymerization shrinkage over the condensation silicone as there is no by-product release3, condensation silicone has high polymerization shrinkage because of the release of alcohol by-product2. Loss of the by-product leads to measurable weight loss accompanied by shrinkage of the impression material on storage8. However, these days, a wide range of condensation silicones are marketed with claims of equally good results as addition silicones. In addition, various brands of condensation silicones available in the market are economically feasible in comparison to addition silicones. Standard 2 mm thick stainless steel copings were fabricated for each abutment with the purpose of producing uniform space for wash materials in putty impressions. For the purpose of impression making, perforated stainless steel custom trays were fabricated (Fig. 3). The tray was fabricated in such a way that the edges of the tray fitted into the 2 mm deep orientation ledges placed on the platform. In this way, the tray could be repeatedly and consistently seated in a self limiting way each time an impression was made so that there was approximately 7.0 mm clearance between its inner surface and the abutments. Accuracy of impressions with repeated pours is of interest clinically, because duplicate models are sometimes desired. The dimensions of a model from a second pour can be affected by continuing polymerization of impression material and/by distortion of the impression with removal of the first model9. The contribution of the impression materials to a successful fixed partial denture can be increased by selecting a material which is stable enough to produce accurate casts from repetitive pours of a single impression. ADA Specification Number 19 recommends a maximum negative change in dimension of 0.5% after a minimum of 24 h10. In this study, a total of four elastomeric impression materials were evaluated: two brands of addition silicones (Reprosil, Dentsply/ Caulk, USA and Express XT, 3M ESPE, Germany) and two brands of condensation silicones (Speedex, Coltene Whaledent, USA and Zetaplus, Zhermack, Italy). All the materials, which were commercially available and recommended for use in making fixed partial denture impression, were stored at manufacturers’ recommended temperatures before use and were mixed at room temperature and humidity so as to simulate their clinical use. A two step putty-wash impression technique was used for making impression of the metal die using all the four types of impression materials (Table 1). The tray adhesive supplied by the manufacturer was evenly applied over the inner surface of the tray and extended approximately 2 mm on the outer surface along the periphery. To allow space for the wash thickness, 2 mm stainless steel spacer was placed on the abutments before making putty impression. Putty (base and catalyst) was mixed according to the manufacturers’ recommended proportions, loaded into the tray and the tray seated over the stainless steel die as guided by the alignment ledges until firm contact was made, indicating that seating had occurred to the predetermined degree. All the materials were hand mixed, to get a homogenous mix, at room temperature and placed within the working time recommended by the manufacturer. After seating the tray, the impression was held with gentle finger pressure on the stainless steel master die for twice the indicated setting time to assure complete polymerization at room temperature. After the putty impression had completely set, impression was removed vertically. Metal spacers were carefully removed and the impressions were examined. The primary purpose of this study was to evaluate and compare the dimensional accuracy and stability of addition silicone and condensation silicone on repeated pours of single impression at various time intervals, viz, immediately, one hour, 24 hours, 48 hours and one week (168 h) after making the impression. The quantitative method was accomplished by microscopically measuring two critical dimensions of each stone die: (1) The interpreparation dimension (IP) and (2) the occlusogingival dimension (height) of the larger abutment (posterior). Materials and methods A machined standard stainless steel die preparation with specific dimensions (Figs. 1 & 2) was made so as to simulate a three-unit fixed partial denture situation replacing a mandibular first molar. Two dimensions, the interpreparation dimension and the occlusogingival dimension were measured on the master die and stone dies. In order to assess the linear change in the interpreparation distance, cross-grooves were prepared on the occlusal surfaces of the abutments as reference points. In the molar abutment, a vertical line which was used for assessing the vertical change in occlusogingival direction, was inscribed along the occlusogingival direction joining two circumferential lines which were 1 mm from the occlusal surface and 0.5 mm from the base. The measurements of the reference lines on the stainless steel master die were recorded as: i) interpreparation After removal and allowing for a short period of elastic recovery, light body material was introduced into the prespaced putty impression. Express XT Light Body impression material was available in automix syringe 89 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 tips and was dispensed using an automixing device. For Reprosil Light Body, equal quantity of base and catalyst paste were dispensed directly from the tubes on clean glass slab according to the manufacturers’ instruction and mixed with clean stainless steel spatula and the application was done with an impression syringe. For both the brands of condensation silicones, equal strand lengths of base material and activator were dispensed directly from the tubes on a clean glass slab according to the manufacturers’ instruction and mixed with a clean stainless steel spatula and the application was done with an impression syringe. The impression was re-seated to the predetermined position and held with gentle finger pressure for an adequate amount of time to ensure that setting reaction was complete before removal. Since the reaction took place in room temperature, which was lower than the mouth temperature, the tray was held in place for a longer duration than the manufacturers’ recommendation to ensure complete polymerization. After that, the impression was removed with straight pull directed along the path of withdrawal of the preparations. The impression was checked and impression with voids and other inaccuracies were discarded. and a mean was recorded for a particular dimension. To eliminate individual variability, all measurements were made by the same individual. A positioning device was made so that the measurement made for occlusogingival dimension on the stainless steel die and the stone dies could be reproduced. The accuracy of casts was expressed as percentage deviation from the standard die values. The difference between the mean of the stone cast (msc) and the mean of the stainless steel die (msd) divided by the mean of the stainless steel die multiplied by 100 was expressed as the percentage deviation from the stainless steel die for each impression material at each measurement location. Percentage deviation = Results The mean (in cm) and standard deviation of interpreparation and occlusogingival measurements for silicone impression materials tested at various time are listed in Table 2. In this Table, the relative accuracies of first and second pours (0 h and 1 h) for the materials tested are depicted for interpreparation measurement. For all the tested materials, occlusogingival dimension is relatively stable at 0 h. The interpreparation distance, generally, increased for most stone dies compared with the stainless steel master die for all the tested materials. Occlusogingival dimension decreased for most of the materials compared with the stainless steel die. Graphic results of comparison of mean interpreparation and occlusogingival measurements for all materials tested with the master die are shown in Figs. 6 & 7. To prepare die stone casts, a ratio of 23 ml water to 100 gm die stone (Type IV, Kalrock) was used. It was first mixed by hand to incorporate the water and then mechanically mixed under vacuum for 15 sec. The mixture was placed into the impression from one end in small increments with a small instrument until it completely filled the tray. While pouring, the impression was kept on a vibrator to avoid any air bubble entrapment. For each brand of addition silicone as well as condensation silicone, six impressions were made giving a total of 24 impressions. All the impressions were poured with high strength dental stone immediately after the impressions were obtained. After 45 minutes when the stone cast was completely set, a total of 24 casts were recovered. Likewise, the impressions were poured successively at 1 hour, 24 hours, 48 hours and 1 week (168 h) after the impressions were made and thus altogether 120 casts were made. Any cast which showed voids and other inaccuracies were discarded and replaced. All the casts were labeled with the first letter of the brand name coding the brand of the material. Roman numbers coded the sample number and Arabic numbers coded the pouring time (Fig. 4). Effects of time of pouring are shown in Table 3. There was no statistically significant difference in mean percentage change at each measurement (interpreparation and occlusogingival) for all the materials at 0 h, 1 h, 24 h and 48 h. Results of Kruskal Wallis Test indicated statistically significant change at 168 h (p<0.05) at both the dimensions for the materials tested. Graphic results are presented in Figs. 8 & 9 as percentage change of each measurement at various time intervals between the materials tested. Table 4 shows mean and standard deviation of interpreparation and occlusogingival measurements between various time intervals for silicone impression materials tested. Regarding interpreparation distance, statistically significant differences were recorded between 0-1 hour for Express XT (p<0.05). Likewise, at interpreparation distance, statistically significant differences were recorded for Speedex and Zetaplus between 48 h to 168 h (p<0.05). Regarding occlusogingival dimension, statistically significant change was recorded for Zetaplus during 48 h to 168 h (p<0.05). Before measurements were obtained, the casts were allowed to air dry for at least 48 hours and were carefully observed to verify the proper replication of the reference lines. The dental stone casts at the measurement locations were each measured with a travelling microscope (Parco) capable of measuring to 0.001 cm (Fig. 5). Each measurement of the stone dies was repeated three times to ensure its reproducibility J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 msc - msd x 100 msd 90 m1 m2 PM m4 M m3 m7 m5 m6 Fig 1: Stainless steel die with spacer m1 m2 m3 m4 = = = = Fig 2: Diagram of stainless steel die with reference marks interpreparation distance occlusogingival distance (height) distance between abutment preparation (10.5 mm) occlusogingical dimesion of each died (9.5 mm) m5 m6 m7 M Fig 4: Stone dies gingival diameter of molar die (10.5 mm) gingival diameter of premolar die (7.5 mm) plateform thickness (5 mm) molar abutment, PM = premolar abutment Fig. 5: Travelling Microscope 1.970 0.800 1.965 0.795 1.960 Reprosil 1.955 Height mean IP mean = = = = Fig 3: Impression Trays and Final Impressions Express XT 1.950 Speedex 1.945 Zetaplus 1.940 0.790 Reprosil Express XT 0.785 Speedex Zetaplus 0.780 0.775 1.935 0.770 1.930 0 hr 1 hr 24 hrs 48 hrs 168 hrs Master model 0 hr Fig 6: Comparison of mean interpreparation (IP) distance of addition silicone and condensation impression materials with master die 1 hr 24 hrs 48 hrs 168 hrs Master model Fig 7: Comparison of mean occlusogingival dimension (height) of addition silicone and condensation impression materials with master die 0.50000 1.20000 1.00000 0.00000 0.60000 % Change % Change 0.80000 Reprosil Express XT 0.40000 Speedex 0.20000 -1.00000 Zetaplus 0.00000 -0.20000 HR HR HR -0.50000 0 hr 1 hr Reprosil 24 hr 48 hr Express XT 168 hr Speedex Zetaplus -1.50000 HR HR -2.00000 -0.40000 Fig 8: Comparison of mean percentage deviation of interpreparation distance at different time intervals between materials tested Fig 9: Comparison of mean percentage deviation of occlusogingival distance (height) at different time intervals between materials tested 91 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Table 1: The details of the products involved in the study Serial No. 1. Materials Express XT Putty Soft Type Manufacturer Batch No. Addition silicone 3M ESPE, Germany P060626C, P060626B 3M ESPE, Germany B263227, C264787 Dentsply/ Caulk, USA 060818 Dentsply/ Caulk, USA 060914 Express XT Light Body 2. Reprosil Putty Addition silicone Reprosil Light Body 3. Speedex Putty Base Condensation silicone Speedex Light Body 4. Zetaplus (Putty) Condensation silicone Oranwash L (Light body) Coltene Whaledent, USA NI675 Coltene Whaledent, USA 0074657 Zhermack, Italy 34522 Zhermack, Italy 34467 Table 2: Mean and standard deviation of interpreparation distance and occlusogingival dimension (height) between silicone impression materials tested. Time (h) 0 1 24 48 168 Product N Interpreparation distance Mean Std. Deviation (cm) 1.945 .002 Occlusogingival dimension (Height) Mean Std. Deviation (cm) .793 .002 Reprosil 6 Express XT 6 1.944 .005 .795 .004 Speedex 6 1.946 .008 .793 .007 Zetaplus 6 1.946 .008 .795 .007 Reprosil 6 1.947 .006 .795 .004 Express XT 6 1.948 .005 .793 .002 Speedex 6 1.948 .013 .793 .011 Zetaplus 6 1.949 .013 .792 .006 Reprosil 6 1.948 .004 .792 .005 Express XT 6 1.948 .002 .791 .011 Speedex 6 1.955 .010 .792 .006 Zetaplus 6 1.955 .006 .791 .013 Reprosil 6 1.950 .009 .791 .013 Express XT 6 1.950 .011 .793 .007 Speedex 6 1.957 .010 .790 .009 Zetaplus 6 1.959 .018 .788 .016 Reprosil 6 1.950 .034 .791 .007 Express XT 6 1.951 .005 .792 .015 Speedex 6 1.953 .012 .788 .011 Zetaplus 6 1.967 .031 .780 .020 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 92 Table 3: Mean percentage change of interpreparation distance and occlusogingival dimension (height) from master die for silicone impression materials tested Deviation At 0 h At 1 h At 24 h At 48 h At 168 h Product N Reprosil Express XT Speedex 6 Interpreparation distance Kruskal Wallis % Std. p value Test Change Deviation X2(3) -.1000 .133 6 -.1500 .285 6 -.0500 .412 Zetaplus 6 -.0500 Reprosil Express XT Speedex 6 .0000 6 .0500 .305 6 .0500 .697 Occlusogingival dimension Kruskal Wallis % Std. p value Test Change Deviation X2(3) -.1200 .325 .1200 .611 -.1200 .939 .428 .1200 .922 .351 .1200 .563 -.1200 .365 -.1200 1.470 .954 NS .344 .925 NS .473 Zetaplus 6 .1000 .708 -.2500 .804 Reprosil Express XT Speedex 6 .0500 .246 -.2500 .649 6 .0500 .121 -.3700 1.471 6 .4109 .524 -.2500 .765 Zetaplus 6 .4109 .380 -.3700 1.695 Reprosil Express XT Speedex 6 .1500 .464 -.3700 .682 6 .1500 .592 -.1200 .948 6 .5130 .543 -.5000 1.239 Zetaplus 6 .6160 .935 -.7550 2.114 Reprosil Express XT Speedex 6 .1500 1.788 -.3700 .999 6 .2000 .279 -.2500 1.934 6 .3080 .643 -.7550 1.448 Zetaplus 6 1.0272 .590 -1.7630 2.553 4.239 2.336 8.050 .237 NS .990 NS .045 sig .253 .969 NS 1.864 .601 NS .302 .960 NS .501 .919 NS 8.150 .043 sig p = probability level (<0.05) Table 4: Mean and standard deviation of interpreparation distance and occlusogingival dimension between various time intervals of silicone impression materials tested Product Reprosil Express XT 0h–1h Interpreparation distance Paired differences Wilcoxon Signed p value Std. Ranks Mean Deviation Test Z -.0020 .004 -.841 .400 NS Occlusogingival dimension Paired differences Wilcoxon Signed p value Std. Ranks Mean Deviation Test Z -.0013 .003 -.841 .400 NS 1 h – 24 h -.0011 .0021 24 h – 48 h -.0020 .006 -.736 .462 NS .0018 .010 -.736 .462 NS 48 h – 168 h -.0003 .037 -.135 .893 NS -.0001 .017 -.105 .916 NS Duration .007 -.105 .917 NS .005 -.736 .462 NS 0h–1h -.0041 .002 -2.049 .040 sig. .0020 .006 -.674 .500 NS 1 h – 24 h .0001 .005 -.211 .833 NS .0011 .010 -.314 .753 NS 24 h – 48 h -.0021 .010 -.314 .753 NS -.0018 .012 -.105 .916 NS 48 h – 168 h -.0008 .009 .000 1.000 NS .0016 .015 -.105 .917 NS table 4 cont ... 93 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 table 4 cont... Product Duration 0h–1h Speedex Zetaplus Interpreparation distance Paired differences Wilcoxon Signed p value Std. Ranks Mean Deviation Test Z -.0020 .009 -.946 .344 NS Occlusogingival dimension Paired differences Wilcoxon Signed p value Std. Ranks Mean Deviation Test Z -.0005 .013 -.210 .833 NS 1 h – 24 h -.0070 .010 -1.476 .140 NS .0013 .008 -.526 .599 NS 24 h – 48 h -.0020 .015 -.314 .753 NS .0021 .009 -.406 .684 NS 48 h – 168 h -.0030 .018 -1.976 .047 sig .0016 .015 -.105 .917 NS 0h–1h -.0025 .007 -.946 .344 NS .0030 .006 -1.051 .293 NS 1 h – 24 h -.0036 .014 -.813 .416 NS .0010 .015 -.315 .752 NS 24 h – 48 h -.0045 .020 -.933 .528 NS .0028 .026 -.526 .599 NS 48 h – 168 h -.0048 .025 -1.999 .045 sig -.0008 .016 2.120 .041 sig p = probability level (<0.05) Discussion which represents a linear change of approximately 79.82 μm greater than the standard. At 48 hours of repour, interpreparation distance increased by 0.513% to 0.616% for Speedex and Zetaplus when compared with the master die. This represented an increase of 99.881 μm to 119.935 μm from the master die. Similarly, at 1 week of repour, for the same products, there was increase in the dimension by 0.308% to 1.027% when compared with master die. These values represented increase of 59.968 μm to 199.935 μm in comparison to the master die. The increased deviation in interpreparation distance for condensation silicone over the time period indicates a possible loss of volatile constituents (alcohol) yielding undesirable dimensional stability1. The study revealed statistically significant difference in interpreparation distance for both the products of condensation silicone during 48 h to 168 h of repour (p<0.05). The difference in the interpreparation distance between the master die and stone models repoured at 24 h, 48 h and 168 h for condensation silicone may be clinically important because this change may result in fixed partial dentures that are too long mesiodistally12. Interpreparation dimension (IP) Interpreparation distance for all the dies produced immediately after making impression from Reprosil and Express XT decreased by -0.15% to -0.1%, whereas, for the same dimension, Speedex and Zetaplus revealed a decrease of -0.05%. All the four materials seemed to have comparable accuracy and dimensional stability at 1 hour of pour. At 1 hour of pour, Reprosil revealed the highest accuracy with no dimensional variation (Table 3). The interpreparation distance increased for most stone dies compared with the stainless steel master die for all the tested materials. The effect of repouring on the interpreparation distance are shown in Figs. 6 & 8. Linke et al11. studied six types of impression materials and reported that the perimeter of the arch of the test cast was larger than the standard reference model. Gordon et al12. reported the interabutment distances were greater for all dies using polysulfide, polyether and addition silicone impression materials: a linear change of 45 μm to 100 μm greater than the standard was observed. Clinically, this change may result in fixed partial dentures that are too long mesiodistally. On the other hand, Craig13, in a study, stated that no statistical or clinical differences existed in interpreparation distances in relation to master dies. Johnson and Craig9 reported small differences that were insignificant in interabutment measurements when compared with the master model. Nissan et al14. reported an increase of 0.009% to 0.1% in the interabutment measurements. Regarding addition silicone impression materials tested, deviation in interpreparation distance ranged from -0.15% to 0.20% for all times of pour, when compared with the master die. These values represent a linear change of -29.205 μm to 38.94 μm which has questionable clinical significance. Consistent with previous studies on addition silicone, the materials used in this study were found to be dimensionally accurate even up to one week12. This is advantageous because casts can be poured up to 1 week without concern for dimensional accuracies as in the case when the impression needs to be sent to the laboratory for pouring. Repour at 24 h showed the minimal percentage variation for addition silicone whereas condensation silicone revealed 0.41% increase in the interpreparation distance J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 94 The increase in the interpreparation distances seen may be explained by linear setting expansion of the die material. The increase in these distances may also be partially attributed to the impression material shrinkage upon setting towards the adhesive coated tray 9. Because of the constrain imposed by an effective adhesive on uniform shrinkage upon setting, abutments in resultant casts may tend to be at a greater distance apart than actually were on the master die or in the mouth7. materials; the addition silicone material demonstrated the smallest vertical change ranging from -0.37% to 0.12%. These values represent a linear change of -29.37 μm to 9.528 μm. Hence, the addition silicone impression materials tested were extremely stable over the 1-week period. It is desirable to minimize the decrease in height because a shorter model will produce a casting that is short at the margins9. A considerable gap or space may be detected when the die is undersized or short. Occlusogingival dimension (height) For pours immediately after making the impression and at 1 hour, vertical change for addition silicone impression materials and condensation silicone impression materials ranged from -0.12% to 0.12% and -0.25% to 0.12% respectively. At 24 hours of pour, the change in occlusogingival dimension for all the materials tested ranged from -0.37% to -0.25% (Table 3). These values are of less clinical significance, hence, all the four materials seemed to have comparable accuracy and dimensional stability during this period of time. Conclusions Within the limitations of this study, the following conclusions can be drawn. 1. The addition polymerization silicone demonstrated superior results in accuracy and dimensional stability in comparison to condensation silicone impression material. This material was extremely stable over the 1-week period. Amongst the addition silicone impression materials tested, Reprosil proved to be highly accurate. 2. Addition silicone and condensation silicone impression materials seemed to have comparable accuracy and dimensional stability at 1 hour of pour. For condensation silicones, the time interval between pours should not be greater than 1 hour. One can expect changes in dimensions of dies produced from successive pours of condensation silicone. Therefore, impressions made from condensation silicone should be poured as soon as possible. At 48 hours of repour, Speedex and Zetaplus showed the change in occlusogingival dimension of -0.50% and -0.755% respectively. These values represent a change of approximately - 39 μm and -59.947 μm respectively. For pours at 168 hours, Speedex and Zetaplus showed the change in occlusogingival dimensions of -0.75% to -1.763% (Table 3). These values represent a change of approximately -59.947 μm and -139.982 μm respectively. Table 4 reveals statistically significant difference in occlusogingival distance for Zetaplus between 48 h to 168 h of repour (p<0.05). These values may be clinically significant which may result in shorter castings made from the stone dies. 3. The gypsum dies produced from the successive pours were generally larger in interpreparation distance and smaller in occlusogingival dimension than the stainless steel master die, with the addition silicone demonstrating the smallest change. Larger interpreparation distance may result in fixed partial denture that are too long mesiodistally, whereas, smaller occlusogingival dimension may result in shorter castings made from the stone dies. The effect of repouring on the occlusogingival distance are shown in Figs. 7 & 9. This study showed decrease in vertical height when compared to the standard for all impression materials tested which was in agreement with Stackhouse15. Craig16, Linke et al.11 and Johnson and Craig9 also reported shorter vertical heights in their studies. Nissan J. et al.14, in a study, reported a decrease of 0.8% to 3% in the occlusogingival measurements. This phenomenon occurred because of contraction of the impression material toward the tray walls, making the stone dies wider in the horizontal aspect and shorter vertically9,17. During polymerization reaction, impression materials shrink toward the center of mass; the use of tray adhesives, however, would redirect this shrinkage toward the impression tray wall. In contrast, in a study by Gordon et al.,12 a slight increase of vertical heights for addition silicone impression was reported. Increase in vertical height was also reported by Hung et al18. References The vertical change was found to be smaller for addition silicone for all times of pour than for condensation silicone 95 1. Ciesco JN, Malone WF, Sandrik JL, Mazur B. Comparison of elastomeric impression materials used in fixed prosthodontics. J Prosthet Dent. 1981; 45: 89-94. 2. O’Brien WJ. Dental Materials and their selection. 3rd ed. IL: Quintessence Publishing Co, Inc; 2002. p 90-112. 3. Council on Dental materials, Instruments and Equipment: Vinyl Polysiloxane impression material: A status report. J Am Dent Assoc. 1990; 120: 595-6,598,600. 4. Craig RG, Urquiola NJ, Liu CC. Comparison of commercial elastomeric impression materials. Oper Dent. 1990; 15(3):94-104. 5. McCabe JF, Storer R. Elastomeric impression materials. The measurement of some properties relevant to clinical practice. Br Dent J. 1980; 149(3):73-9. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 6. Wassell RW, Ibbetson RJ. The accuracy of polyvinyl siloxane impressions made with standard and reinforced stock trays. J Prosthet Dent. 1991 ;65(6):748-57. 12. Gordon GE, Johnson GH, Drennon DG. The effect of tray selection on the accuracy of elastomeric impression materials. J Prosthet Dent. 1990 ;63(1):12-5. 7. Idris B, Houston F, Claffey N. Comparison of the dimensional accuracy of one- and two-step techniques with the use of putty/wash addition silicone impression materials. J Prosthet Dent. 1995; 74(5):535-41. 13. Craig RG. Review of dental impression materials. Adv Dent Res.1988; 2(1):51-64. 14. Nissan J, Laufer BZ, Brosh T, Assif D. Accuracy of three polyvinyl siloxane putty-wash impression techniques. J Prosthet Dent. 2000; 83(2):161-5. 15. Stackhouse JA Jr. The accuracy of stone dies made from rubber impression materials. J Prosthet Dent. 1970; 24(4):377-86. 16. Craig RG. Evaluation of an automatic mixing system for an addition silicone impression material. J Am Dent Assoc. 1985; 110(2):213-5. 17. Johnson GH, Craig RG. Accuracy of addition silicones as a function of technique. J Prosthet Dent. 1986; 55(2):197203. 18. Hung SH, Purk JH, Tira DE, Eick JD. Accuracy of one-step versus two-step putty wash addition silicone impression technique. J Prosthet Dent. 1992; 67(5):583-9. 8. 9. Wassell RW, Barker D, Walls AW. Crowns and other extracoronal restorations: impression materials and technique. Br Dent J. 2002 29; 192(12):679-84, 687-90. Johnson GH, Craig RG. Accuracy of four types of rubber impression materials compared with time of pour and a repeat pour of models. J Prosthet Dent. 1985; 53(4):48490. 10. Council on Dental Materials and Devices: Revised American Dental Association Specification no. 19 for Non-aqueous, Elastomeric Dental Impression Materials. J Am Dent Assoc. 1977; 94:733-41. 11. Linke BA, Nicholls JI, Faucher RR. Distortion analysis of stone casts made from impression materials. J Prosthet Dent. 1985; 54(6):794-802. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 96 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 97-104 Original Article Assessment of periodontal status of rural Nepalese population using the community periodontal index Pradhan S1, Bhat MK2 Professor, Department of Dental Surgery, Bir Hospital, National Academy of Medical Sciences, Kathmandu, Nepal, 2Professor, Department of Periodontics, College of Dental Surgery, Manipal, India 1 Abstract Background: Periodontal diseases are the most common and widespread chronic dental diseases worldwide. It is mandatory to know the disease status and treatment needs of the target population, in order to establish preventive community programmes and to treat periodontitis. Update information about the periodontal health status of adults in Nepal is limited. Aims and Objectives: To assess periodontal status of rural Nepalese population aged 35-44 years using Community Periodontal Index (CPI) and to analyze oral hygiene status of the population according to methods used for maintaining oral hygiene. Materials and methods: In 1998, 300 residents of appropriate age were examined to assess their periodontal status with Community Periodontal Index (CPI) and Loss of Attachment (LOA). Basic demographic information was also collected according to WHO (World Health Organization) proforma. Results: Among 300 subjects of 35-44 years of age, 156 (52%) were males and 144 (48%) were females. None had healthy periodontium, only 0.3% had bleeding on probing (Code 1). Shallow pockets (Code 3) were most prevalent at 41.67%, followed by calculus (Code 2) 37.33% and deep pockets in 20.33% of the surveyed population. 36% had no loss of attachment (Code I), 29.67% had 4-5 mm attachment loss, 19.67% had 6-8 mm attachment loss, 11.33% had 9-11mm attachment loss and 3.33% had >12 mm loss of attachment. Conclusion: The prevalence of periodontal disease in 35 – 44 year olds was high in this epidemiological study for periodontal disease with CPI and LOA. Poorer periodontal health was observed in males, smokers with some chewing habits and with poor plaque score. Key words: CPI, Periodontal status, Smoking, Oral hygiene Introduction Periodontal diseases are the most common and widespread chronic dental diseases worldwide. In developing countries, with acute shortages of trained dental manpower, high levels of unmet dental needs, and a scarcity of economic resources about 75 to 80 percent of the population live in rural areas1. In order to establish community programmes to prevent and treat periodontitis, it is mandatory to know the disease status and treatment needs of the target population. The community Periodontal Index of Treatment Needs (CPITN) was developed for this purpose by the Oral Health Unit of the World Health Organization in collaboration with the Federation Dentaire Internationale. It is a simple, time-saving method of assessing the treatment needs of a specified population group, and has stood the test in a number of major epidemiological studies on the prevalence of marginal periodontal disease2,3,4. Simplifications to this index system have, however, entailed increasing criticism and a demand for more precise recording of periodontal parameters5,6. Use of the CPITN for epidemiological purposes that is to obtain estimates of the prevalence and severity of destructive periodontal disease in a population7 must necessarily be based on the assumption that loss of periodontal support is accompanied by the formation of deepened periodontal pockets. However, the presence Correspondence Dr. Shaili Pradhan, Professor, Department of Dental Surgery, Bir Hospital, National Academy of Medical Sciences, Kathmandu, Nepal E-mail: [email protected] 97 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 An interview cum oral examination, with the help of a proforma prepared for the study was conducted for the collection of data. Personal data regarding each subject was recorded on the proforma. The recording of data was based on the “WHO Oral Health Assessment survey form (Proforma)”. Since the information recorded was to be computerized, appropriate codes were assigned. The assessment of the periodontal status was carried out using the Community Periodontal Index21. Prior to CPI recording plaque score for all teeth was recorded using Silness and Loe Plaque Index. of deepened pockets is reported to overestimate the periodontal attachment loss in some populations8 while in other populations the occurrence of deepened pockets is reported to underestimate loss of periodontal support9,10,11,12. It does not include any of the cumulative manifestations of periodontal tissue destruction such as attachment loss, alveolar bone loss and gingival recession but only the pocket depth. Pocket depth is indeed an important aspect since it directly influences the composition of the bacterial flora13,14 even though it may not establish the extent of attachment loss. However, recent research has been increasingly interested in attachment loss which determines the remaining tooth support15,16. The loss of attachment in the furcation areas could be more important than pocket depth per sextant17. Some authors have therefore suggested that the inability of the CPITN to assess the degree of attachment loss is a serious handicap18; others have suggested that a measure of gingival recession or attachment loss measurement5,12,19,20 should be incorporated in epidemiological studies involving the CPITN. This study was carried out in 1998 by single examiner (first author). Examination was based on the methods and diagnostic criteria recommended by WHO21 .The examination was carried out using the standardized Community Periodontal Index (CPI) probe (‘TSR 621’ WHO Periodontal probe) for detection of signs of periodontal disease. This tool has a 0.5 mm diameter ball at its tip, a black band between 3.5 and 5.5 mm, and coloured rings at 8.5 and 11.5mm from the tip. The CPI scores applied on the index teeth were as follows: presence or absence of gingival bleeding (CPI 1), presence of calculus (CPI 2), periodontal pockets 4-5 mm (CPI 3) or periodontal pockets 6 mm + (CPI 4). In addition, loss of attachment (LOA) was recorded for the index teeth according to the following criteria: Loss of attachment was measured only if the CEJ (CementoEnamel Junction) was visible, Loss of attachment 0-3 mm(Code 0), Loss of attachment 4-5 mm(Code 1), Loss of attachment 6-8 mm(Code 2), Loss of attachment 9-11 mm(Code 3), Loss of attachment 12 mm or more( Code 4)21. The mouth was divided into six sextants: the right upper posterior teeth (teeth 18-14), the upper anterior teeth (teeth 13-23), the upper left posterior teeth (24-28), the left lower posterior teeth(38-34), the lower anterior teeth (33-43) and the right lower posterior teeth (44-48). Two molars in the posterior sextants and teeth 11 or 31 in the anterior sextants were selected for examination at six conventional sites: the mesiobuccal, mid-buccal, distobuccal, mesiolingual, mid-lingual and distolingual surfaces. The highest of the component scores for each sextant was taken to be the overall sextant score, and the highest of the sextant scores for each individual to be their overall assessment of periodontal disease. The Community Periodontal Index (CPI) recommended by WHO21, which also considers loss of attachment is taken into consideration in this study conducted in rural area of Nepal. Update information about the periodontal health status of adults in Nepal is limited. According to the data obtained from WHO Global Oral Data Bank, the periodontal health of Nepalese population is poor. Hence this study was undertaken in a rural Nepalese population with no access to preventive or therapeutic dental services. The aims of the present study were to assess the periodontal status of Nepalese rural adult population using CPI and to analyze oral hygiene status of the population according to the method they use for maintenance of their oral hygiene. Furthermore, the intention was to correlate other possible variables which may have an influence on the periodontal status. Materials and methods Study area and population Jhor Mahankal, a village situated in Kathmandu district of Nepal was selected for the study. The selection of this village was based on certain logistic considerations like it is situated on the outskirts of Kathmandu valley, about 16 Km from the main city and has population of 3360 with a favourable sex ratio of 1700 males for 1660 females. The population residing has limited tradition for oral hygiene and very limited access to dental health care facilities. Prior to analysis of the data collected, the subjects were assigned to various groups on the basis of their oral hygiene practices or teeth cleaning devices, smoking habits, chewing habits and plaque score. Data analysis The collected data was analyzed using the statistical package SPSS/PC + and Chi Square test was applied for comparing the associations. A p value of less than 0.05 was considered as significant. Study Design A total population of 300 subjects of 35-44 years were chosen by random sampling technique and were examined at their houses selected randomly. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 98 had calculus, 42.86% had shallow pockets and 20.41% had deep pockets, 32.65% had no loss of attachment, 40.82% had 4-5 mm loss of attachment, 18.37% had 6-8 mm loss of attachment, 8.16% had 9-11mm loss of attachment and none had loss of attachment ≥ 12 mm. Among the subjects using other methods, 25.56% had calculus, 48.12% had shallow pockets and 26.32% had deep pockets, 19.55% had no loss of attachment, 31.58% had 4-5 mm loss of attachment, 26.32% had 6-8 mm loss of attachment, 17.56% had 9-11 mm loss of attachment and 5.26% had loss of attachment ≥ 12 mm. (Table 2) Results In the present study, out of total number of 300 subjects of 35-44 years of age, 156 (52%) were males and 144 (48%) were females. Among the total population examined none had healthy periodontium, only 0.3% had bleeding on probing (Code 1). Shallow pockets (Code 3) were most prevalent at 41.67%, followed by calculus (Code 2) 37.33% and deep pockets in 20.33% of the surveyed population. (Table 1) 36% had no loss of attachment (Code I), 29.67% had 4-5 mm attachment loss, 19.67% had 6-8 mm attachment loss, 11.33% had 9-11mm attachment loss and 3.33% had >12 mm loss of attachment (Table 2). The results suggest that the amount of periodontal destruction exhibited by the subjects using the toothbrush were less than the destruction observed in those using tooth powders, charcoal, ash and sand. This was demonstrated by the lesser percentages of deep pockets and higher percentages of subjects without loss of attachment among the subjects using tooth brush (p < 0.0001). When plaque score was correlated with oral hygiene devices, it was observed that among tooth brush users, 71.43% had lesser plaque score and 28.31% had fair plaque score while 25% of the subjects had poor plaque score. Among tooth powder and finger users, 20.09% had fair plaque score and 6.49% lesser plaque score. Among those who used other devices, 75% had higher (poor) plaque score, 51.60% had fair plaque score and 22.08% with lower (good) plaque score (Table 3). Gender It was observed that among the males none had healthy periodontium and bleeding on probing (Code 1), 29.49% had calculus (Code 2) as the highest score, 44.23% had shallow pockets (Code 3) also and 26.26% had deep pockets (Code 4). Among the females, none had healthy periodontium, 0.69% had only bleeding on probing, 45.83% had calculus as their highest score, 39.58% shallow pockets and 13.89% had deep periodontal pockets (Table 1). In relation to the loss of attachment (gingival recession), it was observed that among males 30.77% had no loss of attachment, 32.05% had 4-5 mm loss of attachment, 17.95% had 6-8 mm loss of attachment, 12.82% had 911 mm loss of attachment and 6.41% had ≥ 12 mm loss of attachment while for the females, 41.67% had no loss of attachment, 27.08% had 4-5 mm loss of attachment, 221.53% had 6-8 mm loss of attachment, 9.72% had 9-11 mm loss of attachment and none had loss of attachment exceeding 12 mm or more. (Table 2) The above study suggests that the prevalence of periodontal disease was more in males in comparison to females. Plaque score Among the study sample, 25.67% had lower plaque score, 73% had fair plaque score and 1.33% had higher plaque score. Among the subjects who had lower plaque score, 1.30% had bleeding on probing (Code 1), 58.44% had calculus, 25.97% had shallow pockets and 14.29% had deep pockets (Table 1), 55.84% had no loss of attachment, 19.48% had 4-5 mm loss of attachment, 14.29% had 6-8 mm loss of attachment, 6.49% had 9-11 mm loss of attachment and 3.90% had ≥ 12 mm loss of attachment (Table 2). Among the subjects who had fair plaque score, 30.59% had calculus, 47.49% had shallow pockets and 21.92% had deep pockets, 29.68% had no loss of attachment, 33.33% had 4-5 mm loss of attachment, 21.46% had 6-8 mm loss of attachment, 12.79% had 9-11 mm loss of attachment and 2.74% had ≥ 12 mm loss of attachment. Among the subjects who had higher plaque score, 50% had shallow pockets and 50% had deep pockets, none had loss of attachment, 25% had 4-5 mm loss of attachment, 25% had 6-8 mm loss of attachment, 25% had 9-11 mm loss of attachment and 25% had ≥ 12mm loss of attachment. It was observed that the subjects with lower plaque score had healthier periodontal tissues than the subjects with fair or higher plaque score. (p<0.0001) Teeth Cleaning Devices/ Oral Hygiene Practices The population was divided into three groups according to the devices they use to clean their teeth, Group I who used tooth brush constituted 39.33%, Group II who used tooth powder with finger constituted 16.33% and Group III other methods like charcoal, ash and sand constituted 44.33%. In the distribution of periodontal status it was observed that none had healthy periodontium and the groups who used other methods had more attachment loss. Among tooth brush users (Group I), it was observed that 0.85% had bleeding on probing (Code 1), 50.85% had calculus, 34.75% had shallow pockets and 13.56% had deep periodontal pockets (Table 1), 55.93% had no loss of attachment, 22.88% had 4-5mm loss of attachment, 46.61% had 6-8mm loss of attachment, 5.93% had 9-11 mm loss of attachment and 2.54% had loss of attachment ≥ 12 mm. Among tooth powder with finger users, 36.73% 99 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Smoking In the population studied, 31% were none smokers and 69% were smokers. Among smokers, 41.4% were light smokers (those smoking less than 10 cigarettes a day) and 27.3% were heavy smokers (those smoking 10 or more than 10 cigarettes a day). It was observed among non smokers, 1.06% had bleeding on probing (Code 1), 57.45% had calculus, 34.04% had shallow pockets and 7.45% had deep pockets (Table 1), 56.38% had no loss of attachment, 14.89% had 4-5 mm loss of attachment, 23.40% had 6-8 mm loss of attachment and 5.332% had 9-11 mm loss of attachment. None had loss of attachment ≥ 12 mm. (Table 2) Among light smokers, 29.03% had calculus, 50% had shallow pockets and 20.97% had deep pockets, 25% had no loss of attachment, 37.90% had 4-5 mm loss of attachment, 20.16% had 6-8 mm loss of attachment and 13. 71% had 9-11 mm loss of attachment and 3.23% had loss of attachment ≥ 12 mm. Among heavy smokers, 26.83% had calculus, 39.02% had shallow pockets and 34.15% had deep pockets, 29.27% had no loss of attachment, 34.15% had 4-5 mm loss of attachment, 14.63% had 6-8 mm loss of attachment an 14.63% had 9-11 mm loss of attachment and 7.32% had ≥ 12 mm loss of attachment. It can thus be concluded that the non smokers had better periodontal status than smokers (p<0.00001). of attachment, 24.24% had 6-8 mm loss of attachment, 18.18 % had 9-11 mm loss of attachment and 12.12 % had ≥ 12 mm loss of attachment. (Table 1 and 2) The results indicate that the non chewers had better periodontal status than chewers. (p<0.00001) When chewing habit was correlated with plaque score, it was observed that among those who had lower plaque score, 28.79% were chewers and 24.79% were non chewers. Among those who had fair plaque score, 73.50% were non chewers and 71.21% were chewers. 1.71% of non chewers had higher plaque score (Table 3). It was thus demonstrated that various factors like the oral hygiene practices, smoking, tobacco chewing influenced the state of the periodontal tissues. To study their effects in better detail smoking, chewing habits and plaque score were correlated with the oral hygiene practices. The results were as follows: A correlation of smoking habits with oral hygiene practices revealed that the majority of non smokers (56.38%), 37.10% of light smokers and 23.17% of heavy smokers used tooth brush. 19.51% heavy smokers, 16.94% light smokers and 12.77% non smokers used tooth powder with finger. The majority of heavy smokers (57.32%), 45.97% light smokers and 30.85% of non smokers used other devices (Table 3) (p < 0.0001). A correlation of smoking with plaque score showed that, 44.48% of non-smokers, 20.16% of light smokers and 12.20% of heavy smokers had lower plaque score. Among those who had fair plaque score, 87.80% of heavy smokers, 77.42% of light smokers and 54.25% of non-smokers had fair plaque score. Among those who had higher plaque score, 2.42% were light smokers and 1.06% were non-smokers (Table 3) (p<0.00001). A correlation of chewing habits with oral hygiene practices showed that relatively equal proportion of both chewers (39.74%) and non chewers (37.88%) used tooth brush. 31.82% of chewers and 11.97% of non chewers used tooth powder and finger. 48.29% of non chewers and 30.30% of chewers used other devices to clean their teeth (Table 3) (p < 0.00001). Chewing habits Among the study sample 22% had oral habits like tobacco and betel nut chewing and 78% did not. It was observed that among non chewers, 0.43% had bleeding on probing (Code 1), 39.74% had calculus, 38.89% had shallow pockets and 20.94% had deep pockets. Among non chewers, 41.45% had no loss of attachment, 29.91% had 4-5 mm loss of attachment, 18.38% had 6-8 mm loss of attachment, 9.40% had 9-11 mm loss of attachment and 0.85% had ≥ 12 mm loss of attachment. Among chewers, 30.59% had calculus, 47.49% had shallow pockets and 21.92% had deep pockets, 16.67% had no loss of attachment, 28.79% had 4-5 mm loss J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 When smoking habits was correlated with different variables, the following results were observed: A correlation of chewing habits with smoking habits revealed that 34.19% of non chewers and 21.21% of chewers were non smokers. Relatively equal proportion of non chewers (41.45%) and chewers (40.91%) were light smokers. Among heavy smokers, 37.88% were chewers and 24.36% were non chewers. (Table 3) (p < 0.02). 100 Table 1: Periodontal status of the study population as per CPI score (%) according to different variables Variables (n) CPI 0 CPI 1 CPI 2 CPI 3 CPI 4 Gender Male 156 0 0 29.49 44.23 26.28 Female 144 0 0.69 45.83 39.58 13.89 118 0 0.85 50.85 34.75 13.56 Tooth powder and finger 49 0 0 36.73 42.86 20.41 Charcoal, sand, ash etc 133 0 0 25.56 48.12 26.32 Oral Hygiene Practices Tooth brush and tooth paste Smoking habit Non smokers 94 0 1.06 57.45 34.04 7.45 Light smokers 124 0 0 29.03 50 20.97 82 0 0 26.83 39.02 34.15 234 0 0.43 39.74 38.89 20.94 66 0 0 28.79 53.03 18.18 77 0 1.3 58.44 25.97 14.29 Fair(1-1.9) 219 0 0 30.59 47.49 21.92 Poor (2-3) 4 0 0 0 50 50 (≤10 sticks/day) Heavy smokers (>10 sticks /day) Chewing habits Non chewers Chewres Plaque score (Sillness and Loe) Good(0-0.9) Table 2: Periodontal status of the study population as per LOA score (%) according to different variables Variables (n) LOA 0 LOA 1 LOA 2 LOA 3 LOA 4 Gender Male 156 30.77 32.05 17.95 12.82 6.41 Female 144 41.67 27.08 21.53 9.72 0 118 55.93 22.88 46.61 5.93 2.54 Oral Hygiene Practices Tooth brush and tooth paste Tooth powder and finger 49 32.65 40.82 18.37 8.16 0 Charcoal, sand, ash etc 133 19.55 31.58 26.32 17.56 5.26 Non smokers 94 56.38 14.89 23.4 5.32 0 Light smokers 124 25 37.9 20.16 13.71 3.23 82 29.27 34.15 14.63 14.63 7.32 234 41.45 29.91 18.38 9.4 0.85 66 28.79 28.79 24.24 18.18 0 Smoking habit (≤10 sticks/day) Heavy smokers (>10 sticks /day) Chewing habits Non chewers Chewers Plaque score (Sillness and Loe) Good(0-0.9) 77 55.84 19.48 14.29 6.49 3.9 Fair(1-1.9) 219 29.68 33.33 21.46 12.79 2.74 Poor (2-3) 4 0 25 25 25 25 101 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Table 3: Relationship between various demographic factors in percentage (%) Smoking Plaque score Oral hygiene Tooth Others powder 12.77 30.85 good Fair poor Non smoker 44.68 54.26 1.06 Tooth brush 56.38 Light smoker 20.16 77.42 2.42 37.10 16.94 45.97 Heavy smoker 12.20 87.80 0 23.17 19.51 57.32 Oral hygiene Plaque score good Tooth brush Tooth powder Others (charcoal, sand, ash) fair 41.45 40.91 24.36 37.88 Chewing habits poor Non chewers Chewers 71.43 28.31 25 39.74 37.88 6.49 20.09 0 11.97 31.82 22.08 51.60 75 48.29 30.30 Discussion The age 35-44 years is a key age group acknowledged by the WHO because, in most populations, all signs of periodontal disease can be observed and various stages of periodontal disease can be investigated, though tooth loss is still not a phenomenon frequently encountered3,22,23,24. followed by light smokers and least in non smokers. This finding demonstrates the detrimental effect tobacco has on the periodontal tissues, which is in accordance with other studies27, 29, 32. Various factors such as altered host response33,34, changes in oral microflora35 may probably contribute to more severe forms of periodontal disease in smokers. Although the mechanisms by which tobacco exerts its influences are not clearly known, it seems likely that it primarily has a systemic influence affecting host response or susceptibility27 .The results suggest that smoking influences the prevalence and severity of periodontal diseases and thus favour the hypothesis that it is a major risk factor for periodontal disease. The habit of tobacco and betel nut chewing was also shown to adversely affect the health of the periodontal tissues of the subjects. This finding is in agreement with earlier reports36, 37, 38. About 90% of the Nepalese population live in rural areas with neither facility for any preventive nor therapeutic dental services. Jhor Mahankal village, in Kathmandu valley is one such village. A lack of reliable data on prevalence of periodontal status in Nepal prompted the survey. In the present study, the prevalence of periodontal disease was found to be 100% in the subjects, i.e., none of the subjects had a completely healthy periodontium (Code 0) as their highest CPI score. This is in comparison to other studies5, 25. Lack of proper dental health knowledge and awareness and the virtual absence of preventive and therapeutic dental services could be the factors responsible for this rather alarming state of unhealthy amongst this backward, rural community. Calculus (Code 2) and shallow pocketing (Code 3) were the most frequently observed conditions. Thus this rural population exhibited a high level of periodontal disease as was evident from the prevalence of periodontal pockets which is in agreement with several earlier studies24,26. Prevalence of gingival recession was observed to be more in subjects with chewing habits than non chewers in the present study. Gingival recession and advanced periodontal destruction have been reported adjacent to the regions where the tobacco quid is held36, 37.This greater severity of gingival recession observed in the present study could probably be the result of mechanical injury to the gingiva. Holm G38 has shown that increased prevalence of gingival recession could be attributed not only to mechanical but chemical irritating effect of smokeless tobacco components. According to him, this stimulus is likely to result in the release of inflammatory mediators, toxic substances such as nitrosoamines which may play a role in the development of periodontal attachment loss and gingival recession. These observations lend credence to the view that control of such deleterious habits could pave the way to a great extent in promoting periodontal health. The detrimental effect of tobacco smoking on the periodontal tissue was demonstrated in this study, corroborating earlier reports27,28,29,30,31.The estimated risk of periodontal destruction for smokers increased, compared to the non smokers. Non smokers in general had less periodontal destruction than smokers. This value is comparable to those obtained by Goultschin28. The percentage of subjects with deep pockets (Code 4) were observed to be more in heavy cigarette smokers, J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Chewing habits Non chewers chewers 34.19 21.21 102 The various oral hygiene practices employed by this rural population included the use of toothbrush and tooth paste, tooth powder and others like charcoal, ash and sand. It was observed that majority of subjects used other methods. The tooth brush users were found to have better periodontal health when compared to tooth powder and other method users. This is in agreement with other studies32,39,40. Greene JC40 noticed both in urban and rural samples in India that tooth brush users had lower periodontal disease scores than those who used the finger as a means of cleaning the teeth, while Ramfjord32, in an attempt to compare methods of oral hygiene with the periodontal scores, showed that the use of a brush was associated with a lower periodontal disease score than other methods of oral hygiene. This reinforces the belief that to date, the most dependable mode of plaque control is mechanical cleaning with a tooth brush. Conclusion In conclusion, we estimated the overall prevalence of severe periodontal disease (6 mm or deeper periodontal pockets) in subjects 35 -44 years of age to be 20.33% using CPI and loss of attachment >3 mm to be 64% using LOA, in a 300 study population of Jhor Mahankal village. Data analysis revealed that this community which is deprived of professional dental services or any oral health education programmes had a high prevalence of periodontal diseases. In light of these observations from the present study the following recommendations for a community based oral health programme suited to such a population group may be made. The public needs to be educated and motivated towards prevention of periodontal diseases during childhood. This goal can be pursued by laying adequate emphasis on school dental health education programmes. A proper strategy thus needs to be adopted in Nepal to promote and maintain oral health through a well designed health care delivery system. Such a scheme has already been introduced in Chiang Mai, Thailand with remarkable success. To contend with the oral health problems in Nepal, National Oral Health Policy that emphasizes prevention will be more advantageous and cheaper than the establishment of traditional curative programmes. This survey was confined to just one of the numerous villages of this nation. More such surveys need to be conducted in different parts of Nepal amongst populations with different cultures, living conditions and habits. This should enable us to devise and implement a National Oral Health Programme best suited to this country. In the present study, statistically significant higher plaque scores were observed in smokers. This is comparable with earlier report18. It could be attributed to the devices used by higher percentages of smokers for cleaning their teeth as most of the smokers used other devices than tooth brush to clean their teeth. Majority of nonsmokers used tooth brush to clean their teeth (Table 3) Plaque scores in chewers and non chewers were found to be relatively similar. Results of this study indicate a high prevalence of plaque, calculus and shallow pockets among the population examined, which shows that effectiveness of the oral hygiene methods employed amongst them is not very high and further, that the low number of dental professionals in Nepal are unable to treat these conditions adequately. References However, though CPI includes measurement of attachment loss, determination of loss of attachment is in general not sufficient for the assessment of the periodontal status. As CPI measurements are done only in index teeth, it can overestimate or underestimate the prevalence of periodontal disease. A disadvantage of the CPI is that, by using the highest score per sextant and not individual tooth scores, the extent of periodontal disease within and between individuals and populations is poorly defined. CPI codes could be recorded as noncontiguous, distinct categories for each tooth rather than a sextant score. In this way, the index would be more representative of the disease distribution within the mouth. As new diagnostic aids such as tests that detect pathogenic bacteria or actively deteriorating periodontal sites become validated, their incorporation into CPI should be explored to better detect and assess destructive periodontal diseases. 103 1. Saparamadu KDG . The provision of dental services in the Third World. Int Dent J 1986;36:194-8. 2. Ainamo J, Barmes D,Beagrie G, Cutress T, Martin J, Sardo Infirri J . Development of the World Health Organization (WHO) Community Periodontal Index of Treatment Needs (CPITN). Int Dent J 1982;32:281-91. 3. Pilot T, Barmes DE, Leclereq MH, McCombie BJ, Sardo Infirri J . Periodontal conditions in adults 35-44 years of age: an overview of CPITN data in the WHO Global Oral Data Bank. Comm Dent Oral Epidemiol 1986;14:310-2. 4. Pilot T, Barmes DE, Leclereq MH, McCombie BJ, Sardo Infirri J. Periodontal conditions in adolescents, 15-19 years of age: an overview of the CPITN data in the WHO Global Oral Data Bank. Comm Dent Health 1987;15:336-8. 5. Almas K, Bulman JS, Newman HN . Assessment of periodontal status with CPITN and conventional periodontal indices. J Clin Periodontol 1991;18:654-9. 6. Lewis JM, Morgan MV, Wright FA . The validity of CPITN scoring and presentation method for measuring periodontal conditions. J Clin Periodontol 1994;21:1-6. 7. Cutress TW, Ainomo J, Sardo-Infirri J . The community periodontal index of treatment needs (CPITN) procedure J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 disease in Keelung, Taiwan: a model from Keelung community-based integrated screening programme. J Clin Periodontol 2007;34:851-9. for population groups and individuals. Int Dent J 1987;37:222-33. 8. 9. Ainamo J, Parvianen K, Murtoma H . Reliability of CPITN in epidemiological assessment of periodontal treatment needs at 13-15 years of age. Int Dent J 1984;34:214-8. Aucott DM, Ashley FP . Assessment of the WHO partial recording in identification of individuals highly susceptible to periodontitis. Community Dent Oral Epidemiol 1986;14:152-5. 10. Baelum V, Fejerskov O, Manji F . Periodontal diseases in adult Kenyans. J Clin Periodontol 1988;15:445-52. 11. Miller NA, Benamghar L, Roland E, Penaud J, Martin G . Analysis of the Community Periodontal Index of Treatment Needs – study on adults in France. IV: The significance of gingival recession. Community Dent Oral Epidemiol 1991;8:45-51. 12. Wilson MA, Clerehugh V, Lennon MA, Worthington HV. An assessment of the validity of the WHO periodontal probe for use with the Community Periodontal Index of Treatment Needs. Br Dent J 1988;165:18-21. 13. Listgarten MA, Slots J, Rosenberg J, Nitkin L, Sullivan P, Oler J . Clinical and microbiological characteristic of treated periodontitis patients on maintenance care. J Periodontol 1989;60:452-9. 14. Socransky SS . Microbiology of periodontal disease present status and future considerations. J Periodontol 1977;48:497-504. 15. Goodson JM, Tanner ACR, Haffajee AD, Sornberger GC, Socransky SS . Patterns of progression and regression of advanced destructive periodontal disease. J Clin Periodontol 1982;9:472-81. 16. Socransky SS, Haffajee AD, Goodson JM,Lindhe J . New concepts of destructive periodontal disease. J Clin Periodontol 1984;11:21-32. 17. Svardstrom G, Wennstrom JL. Furcation topography of the maxillary and mandibular first molars. J Clin Periodontol 1988;15:271-75. 18. Johnson NW, Griffiths GS, Wilton JMA, Maiden MFJ, Curtis MA, Gilett IR, Wilson DT, Sterne JA . Detection of high risk groups and individuals for periodontal diseases. Evidence for the existence of high-risk groups and individuals and approaches to their detection. J Clin Periodontol 1988;15:276-82. 24. Miyazaki H, Shirahama R, Ohtani I, Takehara T, Shimada N, Pilot T . CPITN assessments in institutionalized elderly people in Kitakyushu, Japan. Community Dent Health 1991;8:239-43. 25. Hohfeld M, Bernimoulin JP . Application of the community periodontal index of treatment needs (CPITN) in a group of 45-54 year old German factory workers. J Clin Periodontol 1993;20:551-556. 26. Pilot T, Effendi I, Sunu NP, Wibowo D . Periodontal conditions in different regions in Indonesia. Community Dent Health 1987;4:239-43. 27. Bergstrom J . Cigarette smoking as risk factor in chronic periodontal disease. Community Dent Oral Epidemiol 1989;17:245-7. 28. Goultschin J, Cohen HD, Brayer L, Soskolne WA. Association of smoking with periodontal treatment needs. J Periodontol 1990;61:364-7. 29. Ismail, Burt BA, Eklund SA . Epidemiological pattern of smoking and periodontal disease in United States. J Am Dent Assoc 1983;106:617-23. 30. Preber H,Bergstrom H . Cigarette smoking in patients referred for periodontal treatment. Scand J Dent Res 1986;94:102-8. 31. Vered Y, Livny A, Zini A, Sgan-Cohen HD. Periodontal health status and smoking among young adults. J Clin Periodontol 2008;35:768-72. 32. Ramfjord SP . Periodontal status of boys 11 to 17 years of old in Bombay, India. J Periodontol 1961;32:237. 33. Bridges RB, Krall JH, Huang LJ, Chancellor BM . Effect of tobacco smoke on chemotaxis and glucose metabolism of polymorphonuclear leukocytes. Infect Immun 1977;15:115-23. 34. Kenney EB, Krall JH, Saxe SR, Jones J . The effect of cigarette smoke on human oral polymorphonuclear leukocytes. J Periodontol Res 1977;12:227-34. 35. Kenney B, Saxe SR, Bowles RD . The effect of cigarette smoking on the anaerobiosis in the oral cavity. J Periodontol 1975;46:82-5. 36. Christen AG . The clinical effects of tobacco on oral tissues. J Am Dent Assoc 1970;81(12):1378-82. 19. Holmgren CJ. CPITN – Interpretations and limitations. Int Dent J 1994;44:533-46. 37. 20. Page RC, Morrison EC . Summary of outcomes and recommendations of the workshop on CPITN. Int Dent J 1994;44:589-94. Christen AG, Armstron WR, McDaniel RK . Intra-oral leukoplakia, abrasion, periodontal breakdown and tooth loss in a snuff dipper. J Am Dent Assoc 1979;98:584-6. 38. Holm G . Smoking and chewing tobacco as an additional risk for tooth loss. J Periodontol 1994;65:996-1001. 21. World Health Organization . Oral Health Surveys, Basic Methods, 4th ed. Geneva World Health Organization, 1997. 39. Chiranjeevi K, Wade BA . Periodontal effects of National Health Services on an Immigrant population. J Periodontol 1972;43:718-22. 22. Krustrup U, Erik Petersen P . Periodontal conditions in 3544 and 65-74 year old adults in Denmark. Acta Odontol Scand 2006;64:65-73. 40. Greene JC . Periodontal disease in India: report of an epidemiological study. J Dent Res 1960;39:302 23. Lai H, Lo MT, Wang PE, Wang TT, Chen TH, Wu GH. A community-based epidemiological study of periodontal J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 104 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 105-109 Original Article Spectrophotometric analysis of shade duplication of various recent ceramic system used for porcelain fused to a metal crown: An invitro study Das DK 1, Dong CX2, Singh SK3, Roy J4 Resident, Dalian Medical University, China, 2Professor, Dalian Stomatological Hospital, China, 3Associate Professor, 4Dental Surgeon, UCMS, Bhairahwa, Nepal. 1 Abstract Objective: To evaluate and compare the colour difference of the total colour replication process and the direction of the individual color parameters for dental porcelain of three brands. Materials and methods: The fabricated shades (A2) of 3 different porcelain companies were determined visually and instrumentally using Vita Lumin Shade Tab (A2) and Spectrophotometer. Corresponding porcelain disks were made of approximately 0.8 mm metal, 0.2mm opaque, 0.8 mm dentin, 0.5mm enamel and glaze were fabricated with each of the three porcelain brands (Vita VMK 95, Ceramco 3, Ceramax). The colour of the fabricated disks and master disks were measured with a spectroradiometer with a 450/00 using {C.I.E 1931(xyz)} parameter. Analysis of variance (ANOVA) was applied to evaluate within group differences among the porcelain groups for total colour difference (D.E) and direction of colour parameters (D.L, D.RG, D.YB). Result: The largest mean (D.E) was recorded for Ceramax and least for Vita VMK 95.A significant difference (P= 0.015) was found in yellow and blue axis (D.YB). Data collected further showed no significant difference between shade selection methods and the evaluated clinical criteria. The amount of change within each colour parameters was dependent on the porcelain system, as well as the amount of change among colour parameters. Conclusion: Samples made with different brands of porcelains have noticeably different shade despite having the same Vita Lumin Shade Guide. Different brands of porcelain differ from each other more in redness and yellowness. Different brands of porcelain differ from each other more in lighter than darker shades. Key words: Spectrophotometer, Vita shade guide, Porcelain systems Introduction Colour matching between natural teeth, shade guides and metal ceramic restorations is a common clinical problem1.Use of shade guides is highly subjective2, most existing commercial shade guides do no represent the entire spectrum of tooth colour3.Due to inter human difference in the perception of colour, visual shade assessment of human teeth is lacking standardization that may be improved by use of spectrophotometer4.General variable such as external light conditions, experience, age, fatigue of human eye and physiological variables such as colour blindness lead to inconsistencies4. Computerized shade matching system offers better accuracy, improved efficiency and esthetic benefits to the patient, dentist and technician. It analyzes the color of natural tooth and calculate the exact rates of hue, chroma and value for multitude of points on the tooth surface and display this information on the computer screen2. Materials and methods The materials used in this study were - Porcelain systems: 1: Ceramco 3 (Dentsply International, USA, code C) 2: Ceramax (Alphadent Co. Ltd, Korea, code CM) 3: Vita VMK 95 (Vita Zahnfabrik H. Rauter GmbH & Co.KG. Germany, code V) -Base Metal Alloy: Ni-Cr alloy: (Brand-Ugirex, France, code N) Correspondence Dr. Dilip Kumar Das, Dalian Medical University, China E-mail: [email protected] 105 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 For this study, the instrument geometry used was 450/00 with specular component excluded, as this geometry closely relates to the normal human vision when observing a natural tooth. In this study 15 substructure patterns were fabricated using inlay wax, then cut into 1 x 1 cm square pieces, measured with digital Vernier caliper, followed by casting with Ni-Cr alloy. Thickness of each specimen was measured at nine locations having average mean thickness of 0.8 mm approximately. The surface of alloy in which porcelain was to be fired was air abraded with 50μm aluminum oxide at 75psi pressure. All the specimens were cleaned with pressurized steam for any surface contaminants. The specimens were held under vacuum for 2 minutes at 9600 C with temperature increase of 700 C per minute according to the manufacturer instructions. Results Presented below is the comparative analysis of the respective mean values corresponding to each of the three brands viz. V (Vita VMK 95), C (Ceramco 3) & Cm (Ceramax); for each of the four parameters of C.I.E1931(xyz)(International commission on Illumination) i.e. D.E (Total colour difference), D.L (Sample darker and lighter shades), D. RG. (Sample red and green) & D.YB (Sample yellow and blue). Each type of porcelain was applied on 5 samples each (5 each of Ni-Cr).Wash opaque was applied as thin layer with brush and fired. Each company shade had its own opaque paste which was applied in thin layer and then fired. Opaque thickness was determined with a micrometer by measuring the sample at 3 points on each disk. Dentine porcelain was mixed to a creamy consistency using distilled water, vibrated mechanically for proper condensation and fired. Final thickness of 1.8 mm approximately was ground to matte finish and steam cleaned for removal of any surface contaminants. Enamel powder was mixed on the glass slab with a special liquid provided by the manufacturer into a creamy consistency, spread evenly and over build to compensate for the firing shrinkage and then fired. The specimens were ground to approximate thickness of 0.5 mm of enamel porcelain. A thin layer of glaze was applied and fired. All the five layers were fired by strictly following the manufacturer’s instructions. Table 1 shows that the highest mean value (17.98) is recorded in case of brand Cm (Ceramax) & lowest (16.15) in case of brand V (Vita VMK 95). Table 2 shows that the value of F is not significant at 5 percent level of significance. Three brands may be regarded as one and the same. Table 3 shows that the highest mean value (14.25) is recorded in case of brand V (VitaVMK95) & lowest (13.24) in case of brand Cm (Ceramax). Table 4 shows that the value of F is not significant at 5 percent level of significance. Three brands may be regarded as one and the same. Table 5 shows that the highest mean value (8.77) is recorded in case of brand Cm (Ceramax) & lowest (6.43) in case of brand V (Vita VMK 95). Sample measurements and data manipulation The samples were individually analyzed with Vita lumin shade guide (A2) in a spectrolinao spectrophotometer. CIE standard illuminant D65 was used for all measurements. The colour of each sample in this study were described by 4 parameters of C.I.E (International Commission on Illumination) 1931(xyz). The resultant tristimulus values X, Y, Z are the standard response of the eye to the red, green, and blue stimuli from the object. The X (D.L) parameter defines the lightness or darkness of samples and its numerical value ranges from black (-) to white (+). Similarly the other two axis defines (D.R.G) Red(+) & Green(-) and (D.Y.B) Yellow(+) & blue(-). Evaluation of color differences or DE in dental research is usually performed with the following formula. Table 6 shows that the value of F is not significant at 5 percent level of significance. Three brands may be regarded as one and the same. Table 7 shows that the highest mean value (6.72) is recorded in case of brand Cm (Ceramax) & lowest (2.98) in case of brand C (Ceramco 3). Statistical Significance for difference in mean value has been tested by Analysis of Variance (ANOVA) through Table 8. D.E = Dl2 + D.RG2 + D.YB2 Table 8 shows that the value of F is significant at 5 percent level of significance. Three different brands cannot be regarded as one and same since these are resulting to mean values whose differences are significant at 5 percent level of significance. The CIE system of color specification provides a common means of analyzing and presenting color measurements data. As the difference between various brands has been found to be statistically significant; the individual comparisons between them are present in Table 9. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 106 significantly from V and also C, at 5 percent level of significance. Table 9 shows that the difference between means of brands V (Vita VMK 95) and C (Ceramco 3) is not significant; while that of brand Cm (Ceramax) differs D.E: Table 1: Mean Values Replication Brand V I 15.64 II III IV 14.81 15.70 18.07 V 16.54 Total Mean S. D C.V (In %) 80.76 16.15 1.24 7.68 C 18.48 19.20 19.12 15.56 10.44 82.80 16.56 3.73 22.52 Cm 18.72 17.79 18.31 14.38 20.72 89.92 17.98 2.30 12.79 Total 52.84 51.80 53.13 48.01 47.70 253.48 16.90 - - Table 2: ANOVA (D.E) Between Groups 9.225 2 4.612 0.667 F tab 5% 3.88 Within Groups 83.004 12 6.917 - - - Total 92.229 14 - - - - Sum of squares Source Df Mean square F P value > 0.05 D.E: Table 3: Mean Values V I 13.49 II 14.16 Replication III 14.36 IV 15.64 Brand V 13.64 Total Mean S. D C.V (In %) 71.29 14.25 0.85 5.96 C 17.15 13.98 18.18 13.78 7.75 70.84 14.16 4.07 28.74 Cm 15.26 14.37 16.86 4.14 15.61 66.24 13.24 5.17 13.04 Total 45.90 42.51 49.40 33.56 37.00 208.37 13.89 - - Table 4: ANOVA (D.L) 3.114 2 1.557 .106 F tab 5% 3.88 Within Groups 176.174 12 14.681 - - - Total 179.288 14 - - - - Source Sum of Squares Between Groups Df Mean Square F P value > 0.05 D.RG: Table 5: Mean Values V I 7.38 II 4.06 Replication III 6.00 Brand IV 5.66 V 9.07 Total Mean S. D C.V (In %) 32.17 6.43 1.90 29.55 C 6.14 12.05 5.74 6.90 6.39 37.22 7.44 2.61 35.08 Cm 7.90 9.62 4.76 11.57 10.00 43.85 8.77 1.41 16.08 Total 52.84 51.80 53.13 48.01 47.70 253.48 16.90 - - Table 6: ANOVA (D.RG) Source F tab P value Sum of squares Df Mean square F Between Groups 13.721 2 6.861 1.203 3.88 > 0.05 Within Groups 68.422 12 5.702 - - - Total 82.143 14 - - - - 107 5% J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 D.YB: Table 7: Mean Values Replication Brand I Ii Iii Iv V Total Mean C.V (In %) S. D. V 2.88 1.50 2.05 7.07 2.28 15.78 3.15 2.24 71.11 C 3.08 5.29 1.58 2.18 2.81 14.94 2.98 1.41 47.32 Cm 7.42 4.13 5.32 7.48 9.25 33.60 6.72 2.00 29.76 Total 13.38 10.92 8.95 16.73 14.34 64.32 4.29 - - Table 8: ANOVA (D.YB) Source Sum of squares Between Groups Within Groups Total F tab P value Df Mean square F 44.380 2 22.190 6.018* 3.88 < 0.05 44.248 12 3.687 - - - 88.628 14 - - - - 5% *: Significant at 5 percent level of significance Table 9: Summary Table Brand V C Cm C. D (critical difference) Mean 3.15 2.98 6.72 1.21 Discussion The most important goal in modern dentistry is to restore colour and appearance of natural dentition5. Due to superior optical properties, ceramics have become a standard application as a dental restorative material to mimic natural tooth esthetics6. A large number of studies have shown the variation in shade due to the type of metal alloy7,8, shade selected9,10, brand and batch of porcelain11, firing temperature and number of firings12, as well as thickness of the porcelain layer13,14. Minimizing one or more of these errors will overall help in duplication of more acceptable shades for the patient. In such scenario, instrumental color analysis offers potential advantages over visual color determination. Vita lumin shade guide is the most widely used standard for shade selection in dentistry worldwide in spite of its many drawbacks2, 15. The particle size of the porcelain is known to affect the perceived colour by affecting the scattering property, as small particles scatter less light than big particles. These 2 properties, the smooth surface topography and the small particle size, are thought to be responsible for the better colour quality and reproducibility. One of the objectives of this study was to evaluate the shade difference when A2 shades of 3 different brands of porcelain were fired on the same metal. This difference is due to the different concentration of shade pigments used by the manufacturers. The 3 porcelain brands differed significantly from each other mostly in their amount of yellow saturation. In our study observation of Chroma of all three samples (Ceramco 3, Ceramax and VitaVMK 95) was statistically insignificant in terms D.RG (Red and Green). Batch to batch variation of porcelain may necessitate the fabrication of customized shade tabs with fresh batch of porcelain11,17. In our study, observation of Chroma of all three samples (Ceramco 3, Ceramax and Vita VMK 95) varied and significant in terms of D.YB (yellow and blue) where as in other studies, the yellowness increased with thickness and shade of opaque. Their observation showed difference (0.05) due to difference in thickness in porcelain and also due to different types of condensation techniques16,18. Also difference in D.L lightness (value) has been seen between 3 samples of experimental group of porcelain and was statistically insignificant. In our study D.E The specimens were made manually and there is bound to be difference within an experimental group, which contained five samples, each fired on the same metal with different brand of porcelain. This error is mostly due to difference in condensation of the porcelain as any air bubbles incorporated usually influences the shade16. The Vita VMK 95 experimental group samples presented the minimum deviation in D.E, D.L among all the groups i.e. it was least technique sensitive. The Ceramco 3 experimental group samples presented minimum deviation in D.YB and Ceramax experimental samples group presented minimum deviations in D.RG group. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 108 (difference) in all three samples (Vita VMK 95, Ceramax, Ceramco3) were subjectly observed and statistically insignificant. The experimental group which came closest to the shade tab was VitaVMK 95 samples, as the saturation of the colouring oxides are under the control of the same manufacturer both in shade guide and porcelain powder3.The largest error was seen with Ceramax. The operator using porcelain should posse sufficient knowledge so that the best judgment can be exercised in the selection of physical and chemical property of different types of material. Conclusions 7. Hammad IA, Stein RS. The qualitative study for the bond and color of ceramometals, Part. II. J Prosthet Dent 1991; 65:169.-79. 8. Groh CL, O’Brien WJ, Boenke KM. Differences in color between fired porcelain and shade guides. Int J Prosthodont 1992;5:510-4. 9. Seghi RR, Johnston WM, O’Brien WS. Spectrophotometric analysis of color differences between porcelain systems. J Prosthet Dent 1986;56:35-40. 10. Bolt RA, Bosch JJ, Coops JC. Influence of window size in small-window colour measurement, particularly of teeth. Phys Med Biol 1994;39:1133-42. 11. Jorgenson MW, Goodkind RJ. Spectrophotometric study of five porcelain shades relative to the dimensions of color, porcelain thickness, and repeated firings. J Prosthet Dent 1979; 42:96-105. 12. Rade P, Dragutin S, Ljiljana A et al. Problems in standard shade matching and reproduction procedure in dentistry, A review of the state of the art. The scientific journal Facta Universitatis 1997; 4(1):12-16. 13. Barghi N, Lorenzana RE. Optimum thickness of opaque and body porcelain. J Prosthet Dent. 1982; 48:429-31. 14. Evans DB, Barghi N, Malloy CM, Windeler AS. The influence of condensation method on porosity and shade of body porcelain. J Prosthet Dent 1990;63:380-9. 15. Paul S, Peter A, Pietrobon N, Hammerle CH. Visual and spectrophotometric shade analysis of human teeth. J Dent Res 2002;81: 578-82. 16. Carlson GE, Wagner IV, Odman P et al. An international comparative multicenter study of assessment of dental appearance using computer-aided image manipulation. Int J Prosthodont 1998; 11:246-54. 17. Goetzen N, Gerd N, Michael MM et al. Analysis of all ceramic fixed partial dentures. Summer Bioengineering Conference; Sonesta Beach Resort in Key Biscayne, Florida 2003; June 25-29. 18. Dozic A, Kleverlaan CJ, Meegdes M, Van der Zel J, Feilzer AJ. The influence of porcelain layer thickness on the final shade of ceramic restorations. J Prosthet Dent 2003;90:563-70. 1. Samples made with different brands of porcelains have noticeably different shades despite having same Vita Lumin shade guide. 2. Different brands of porcelain differ from each other more in redness and yellowness. 3. Different brands of porcelain differ from each other more in lighter than darker shades. References 1. 2. Kourtis SG, Tripodakis AP, Doukoudakis AA. Spectrophotometric evaluation of optical influence of different metal alloys and porcelain in the metal ceramic complex. J Prosthet Dent 2004; 92:477-85. Ishikawa-Nagai S, Ishibashi K,Tsuruta O, Weber HP. Reproducibility of tooth color gradation using a computer color-matching technique applied to ceramic restoration. J Prosthet Dent 2005; 93: 129-37. 3. Miller L. Organizing color in dentistry. J Am Dent Assoc 1987 Spec No: 26E-40E. 4. Seghi RR, Johnston WM, O’Brien WJ. Performance assessment of calorimetric devices on dental porcelain. J Dent Res 1989;68:1755-9. 5. Brewer JD, Akers CK, Garlapo DA, Sorensen SE. Spectrometric analysis of the influence of metal substrates on the color of metal-ceramic restorations. J Dent Res 1985 64:74-7. 6. Crispin BJ, Seghi RR, Globe H. Effect of different metal ceramic alloys on the color of opaque and dentin porcelain. J Prosthet Dent 1991;65:351-6. 109 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 110-114 Original Article Dental arch length and arch symmetry analysis of Nepalese permanent dentition Shrestha RM1, Bhattarai P2 1 Consultant Orthodontist, Kathmandu Model Hospital, 2Consultant Orthodontist, The Orthodontic Center Abstract Objective: To study the dental arch lengths at canines and first molars of permanent dentitions of Nepalese adults using Lavelle’s method. Materials and methods: Dental stone models of one hundred subjects with normal occlusion and dentofacial proportion were studied using standard Boley gauze. The study compared gender differences among the Nepalese adults as well as between the Nepalese and Caucasian samples. Results: Arch lengths of the Nepalese males were significantly greater than those of the females at all parameters studied except at mandibular canine. The arch lengths of the Nepalese adults were significantly greater than those of the Caucasians except at mandibular canine. Conclusion: Significant variation between left and right sides of the dental arch lengths at mandibular canine region suggest asymmetry of dental arch among Nepalese adults. Key words: Arch length, Arch Symmetry, Lavelle’s method Introduction Lavelle1 in 1971 defined dental arch length as the oblique dimension measured between the most mesial aspect of anterior teeth and the most distal aspects of posterior teeth. The dental arch length denotes the sagittal dimension of the dental arch from most anterior reference point to the posterior surface. Various researchers have measured the dental arch length differently; and many consider arch length and arch depth synonymously. Other researchers including Burris2, DeKock3, and Barrett4 measured arch length at mid-palatal line. Sanin5 estimated dental arch length using fourth degree polynomial formula. The study on dental arch symmetry is of interest to orthodontists from functional as well as esthetic point of view. Historically Gruenburg11 in 1912 devised “symmetroscope” to measure the symmetry of the dental arch; later Friel12 modified it as a transparent celluloid sheet with ruled squares. Lu13 in 1964 studied the symmetry of dental arch using orthogonal polynomial analysis. BeGole14 suggested cubic spline curve as an ideal means to represent the asymmetry of the dental arch. Comparing left and right sides of the dental arch has been the most common method to describe the arch asymmetry. Lavelle & Plant15 compared right and left sides of the dental arch with normal occlusion to analyze arch symmetry using traveling microscope. Anthropologists believe that different racial types have differently shaped dental arches. Williams6 in 1917 stated that arches vary slightly to harmonize with different racial types, and the variability within a racial type is extremely less. Laine7 showed that, arch length did not differ from one Caucasoid population group to another of same age range. Buris2, Merz8 found that the Black subject's arches were longer compared to Whites. Confirming the general observation, most of the researchers including Barrett4, Bishara9, and Huang10 found greater dimension of arch length in males compared to females. The racial, sexual and symmetrical variations in dental arch lengths are thus deemed important to be analyzed for permanent dentition of the Nepalese adults. The study is believed to be useful for orthodontic, odontometric and anthropometric purposes. Materials and methods The sample consisted of dental stone cast of one hundred Nepalese adults aged 17 to 32 years; with Correspondence Dr. Rabindra Man Shrestha, Consultant Orthodontist, Kathmandu Model Hospital, Kathmandu E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 110 equal female to male ratio. The sampling was based on inclusion criteria established for the research. The samples possessed all permanent teeth (with or without third molars), Angle’s Class I molar and canine relationships, normal overjet and overbite, orthognathic skeletal and facial profile. The subjects were selected among the patients who visited to the Dental Center of Kathmandu Model Hospital and among the participants of dental camp organized by the same center. When comparing the arch lengths between Nepalese females and males, all mean values of the males were significantly greater than those of the females at all dimensions except for the mandibular arch length at canine on the left side (Table 4 and Table 5). When comparing the difference between Nepalese females and males for the average of right and left arch lengths, all dimensions were greater in males except for arch length at mandibular canine (Table 6). The measurement of dental arch length followed the method described by Lavelle et al1. The dimensions were measured between the mesial line angles of the central incisors to the distal contact point of the canine and to the distal contact point of first molar in oblique direction on both right and left sides (Fig 1). The measurements were performed directly on maxillary and mandibular casts using standard Boley gauge (Dentaurum Munchner model) of 0.1 mm accuracy. Table 7 shows that the mandibular arch length at canine on left side is significantly greater than that on the right side of the combined Nepalese females and males. The study shows that all arch length measurements except at the mandibular canine length were greater in Nepalese compared to the Caucasian samples (Table 8). Table 9 illustrates the comparative arch lengths of Nepalese adults with other racial groups as reported by Lavelle. The samples were analyzed for the statistical difference between female and male sexes, and between the Nepalese and Caucasian (British) samples. The mean arch lengths were compared between right and left sides to analyze the symmetry of the dental arch. The data were also compared with Cucasians, Australian aboriginies, Negroid and Mongoloid races as reported by Lavelle1. The statistical analysis was performed using Student’s t-test at the level of significance of 0.05. Result A descriptive statistics of the mean arch lengths of Nepalese female, male, and combined female and male subjects are presented in Table 1, Table 2, and Table 3 respectively. The data also show the average of the right and left dimensions. Fig 1: Dental arch length reference points Table 1: Descriptive statistics for the arch lengths of Nepalese females (in mm) Right Mx Md Left Average Mean SD Range Mean SD Range Mean SD Range I1 – C 22.17 1.02 4..80 22.10 1.07 5.30 22.14 1.04 5.05 I1 – M1 43.23 1.54 6.80 43.33 1.71 8.30 43.28 1.60 7.55 I1 – C 16.96 0.77 3.50 17.09 0.75 3.40 17.03 0.74 3.40 I1 – M1 39.00 1.52 7.80 39.11 1.47 7.30 39.05 1.47 7.55 Table 2: Descriptive statistics for the arch lengths of Nepalese males (in mm) Right Mx Md Left Average Mean SD Range Mean SD Range Mean SD Range I1 – C 22.68 1.14 4.60 22.67 1.08 4.30 22.68 1.09 4.45 I1 – M1 44.41 1.98 8.80 44.33 1.92 8.30 44.37 1.93 8.50 I1 – C 17.31 0.92 3.60 17.40 0.91 4.00 17.36 0.90 3.70 I1 – M1 40.01 1.67 7.00 40.12 1.91 8.10 40.06 1.77 7.30 111 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Table 3: Descriptive statistics for the arch lengths of combined Nepalese females and males (in mm) Right Mean Mx Md SD Left Range Mean SD Average Range Mean SD Range I1 - C 22.43 1.11 5.70 22.39 1.11 5.50 22.41 1.09 5.60 I1 – M1 43.82 1.86 8.80 43.83 1.88 9.20 43.83 1.85 8.75 I1 - C 17.13 0.86 3.80 17.25 0.85 4.00 17.19 0.84 3.85 I1 – M1 39.50 1.67 7.80 39.61 1.77 9.00 39.56 1.70 8.05 Table 4: t-Test of significance for the difference between the mean arch lengths of Nepalese females and males on right side Female Mx Md Male p-value Significance Mean S.D. Mean S.D. I1 – C 22.17 1.02 22.68 1.14 0.021 * I1 – M1 43.23 1.54 44.41 1.98 0.001 *** I1 – C 16.96 0.77 17.31 0.92 0.038 * I1 – M1 39.00 1.52 40.01 1.67 0.002 ** (* P ≤ 0.05, ** P ≤ 0.01, *** P ≤ 0.001) Table 5: t-Test of significance for the difference between the mean arch lengths of Nepalese females and males on left side Female Mx Md Male Mean S.D. Mean S.D. p-value Significance I1 – C 22.10 1.07 22.67 1.08 0.009 I1 – M1 43.33 1.71 44.33 1.92 0.007 ** I1 – C 17.09 0.75 17.40 0.91 0.066 NS I1 – M1 39.11 1.47 40.12 1.91 0.004 ** ** (NS = not significant, ** P ≤ 0.01) Table 6: t-Test of significance for the difference between the sexes for the average of right and left arch lengths Female Mean Mx Md Male S.D. Mean S.D. p-value Significance I1 – C 22.14 1.04 22.68 1.09 0.012 * I1 – M1 43.28 1.60 44.37 1.93 0.003 ** I1 – C 17.03 0.74 17.36 0.90 0.051 NS I1 – M1 39.05 1.47 40.06 1.77 0.003 ** (NS = not significant, * P ≤ 0.05, ** P ≤ 0.01) Table 7: t-Test of significance for the difference between right and left arch lengths of combined Nepalese females and males Right Mean Mx Md Left S.D. Mean S.D. p-value Significance I1 – C 22.43 1.11 22.39 1.11 0.361 NS I1 – M1 43.82 1.86 43.83 1.88 0.879 NS I1 – C 17.13 0.86 17.25 0.85 0.001 *** I1 – M1 39.50 1.67 39.61 1.77 0.062 NS (NS = not significant, *** P ≤ 0.001) J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 112 Table 8: t-Test of significance for the difference between the arch lengths of Nepalese and Caucasian subjects Caucasian (Lavelle, 1971) Mean Mx Md Nepalese (Shrestha, 2009) S.D. Mean p-value Significance S.D. I1 – C 17.7 1.16 22.41 1.09 0.000000 *** I1 – M1 36.9 0.82 43.83 1.85 0.000000 *** I1 – C 17.5 1.18 17.19 0.84 0.082809 NS I1 – M1 38.5 0.29 39.56 1.70 0.000141 *** (NS = not significant, *** P ≤ 0.001) Table 9: Comparative arch lengths of Nepalese and other racial groups Caucasian (Lavelle, 1971) Mx Md I1 - C Australian Aborigine (Lavelle, 1971) Negroid (Lavelle, 1971) Mongoloid (Lavelle, 1971) Nepalese (Shrestha, 2009) Mean SD Mean SD Mean SD Mean SD Mean SD 17.7 1.16 18.6 1.12 22.7 0.58 18.2 0.56 22.4 1.09 I1 – M1 36.9 0.82 47.7 0.53 38.9 0.53 36.0 0.53 43.8 1.85 I1 - C 17.5 1.18 18.1 1.11 17.8 0.63 18.8 0.49 17.2 0.84 I1 – M1 38.5 0.29 38.8 0.57 38.4 1.13 39.0 0.47 39.6 1.70 Discussion The odontometric or anthropometric study of dental arch is best performed among adults. Proffit16 noted a definitive sequence of jaw growth in three planes of space. The growth of the dental arch width is completed first, followed by arch length, and finally growth in arch height takes place. DeKock,3 Sinclair,17 Bishara,18 and Harris19 reported decrease in dimension of arch length with the attainment of adulthood, then after the dental arch attains the stable dimension. observed the dimensions of the teeth and arch lengths on right side were greater than those on the left, but the differences were insignificant. Bishara, Jacobsen et al.18 however found no significant differences between right and left sides in arch length measurement. The present analysis showed that the mandibular arch length at canine region was significantly greater on left side. The apparent bilateral differences on arch dimensions show that the Nepalese dental arch with normal occlusion is dimensionally asymmetrical. The present study is in agreement with the findings of Barrett4, Bishara9, and Huang10 confirming that arch lengths of the males were greater than those of the females. The present study is also consistent with the contemporary studies on arch width20 and arch circumference21 of the Nepalese adults; which reported that arch dimensions of the Nepalese males were significantly greater as compared to females. Kanazawa24 observed significant correlation between the size of the teeth and length of the dental arch. However present study is not consistent with such finding. The present study found greater dimensions of arch length on left side contrarily another study25 on mesio-distal tooth diameter of Nepalese adults show most of the tooth dimensions significantly wider on right side. Thus these facts imply that the arch lengths are not dependent on mesio-distal crown diameters. The racial variation in arch length is also evident from the present study. The arch lengths of the Nepalese adults were significantly greater than those of the Caucasians suggesting the longer dental arch sagitally. This finding is consistent with the cephalometric study22 on Nepalese adults which reported that both maxilla and mandible in relation to cranial base were positioned more anteriorly with greater SNA and SNB angles. Conclusion Most theories consider dental arch forms to be symmetrical. White23 however observed a great deal of asymmetry in the dental arches. Lavelle & Plant15 113 • Dental arch lengths of Nepalese males are significantly greater than those of the females for both maxillary and mandibular canine and first molar dimensions except at mandibular canine on left side. • Average of the left and right arch lengths of the Nepalese males are significantly greater than those of the females for all dimensions except at mandibular canine. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 • • Mandibular arch length at canine on left side is significantly greater than that on the right side of the combined Nepalese adults suggesting asymmetry of the dental arch at the region of mandibular canine. All arch length measurements of the Nepalese adults were significantly greater than those of the Caucasians except at the mandibular canine. References 1. 2. Lavelle CL, Foster TD, Flinn RM. Dental arch in various ethnic groups. Angle Orthod. 1971;41:293-9 Burris BG, Harris EF. Maxillary arch size and shape in American Blacks and Whites. Angle Orthod. 2000;70:297302. 12. Friel S. The diagnosis of malocclusion of the teeth. Dent Cosmos 1914;56: 825-32. 13. Lu KH. An orthogonal analysis of the form, symmetry, and asymmetry of the dental arch. Arch Oral Biol 1966;11:1057-69. 14. Begole EA. A computer program for the analysis of dental arch form using the cubic spline function. Comput Programs Biomed 1979;10:136-42. 15. Lavelle CLB, Plant CG. Comparison between the right and left sides of the dental arch. J Dent Res 1969;48:971. 16. Proffit WR. Contemporary orthodontics. 2nd ed., MosbyYear Book Inc: 1997; p. 93. 17. Sinclair PM, Little RM. Maturation of untreated normal occlusions. Am J Orthod 1983;83:114-23. 18. Bishara SE, Jakobsen JR, Treder JE, Stasi MJ. Changes in the maxillary and mandibular tooth size-arch length relationship from early adolescence to early adulthood. A longitudinal study. Am J Orthod Dentofacial Orthop. 1989;95:46-59. 3. DeKock WH. Dental arch depth and width studied longitudinally from 12 years age to adulthood. Am J Orthod. 1972;62:56-66. 4. Barrett MJ, Brown T, Macdonald MR. Size of dental arches in a tribe of Central Australian aborigines. J Dent Res 1965;44:912-20. 19. 5. Sanin C, Savara BS, Thomas DR, Clarkson QD. Arc length of the dental arch estimated by multiple regression. J Dent Res 1970;49:885. Harris EF. A longitudinal study of arch size and form in untreated adults. Am J Orthod Dentofacial Orthop, 1997;111:419-427. 20. 6. Williams PN: Determining the shape of the normal arch. Dental Cosmos 1917;59:695-708. Shrestha RM, Bhattarai P. Dental arch width of Nepalese adults using Lavelle’s method. J Nep Dent Assoc, 2008;9:7-14. 7. Laine T, Hausen H: Alveolar arch dimensions, orthodontic treatment and absence of permanent teeth among Finnish students: An epidemiologic study. Angle Orthod, 1985;55:225-33, 249-50. 21. Shrestha RM, Bhattarai P. Dental arch circumference of Nepalese adults: A dimorphic study. Dent Nepal, 2008;3:52-3. 22. Bhattarai P. Steiner’s cephalometric analysis of Nepalese adults aged 18 to 30 years. J Nep Dent Assoc 2005;7:19. 23. White LW. Accurate arch discrepancy measurements. Am J Orthod. 1977;72:303-8. 8. Merz ML, Isaacson RJ, Germane N, Rubenstein LK. Tooth diameters and arch perimeters in a black and a white population. Am J Orthod Dentofacial Orthop 1991;100:53-8. 9. Bishara SE, Treder JE, Damon P, Olsen M. Changes in the dental arches and dentition between 25 and 45 years of age. Angle Orthod 1996;66:417-22. 24. Kanazawa E, Sekikawa M, Ozaki T. Correlations between the dimensions of human teeth, the dental arch and the mandible. J Nihon Univ Sch Dent 1987;29:165-79. 10. Huang ST, Miura F, Soma K.. A dental anthropological study of Chinese in Taiwan (2). Teeth size, dental arch dimensions and forms. Gaoxiong Yi Xue Ke Xue Za Zhi 1991;7:635-43. 25. Shrestha RM. Measurement of mesio-distal tooth diameter of Nepalese permanent dentition. J Nep Dent Asso 2005;7:55-63. 11. Gruenburg J. The symmetroscope: An apparatus for measuring the symmetry or asymmetry of dental arches. Dent Cosmos 1912;54:490-91. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 114 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 115-118 Original Article Co-relation between the pattern of impaction of mandibular third molars with their associated pathologies Nyachhyon P1, Mahat A2 Assistant Professor, 2Demonstrator, Department of Oral & Maxillofacial Surgery, People’s Dental College & Hospital, Naya Bazar, Kathmandu, Nepal 1 Abstract Objective: The purpose of this study was to assess the pathologies associated with the different patterns of impacted mandibular third molars and significance of its prophylactic removal. Study Design: A descriptive non-randomized case series study was carried out in a total of two hundred patients presenting with mandibular 3rd molar impactions in the Department of Oral and Maxillofacial Surgery, People's Dental College & Hospital. Result: Pericoronitis (31%) was mainly seen in patients below 30 yrs and associated commonly with vertical impaction whereas dental caries in adjacent 2nd molar was seen in older patients and with mesioangular impaction. Anterior teeth crowding was observed mainly with mesioangular impaction(43%). Cysts (3%) and tumor (<1%) were least common findings associated with impacted third molar. Conclusion: The presence of disease associated with third molar teeth is an indication for their removal but ‘prophylactic’ removal remains controversial. It is not mandatory to remove lower wisdom tooth simply because they are impacted. Each case is considered individually to balance the benefits and risks of both retention and extraction and to plan the treatment accordingly. Key words: Impacted third molar, Pericoronitis, Prophylactic removal Prophylactic removal vs. Non-Extraction Debates exist whether to remove the impacted molars before they become symptomatic. Advocacy for prophylactic removal are based on to avoid the possible pathologies and to facilitate early healing. Impacted third molar can lead to diverse pathologies3 and have been implicated in infections, periodontal problems, resorption of 2nd molars, cysts and tumors of mandible4, lower arch crowding, TMJ disorders and neuralgias5. Removal of the impacted lower third molars has also shown to reduce the incidence of fracture at the angle of mandible4. Whereas retaining the tooth, patients will avoid undue surgical discomfort, prolonged recovery time, increased expense as well as damage to the adjacent vital structures and bony support3. Introduction Impacted wisdom tooth is a common finding in general dental practice and the removal of the third molars in young adults is the common surgical intervention. Incidence of impacted third molars is more common in the mandible (90%) than the maxilla and the rising number of incidence of the impacted tooth is making it a public health problem1. However controversy persists with respect to the associated pathologies and the need for removal of the impacted wisdom tooth. The proportion of third molars that are removed when no disease is present is reported to be between 18% and 40%2. Prophylactic third molar surgery is based on the concept of minimizing the future risk of disease and surgical morbidity in older patients. Risk benefit ratio and socio-economical considerations need to be taken into account before a decision is made to remove the impacted third molar, and if extraction has been decided as the treatment option, one should know why, when and how. Study design A descriptive study was carried out in a total of two hundred patients presenting with mandibular 3rd molar impactions in the Department of Oral and Maxillofacial Correspondence Dr. Pawan Nyachhyon, Assistant Professor, Department of Oral & Maxillofacial Surgery, People’s Dental College & Hospital, Naya Bazar, Kathmandu, Nepal, E-mail: [email protected] 115 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Surgery, People's Dental College & Hospital. The selection criterion was non-randomized including all cases of mandibular 3rd molar impactions (irrelevant of age and sex) presenting in the department. dental caries was more frequent in older patients. Among the impactions, mesioangular impactions (42%) were more common followed by horizontal (26%), vertical (24%) and distoangular impactions (8%) (Fig 5). The exclusion criteria for the study were cases in which the adjacent second molars were absent, the patients requiring full mouth extractions including mandibular 3rd molar due to other reasons and patients who were not willing for extraction. Pericoronitis (31%) was the most commonly seen pathology followed by other periodontal problems (12%) and dental caries in the adjacent second molar (12%). Facial infections like cellulites and osteomylites were less common (4%) (Fig 6). A standard history and clinical examination was carried out in all patients and an Intraoral periapical radiograph and/or Orthopantomogram were made as investigations. A specially designed proforma was filled and the location, angulation, depth, relationship to ramus and the associated pathologies were noted. All the data collected was entered in SPSS version 10 and results were analyzed accordingly. Pericoronitis (Fig 7) was the most commonly associated pathology in 80% of vertical, 60% of horizontal, 52% of distoangular and 23% of mesioangular impactions (Fig 8). Lower anterior crowding was associated with 43% of mesioangular, 18% of distoangular, 15% of horizontal and 5% of vertical impactions (Fig 8). Most patients below 20 years old underwent surgical extraction of the impacted tooth for orthodontic purpose. Results There was more or less equal distribution of male (49%) and female (51%) patients (Fig 1). Unilateral (49%) and bilateral (51%) impactions were almost equally distributed (Fig 2). Impacted third molars were more common on the right side of the mandible (58%) (Fig 3). Caries in the adjacent second molar (Fig 9) was seen in 22% of mesioangular and 15% of horizontal impactions; and no carious lesions were seen in vertical and distoangular impactions. Dentigerous cysts (Fig 10) and odontogenic keratocyst were found in 3% of the patients and tumor (ameloblastoma) (Fig 11) was evident in 1% of all the impacted mandibular third molars. 23% of the patients were less than 20 years old, 59% of the patients were aged between 21-30 years, 13% patients were between 31-40 years old and only 5% were more than 40 years old (Fig 4). Pericoronitis was more common in the younger age group (< 30 yrs) while Left 42% Female Male 49% 51% Right 58% Fig 3: Location of impacted teeth Fig 1: Distribution of male and female patients 31-40 yrs 13% Unilateral 49% >40 yrs 5% Bilateral 51% 21-30 yrs 59% Fig 2: Distributio of location of impacted third molar (Unilateral vs. Bilateral) J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Fig 4: Distribution of age groups 116 <20 yrs 23% 40% 35% 30% 25% 20% 10% 5% 0% mesioangular vertical 25% 12% 12% 6% 4% 4% pe pe ric rio or on do it i nt s al po ck ca et rie s ad s/ jt p ul oo pi th tis /ro ot an ca te r ie r io s rc ad r ow jr oo di fa ng tr sc es ia or ls pt pa io ce n in fe ct io n 15% 31% horizontal distoangular Fig 5: Distribution of types of impactions 6% ot he rs 35% 30% 25% 20% 15% 10% 5% 0% 45% Fig 6: Distribution of associated pathologies 8 80 7 70 mesioangular 6 60 horiz zontal 5 50 vertical 4 40 disto oangular 3 30 2 20 10 0 perio/p pericoronitis Fig 7: Pericoronits ant. crowd ding caries/pulpitis adj. tootth caries others Fig 8: Common associated pathologies of the patterns of impaction Fig 9: Caries in distal of adjacent 2nd molar Fig 10: Dentigerous cyst Fig 11: Ameloblastoma 100% 90% 80% 70% 60% <20 50% 21-30 40% 31-40 30% 20% 40+ 10% 0% perio/infection anterior crowding adj tooth/root caries cysts ameloblastoma Fig 12: Common causes of extraction in different age groups 117 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Discussion Our study showed more or less equal incidence of unilateral and bilateral impactions of mandibular third molars also almost equal distribution between both sexes. However, the right mandibular wisdom tooth was more frequently impacted than the left. Mesioangular impaction (42%) was the most common pattern of impaction while distoangular impaction (8%) was the least common. removal of impacted third molar teeth for prevention of disease. Since the incidence of serious pathologies is not very common, it is not mandatory to remove impacted lower wisdom tooth simply because they are present. The symptoms suffered by the patients, signs noted by the clinicians and the risk of future problem must outweigh the potential morbidity of the surgical extraction procedure. The patient must be in possession of sufficient information to make his decision. In a patient with good oral hygiene, a wait and see policy with regards to impacted 3rd molar is prudent than prophylactic removal. A majority of the patients presenting with impacted lower third molar were aged between 20-30 years while 5% of the patients were more than 40 years old. Pericoronitis has been widely reported as the main reason for extraction of lower third molars6. In our study, most of the young patients underwent extraction for orthodontic purpose and due to repeated pericoronitis (31%) while dental caries (12%) was most common in the older group. Several authors have suggested that there is a close correlation between the risk of acute disease and the angulation and degree of impaction of third molars7. Our findings are in conformity with their studies. Recommendation It is recommended to consider each case individually, to balance the benefits and risks of both retention and extraction and to plan the treatment accordingly. Whenever the non-extraction strategy is adopted, long-term clinical and radiographic checks should be maintained, so that surgical intervention can be instituted as soon as pathology starts to develop. Facial infections like cellulites and osteomylites were found to be less common (4%) and the occurrence of more serious pathologies like cysts (3%) and tumors (1%) were low in our study., A number of studies have supported the role of 3 rd molars in crowding of the lower arch 8. 25% of impacted third molars were extracted for orthodontic purposes to relief anterior crowding. References In Obiechina’s study3, 57.51 % of impacted teeth were associated with pathology. Out of these, 42.9 % were cases of pericoronitis and periodontal disease, 13.9 % were carious and 0.63 % were associated with cysts. In a study conducted by Guven4 on 9994 impacted third molars, 3.10 % were associated with some sort of cyst (2.31%) or tumour (0.79 %). Out of these cases, 68 % of the cysts were in mandible, out of these 93 % were cases of dentigerous cysts and 7 % of odontogenic keratocysts. The presence of tumours in mandibular impacted third molars were 92 % of the total number of tumours associated with impacted molars. Bruce reported an incidence of 6.2% of cysts and tumours developing around impacted mandibular third molars and the incidence was notably highest (13.3 %) in the oldest age group (mean age 46.5 years)9. Conclusion Although there is general agreement by dentists and oral surgeons that the presence of disease associated with third molar teeth is an indication for their removal, ‘prophylactic’ removal remains controversial. There is currently little scientific evidence to support routine J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 118 1. Quek SL, Tay CK, Tay KH, Toh SL, Lim KC. Pattern of third molar impaction in Singapore Chinese: a retrospective radiographic survey. Int J Oral Maxillofac Surg 2003; 32: 548-52. 2. Liedholm R, Knutsson K, Lysell L Rohlin M. Mandibular third molars: oral surgeons’ assessment of the indications for removal. Br J Maxillofac Surg 1999;37:440-3. 3. Obienchina AE, Arobita JT, Fasola AO. Third moar impaction: evauation of the symptoms and pattern of impaction of mandibular third molar teeth in Nigerieans. Odontostomatol Trop 2001; 24: 22-5. 4. Guven O, Keskin A, Akal UK. The incidence of cysts and tumors around third molars. Int J Oral Maxiilofac Surg 2000; 29: 131-5. 5. Glosser JW, Campbell JH. Pathological changes associated with radiographically ‘normal’ third molar impaction. Br J Maxillofac Surg 1999;37:259-60. 6. Nordenram A, Hultin M, Kjellman O, Ramstrom G. Indications for surgical removal of mandibular third molar. Study of 2,630 cases. Swed Dent J 1987;11:23-9. 7. Knutsson K, Brehmer B, Lysell L, Rohlin M. Pathoses associated with mandibular third molars subjected to removal. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 1996; 82:10-7. 8. Lysell L, Rohlin M. A study of indications used for removal of mandibular third molars. Int J Oral Maxillofac Surg 1988;17:161-4. 9. Bruce RA, Frederickson GC, Small GS. Age of patients and morbidity associated with mandibular third molar surgery. J Am Dent Assoc 1980;101:240-5. Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 119-121 Original Article Comparison of duration of orthodontic treatment with and without extraction among orthodontic patients Bhattarai P1, Shrestha RM2, Mishra P3 1 Associate Professor, 2Assistant Professor, Kantipur Dental College and Hospital, 3Professor, National Academy of Medical Sciences Abstract Objective: To compare the effectiveness and duration of orthodontic treatment between Nepalese orthodontic patients with extraction and with non-extraction treatment basis. Materials and methods: A total of two hundred orthodontic patients with proportional number of patients treated on extraction and non-extraction basis were evaluated from two exclusive orthodontic practice centers. All patients were treated with Straight Wire brackets. Transferred patients and previous orthodontically treated patients were excluded from the study. Result: The average duration of orthodontic treatment was 28.5 months for all orthodontic patients with no statistical difference between the extraction and non-extraction groups. The study however found that the treatment for those with extraction cases were more likely to take longer duration clinically than the non-extraction cases. Key words: Duration, Extraction, Non-extraction Introduction The extraction versus non-extraction debate is one of the earliest and most lasting philosophic controversies of orthodontic practice with both biologic and mechanical ramifications1-3. In clinical practice many orthodontic patients are obviously concerned about the duration of time that they will be required to wear fixed orthodontic appliances. Estimates of treatment duration would also be useful to clinicians for efficient office management. Treatment duration is affected by several variables4 such as treatment basis (extraction vs. non-extraction), sex (male vs. female), age group (adolescent vs. adult), and malocclusion type. Furthermore, other variables like missing appointments, breakage of appliance, patient co-operation (i.e. wearing of elastic, bite plate etc.), number of dental arches treated, number of treatment phases etc. may also contribute to longer duration of orthodontic treatment. Most of the authors believe that the duration of orthodontic treatment mainly depend on patient co-operation5-7. treatment basis affect the duration of orthodontic treatment among Nepalese orthodontic patients. Materials and methods Orthodontic records were obtained from two exclusive orthodontic practice centers with subjects treated with Straight Wire appliance. A total of 200 patients comprising of 101 patients treated with extraction basis and 99 patients treated with non-extraction basis were analyzed for the study. 80 patient records were collected from Department of Orthodontics, People’s Dental College and Hospital (PDCH), Kathmandu, and 120 from The Orthodontic Center (TOC), Kathmandu. Consecutively treated cases starting from June 15, 2002 and completing by June 15, 2007 were evaluated. The start of treatment was defined as the date of first arch wire placement and completion of treatment as the date on which fixed appliances were debonded completely. Only those cases with complete pre-treatment and posttreatment records comprising of study models and written treatment records were included. Transferred cases, two The objective of the present study was to compare and evaluate how the extraction versus non-extraction Correspondence Dr. Prakash Bhattarai, Associate Professor, Kantipur Dental College and Hospital, Kathmandu E-mail: [email protected] 119 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 obvious clinical difference of 5.9 months between the extraction and non-extraction cases, there is however no statistical difference between them. The result shows that the obtained p-value of 0.08 is very near to the level of significance (0.05). phase treatment protocol patients, single arch treated patients and previous orthodontically treated patients were excluded from the study. All treatment duration were converted to nearest of months. All subjects were treated with Straight Wire appliance with Roth prescription of tip and torque. All bracket slots were 0.018 and brackets were placed at right angles to the long axes of the teeth. Round, square and rectangular arch wires were used as required; and elastics, headgear, ‘T’ loops, ‘L’ loops and key-hole loops were used routinely. The present data is supported by Chua et al10 whose mean treatment duration for the extraction group wass 33.9 months, which is longer than that of non-extraction group (25.6 months). The present data is also supported by Fink et al11 who found the extraction duration is longer than the non-extraction duration. It is interesting to note their finding that each premolar extraction adds 0.9 months of duration or 1.8 months for two premolar extraction case and 3.6 months for a case with four premolars extraction. Another interesting finding by him is that every degree increase in mandibular plane decrease the 0.3 months of duration of orthodontic treatment. In contrast to present finding, Vig et al4 found that the duration of extraction case is slightly shorter (31.2 months) than the non-extraction cases (31.3 months). All data were fed into SPSS software (version 12). The independent t-test was performed to compare the difference between the extraction and non-extraction treatment basis. The level of significance was set at 0.05. Result The result of the present study is shown in Table 1. The study shows that the mean duration of orthodontic treatment with extraction is 31.4 months and with non-extraction is 25.5 months respectively. The mean duration of orthodontic treatment for all orthodontic patients was 28.5 months with no statistical difference between the extraction and non-extraction groups. The study however found that the treatment for those with extraction cases were more likely to take longer duration clinically than the non-extraction cases. Summary and conclusion The average duration of orthodontic treatment was 28.5 months for all orthodontic patients with no statistical difference between the extraction and non-extraction groups. Differences in duration of treatment were apparent clinically when extraction and non-extraction patients were compared. Treatment for those who had tooth extractions were more likely to take longer period of time. Table 1: Treatment duration according to treatment basis (in months) Extraction 31.4 NonAverage extraction 25.5 28.5 Acknowledgement The Authors heartily acknowledge People’s Dental College and Hospital and its Department of Orthodontics for allowing us to use its data for the present research. We would also like to thank Ms. Abhigyna Adhikari for her help in statistical analysis procedure of the study. p-value Significance .081 NS (NS: not significant) Discussion The average duration of treatment among Nepalese orthodontic patients according to present study is 28.5 months. The result is shorter than the report given by Vig et al4, which reported a mean duration of 31 months; and longer than the report of Alger8 which reported a mean of 22 months. References Most of the authors believe that there is association between increase in duration of treatment and extraction of tooth for treatment purpose. It is so because those patients whose treatment procedures involve tooth extractions generally possess much severe malocclusion compared to those treated on non-extraction basis9. Table 1 shows average treatment duration of 25.5 months for non-extraction cases and 31.4 months for extraction cases with a difference of 5.9 months. Though there is J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 120 1. Angle EH: Malocclusion of the teeth.7th ed. Philadelphia: SS White Dental Mfg. Co.; 1907. 2. Case CS.: Dental orthopedia. Chicago: C. S. Case Co.; 1908. 3. Tweed CH: Indications for the extraction of teeth in orthodontic procedures. Am J Orthod Oral Surg 1944;30:405-28. 4. Vig PS, Weintraub JA, Brown C, Kowalski CJ: The duration of orthodontic treatment with and without extractions: a pilot study of five selected practices. Am J Orthod Dentofacial Orthop 1990;97:45-51. 5. Allan TK, Hodgson EW: The use of personality measurements as a determinant of patient cooperation in an orthodontic practice. Am J Orthod 1968;56:433-40. 6. Starnbach HK, Kaplan A: Profile of an excellent orthodontic patient. Angle Orthod 1975;45:141-5. 7. Slakter MJ, Albino JE, Fox RN, Lewis EA : Reliability and stability of the orthodontic patient cooperation scale. Am J Orthod 1980;78:559-63. 8. Alger DW: Appointment frequency versus treatment time. Am J Orthod Dentofacial Orthop 1988;94:436-9. 9. treatment. Am J Orthod Dentofacial Orthop 1995;107:32934. O’Brien KD, Robbins R, Vig KW, Vig PS, Shnorhokian H, Weyant R. The effectiveness of Class II, Division 1 121 10. Chua AL, Lim JY, Lubit EC: The effects of extraction versus nonextraction orthodontic treatment on the growth of the lower anterior face height. Am J Orthod Dentofacial Orthop 1993;104:361-8. 11. Fink DF, Smith RJ. The duration of orthodontic treatment. Am J Orthod Dentofacial Orthop 1992;102:45-51. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 122-124 Original Article Metronidazole for the prevention of dry socket after removal of impacted mandibular third molar in Nepalese patients Pant N1 1 Assistant Professor, Deptartment of Oral & Maxillofacial Surgery, Kantipur Dental College & Hospital, Kathmandu, Nepal Abstract Aim: The main purpose of the study was to see whether Metrodinazole plays a role in reducing the incidence of dry socket after extraction of mandibular third molars. Method: A total of 119 patients were evaluated out of which 59 patients were given a single dose of 1200 mg Metronidazole 45 minutes prior to the surgical extraction of third molar. The other 60 patients were not given any prophylactic dose of Metronidazole. Result: Out of the fifty nine patients who were given Metronidazole prior to the surgical procedure, 16.95% of the patients developed dry socket and among the other 60 patients who were not given Metronidazole, 21.67% developed dry socket. Conclusion: Metronidazole used as a prophylactic antibiotic for prevention of dry socket after extraction of mandibular third molars has little or no role in preventing dry socket. Key words: Third molar Surgery, Prevention Antibiotic prophylaxis Introduction Dry socket which is also known as Alveolitis Sicca Dolorosa, ASD or Alveolar Osteitis is a common complication after removal of teeth, particularly after surgical extraction of mandibular third molars. The incidence varies from a few percent to 68% depending on the location of the removed tooth/teeth1. It is a painful condition that usually occurs after few days following the removal of mandibular third molars and can be treated using antibiotics. Dry socket occurs when the blood clot at the site of extractions is dislodged, exposing the underlying bone and nerve endings causing significant pain. Patient presenting with dry socket can manifest any of the features like fever, severe jaw pain, facial swellings, and lymphadenopathy. menstrual cycle, smoking habits and prolonged use of antimicrobial drugs and mouth rinses can also have a role in the development of dry socket2-7. Aim and Objective The aim of this study was to see whether 1200 mg Metronidazole given as a single dose before extraction of impacted mandibular third molars reduced the incidence of dry socket. The 1200mg was chosen as the appropriate dose to ensure a high serum concentration of Metronidazole for a couple of hours after the surgical procedure. Method A total of 119 patients between 17- 30 years of age participated in the study. The patients were healthy and were not taking any other medications. All the 119 patients were treated within a period of 6 months.The patients were referred for removal of either unilateral and/or bilateral mandibular third molars and were treated at the Department of Oral and Maxillofacial Surgery, Kantipur Dental College, Basundhara, Kathmandu, Nepal. Even though the precise cause of dry socket remains the subject of study, researchers suspects several factors may be at play ,including bacterial contamination of socket, difficult or traumatic tooth extraction, remaining roots or tooth/root fragments in the socket, type of impacted teeth, presence of pericoronitis etc. Other factors such as age, gender, use oral contraceptives, Correspondence Dr. Neeraj Pant, Assistant Professor, Department of Oral & Maxillofacial Surgery, Kantipur Dental College & Hospital, Kathmandu, Nepal E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 122 of bone removed (depth and volume). The collected data have been presented using percentage, mean and t-test. A criteria for inclusion of the case was that a surgical flap had to be reflected for removal of the tooth/teeth. Patients with acute pericoronitis were treated only after the symptoms of pericoronitis had ceased. On the postoperative recall visit after five days, the following data were noted: The presence of pain, the amount of swelling, presence of any foul odour and/or alteration of taste, and the presence or absence of blood clot. The diagnosis of dry socket was done on the basis of the following criteria: Absence of blood clot in the tooth socket, and continuous increasing postoperative pain from second postoperative day onwards. Among the 119 patients, 1200 mg Metronidazole was given as a single dose to 59 patients and for the remaining 60 patients Metronidazole was not given. Three 400-mg tablets (1200mg), were taken orally 45 minutes before starting the surgical procedure. All extractions were done under local anesthesia using Lidocaine hydrochloride with 2% adrenalin. After giving the mandibular, lingual and the buccal nerve block, an incision was made from 37 / 47 and continued posteriorly beyond 38 / 48 upto the ascending ramus of the mandible, then the mucoperiostal flap was raised. If the tooth could not be extracted in one piece, it was split with surgical burs. During drilling of bone and tooth, a constant irrigation was done with sterile saline. After removal of the tooth, the socket was carefully cleaned using sterile saline and the mucoperiostal flap was repositioned and sutured using 3-0 silk non resorable suture. All the patients were given the same postoperative instructions, and were prescribed analgesic tablets for the following 5 days. Before starting the procedure the purpose of the study was fully explained to the patients and also a written detail of the procedure was provided to the patients. Statistical analysis and data Patient profile Out of the 119 patients, 52 (43.70%) were males and the remaining were females (60) (56.30). Twenty nine patients (24.37%) had a history of smoking and 41 patients (34.45%) had a history of pericoronitis. The details are shown in Table 1. Results Out of the 59 patients who were given Metronidazole, 10 (16.95%) developed dry socket and among the other 60 who did not take Metronidazole 13 (21.67%) developed dry socket. Thus, there is no evidence of difference in proportion of dry socket in patients who took and those who didn’t take Metronidazole. i.e. (P>0.05). The following data were recorded just before the surgical procedure: Age, sex, smoking habits and history of pericoronitis. The data recorded immediately after the operation were: The duration of extraction procedure, the amount of saline used for irrigation, and the amount Table 1: Comparison between the two groups: number of patients. Metronidazole group (n=59) Non Metronidazole group(n=60) Total Male 22 30 52 Female 37 30 67 Yes 14 15 29 No 45 45 90 Yes 21 20 41 No 38 40 78 Sex Smoking History of pericoronitis Amount of bone removed (mm³) None 2 6 8 1-10mm³ 22 22 44 11-20mm³ 23 21 44 >21mm³ 12 11 23 Yes 10 13 23 No 49 47 96 Dry socket 123 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 References Discussion Earlier studies of the efficacy of Metronidazole, with different designs, have shown different results. Ritzau et al9 showed no prophylactic effect of a single dose of 800mg Metronidazole, which was also seen in the present study. 1. Alexander RE. Dental extraction wound management : a case against medicating postextraction sockets. J Oral Maxillofac Surg 2000;58:538-51 2. Larsen P. Aveolar osteitis after surgical removal of impacted mandibular third molars. Oral Surg Oral Med Oral Pathol 1992;73:393-7. In an earlier study a higher incidence of dry socket was found after removal of partially erupted teeth than after the removal of impacted teeth (31% and 9%, respectively). Partially erupted lower third molar teeth have a pericoronal pouch, these pericoronal pouches may be heavily infected¹º. In infected pericoronal pouches there is mixed anaerobic and facultative anaerobic flora with large number of spirochetes, Porphyromonas species and other gram negative bacteria, and similar flora have also been found in the distal pocket of the adjacent second molars¹¹. These bacteria produce protease, have fibrinolytic activity¹² invade the surrounding tissue, and have other metabolic activities. For such gram negative bacteria, Metronidazole can be the drug of choice. 3. Chiapasco M, Crescentini M, Romanoni G. Germectomy or delayed removal of mandibular impacted third molars: the relationship between age and incidence of complications. J Oral Maxillofac Surg 1996;53:418-28. 4. Heasman PA Jacobs DJ. A clinical investigation into the incidence of dry socket. Br J Oral Maxillofac Surg 1984;22:115-22. 5. Sweet JB, Butler DP. Predisposing and operative factors: effects on the incidence of localized osteitis in mandibular third molar surgery. Oral Surg Oral Med Oral Pathol 1978: 44 14-20 6. Tjernberg A. Influence or oral hygiene measures on the development of alveolitis sicca dolorosa after surgical removal of mandibular third molars. Int J Oral Surg 1979; 8:30-4. The finding that a single dose of metronidazole was ineffective in preventing the development of dry socket seems to argue against a microbial aetiology of dry socket. However, recent findings on the increased antimicrobial resistance of bacteria organized in biofilms may explain this. The mechanism of this increased antibiotic resistance has not yet been established, but may be a result from the establishment of functional mixed-species consortia into bioflim, where the cells have a modified metabolism compared with that in their planktonic stage13. This was seen in another study where P. Gingivalis was 160 times more resistance to Metronidazole in vitro when grown as a biofilm than when grown in suspension14. 7. Kleinbaum DG. Logistic regression, a self-learning text. New York: Springer; 1992. 8. Rood JP, Murgatroyed J. Metronidazole in the prevention of dry socket. Br J Oral Maxillofac Surg 1979/1980;17:6270. 9. Ritzau M,Hillerup S, Branebjerg PE, Ersboel BK. Does metronidazole prevent alveolitis sicca dolorosa? Int J Oral Maxillfac Surg 1992;21:299-302. 10. Leung WK, Theilade E, Comfort MB, Lim PL. Micribiology of the pericoronal pouch in mandibular third molar pericoronitis. Oral Microbiol Oral Immunol 1993;8:30612. 11. Mombelli A, Buser D, Lang NP, Bertold H. Suzpected periodontopathogens in erupting third molar sites of periodontally healthy individuals. J Clin Periodontol 1990; 17: 48-54. 12. Cortellini P, Pini Prato G, Clauser C. Fibrinolytic activity of human gingival in the presence or absence of plaque bacteria. J Periodont Res 1992: 27; 34-9. 13. Gilbert P, Das J, Foley I. Bioflim susceptibility to antimicrobials. Adv Dent Res 1997;11:160-7. 14. Wright TL, Ellen RP, Lacrois JM, Sinnadurai S, Mittelman MW. Effects of metronidazole on Porphyromonas gingivalis bioflims. J Periodont Res 1997;32:473-7. Conclusion Although systemic antibiotics are regularly used after surgical procedures to prevent and cure infection of the surgical wound, the use of 1200 mg Metronidazole as a prophylactic antibiotic 45 minutes prior to the surgical procedure to prevent the development of dry socket after extraction of mandibular third molars is not necessary as it plays little or no role in the prevention of dry socket. However, if the extraction socket is infected, then Metronidazole along with other systemic antibiotics are commonly prescribed for reducing the infection. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 124 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 125-127 Case Note Calcium hydroxide in management of large periapical lesion Dixit PB1, Acharya S2, Prajapati I3 1 Lecturer, 3House Officer, Dental Department, Kathmandu Medical College, 2Lecturer, Dental Department, KIST Medical College Abstract The success of root canal treatment is based on total elimination of root canal content, thorough cleaning and shaping of canal and obturation of root canal system. Calcium hydroxide is recommended as intra-canal medicament because of its antibacterial properties, tissue dissolving ability, inhibition of tooth resorption and indication of tissue repair by hard tissue formation. Here we present a case report, where calcium hydroxide was used as an inter appointment endodontic dressing for management of large periapical radiolucency for six months. Follow up after six months of treatment completion revealed complete bone regeneration in the areas where there was extensive bone loss. Key words: Calcium hydroxide, Periapical lesion Introduction Periapical lesions in most of the cases can be classified as periapical granuloma, periapical abscess and periapical cysts and it cannot be differentiated from each other based on radiograph alone, although there is a trend towards increased incidence of cysts among larger lesions1. Dental trauma is often associated with the disruption of pulp blood supply, leading to pulp necrosis. This circulatory breakdown causes tissue necrosis and anaerobic conditions for the growth of opportunistic microorganisms2. The success of root canal treatment is based on total elimination of root canal content, thorough cleaning and shaping of canal and obturation of root canal system. There are various armamentariums, irrigants and medicaments available to perform root canal therapy. One of the medicaments is Calcium hydroxide which was first used in dentistry in 1930 by Herman3. Though calcium hydroxide is not a restorative material by itself it is used in various clinical situations and often forms a part of restoration. Calcium hydroxide is advocated as an inter-appointment endodontic therapeutic dressing because of its antibacterial effect on most of the microorganisms identified in the root canal system4. The antimicrobial properties of calcium hydroxide are directly related to its pH5. of swelling on the anterior region of lower jaw. Patient gave a history of trauma on lower anterior teeth two years back. On clinical examination there was swelling and pus discharge around the lower incisors. Orthopentamogram (OPG) was advised which revealed a well defined large radiolucency in relation to 31, 32, 41, & 42 (Fig 1) Treatment planning was discussed with the patient and his family before starting the procedure. Access was opened, pus was drained from 31, 32, 41 & 42, canals were irrigated with normal saline and closed dressing was placed. In the following appointment, working length was determined, canals were cleaned & shaped using K and H files (MANI, Inc. Japan) and a closed dressing was placed in all the involved teeth. Patient was recalled after one week, canals were irrigated with 3% sodium hypochlorite (Novo Dental Pvt. Ltd., India) & saline, dried with paper points, and calcium hydroxide (RC Cal, Prime Dental, India) dressing was placed after which the canals were filled with temporary cement (Caviton GC Corporation, Japan). This procedure was repeated once every month for five times (Fig 2). Patient was advised to report to the hospital if he experienced pain or discomfort and/or the temporary restoration came out. After five months, the canals were obturated using AH plus (Dentsply Maillerfer, Switzerland) sealer and gutta percha (Dentsply, France SAS) and the access cavities were restored with GIC (GC Corporation, Japan). Patient was recalled after 6 months for follow up. IOPA was made which showed bone formation around the Case Report A 12 year old patient reported to dental department of Kathmandu Medical Teaching Hospital with a complaint Correspondence Dr. Punam Basnet Dixit, Lecturer, Dental Department, Kathmandu Medical College & Teaching Hospital, Sinamangal, Kathmandu, Nepal E-mail: [email protected] 125 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Fig 1: Large radiolucency involving lower incisors Fig 2: Recall visit after 3 months with calcium hydroxide dressing Fig 3: Follow up after after 6 months, healed periapical radioluvency with bone formation periapical areas of all the four root canal treated incisors where there was extensive bone loss seen, initially (Fig 3). tissue repair by hard tissue formation11. Lethal action of calcium hydroxide on bacterial cells are probably due to damage to the bacterial cytoplasmic membrane, protein denaturation and damage to DNA12. Discussion Various studies have shown that root canals in teeth with pulp necrosis and chronic periapical reactions have predominance of anaerobic microorganisms, especially the gram negative5,6. Gram negative microorganisms not only contains virulent factors and produces toxic products in periapical tissues, but contain endotoxin in their cell wall7. Endotoxin in root canal may induce radiographically visible apical reactions, show intense inflammatory infiltrate, increase in the thickness of periodontal ligament and resorption of cementum and alveolar bone8. Therefore management of the teeth with pulp necrosis and chronic periapical reaction should not only be concerned with bacterial death, but also the inactivation of endotoxin. Study by Assed S et al8 shows that Calcium hydroxide detoxifies bacterial endotoxin. Calcium hydroxide is not categorized as a conventional antiseptic, but is clinically effective in eliminating microorganisms from root canal space. Calcium hydroxide is recommended as intra canal medicaments because of antimicrobial properties4, tissue dissolving ability9, inhibition of tooth resorption10, and induction of J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 When endodontic failure occurs, endodontic retreatment is advised either with or without periapical surgery. Theoretically it is better to do retreatment without periradicular surgery. It is better to remove the old filling material and reprepare and refill the root canal system than to perform periradicular surgery13. The success rate for periradicular surgery is lower than that of root canal retreatment has already been shown14. Whether it is root canal therapy or retreatment, infection control lies at the heart of endodontics. Calcium hydroxide for endodontic use comes as a paste form which can be easily introduced into the canal. It is a strong alkaline substance, which has a pH of approximately 12.5. In an aqueous solution, calcium hydroxide dissociates into calcium and hydroxyl ions. The antimicrobial action of calcium hydroxide is related to the release of hydroxyl ions in an aqueous environment15. Calcium hydroxide, with its long acting antimicrobial and tissue solvent properties plays important role in endodontics16. 126 Conclusion Total elimination of microorganism from the canals is the main key to success of endodontic treatment. Use of calcium hydroxide as an intra-appointment dressing may help to eliminate surviving bacteria in the canal and help to achieve a successful endodontic treatment. teeth with chronic apical periodontitis detected by immunofluorescence. Endod Dent Traumatol.1996;12:66-9 8. Assed S, Paulo NF, Leonardo MR, Marcos AR. Effect of calcium hydroxide on bacterial endotoxin in vivo. J Endod 2002;28:94-8 9. Bhaskar SN. Periapical lesion-types, incidence and clinical features. Oral Surg, Oral Med, Oral Pathol. 1966; 21:657–71. Hasselgren G, Olsson B, Cvek M. Effects of calcium hydroxide and sodium hypochlorite on the dissolution of necrotic procine muscle tissue. J Endod 1988;14,125-7 10. Soares J, Santos S, Silveira F, Nunes E. Nonsurgical treatment of extensive cyst-like periapical lesion of endodontic origin. Int Endod J 2006;39: 566–75, Tronstad L. Root resorption etiology, terminology and clinical manifestations. Endod Dent Traumatol 1988;4:241-52 11. Foreman PC, Barnes IE. A review of calcium hydroxide. Int Endod J 1990;23:283-97 12. Siqueira JF, Lopes HP. Mechanisms of antimicrobial activity of calcium hydroxide: a critical review. Int Endod J 1999;32:361-9 13. Lovdahl PE. Endodontic Retreatment. DCNA 1992;36:47390 14. Grung B,Molven O, Halse A.Periapical surgery in a Norwegian county hospital: follow up finding of 477 teeth. J Endod 1990;16:411-4 15. Safavi KE, Dowden WE, Introcaso JH, Langland K. A comparision of antimicrobial effects of calcium hydroxide and iodine potassium iodide. J Endod 1985;11:454-6 16. Fava LR. Calcium hydroxide in endodontic treatment after two nonsurgical and two surgical failures: report of a case. Int Endod J 2001;34:72-80 References 1. 2. 3. H.A. Zander; Reaction of the Pulp to Calcium Hydroxide; J Dent Res 1939;18; 373 4. Bystro MA, Claesson R, Sundqvist G. The antibacterial effect of camphorated para-monochlorophenol, camphorated phenol and calcium hydroxide in the treatment of infected root canals. Endod Dent Traumatol 1985;1:170–5. 5. Evans M, Davies JK, Sundqvist G, Figdor D. Mechanisms involved in the resistance of Enteroccocus faecalis to calcium hydroxide. Int Endod J 2002;35:221-8 6. Abou-Rass M, Bogen G. Microorganisms in closed periapical lesions. Int Endod J 1998;31:39-47 7. Assed S, Ito IY, Leonardo MR, Silva LA, Lopatin D. Anaerobic microorganisms in root canals of human 127 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 128-130 Case Note Goldenhar syndrome: A report of a rare case Dali M1, Chacko V2, Rao A3 Specialist Resident, 2Assistant Professor, 3Professor, Department of Pedodontics and Preventive Dentistry, Manipal College of Dental Sciences, Mangalore 1 Abstract Goldenhar syndrome is a rare condition described by Goldenhar in 1952. It is characterized by a combination of anomalies: dermal epibulbar cysts, auricular appendices, malformation of the ears, hypoplasia of malar bones, mandible and zygomatic arch. The etiology of this rare disease is not fully understood, as it has shown itself variable genetically and of unclear causes. In this report we present a case of Goldenhar syndrome in a 4-year-old boy, who presented all classical signs of this rare condition. Key words: Goldenhar syndrome, Facial palsy, Anophthalmos, Microtia Introduction Goldenhar syndrome is a rare condition and the estimated incidence of this disorder is 1 per 5800 births with male: female ratio of 3:2. It is a presumably inherited condition, causing morphological abnormalities in the parts that developed from the first and second branchial arches during blastogenesis. It has a multifactorial etiopathology that includes nutritional and environmental factors1. Facial palsy7 though rare has been associated with it. A case of Goldenhar Syndrome, with association of anophthalmos and calcification of falx cerebri is also reported8. Goldenhar first described this condition in 1952 as a disease that presents a combination of several anomalies such as dermal epibulbar tumors, periauricular appendices and malformation of the ears. It is also referred to as oculo-auriculovertebral (OAV) dysplasia and hemi facial microsomia2. In this article we present a case report of 4 years old boy diagnosed with Goldenhar syndrome. The presence of anomalies of the ear (microtia) and of appendices on the ear is necessary for diagnosis of this syndrome. Case report A 4 years old boy reported to our clinics for routine dental treatment. The child was born to a young healthy parents (non-consanguinous). The prenatal and antenatal period was un-eventful and there was no relevant family history. The characteristic features of this syndrome are epibulbar dermoids, dacryocystitis, auricular abnormalities, preauricular appendages, preauricular fistulas, hypoplasia of the malar bones, mandible and zygomatic arch. Some associations recorded in the literature are macrostomia, micrognathia, high vaulted cleft palate, bifid tongue, malocclusion and other dental abnormalities3. The physical features of the child was atypical with facial asymmetry, coloboma of middle 3rd of upper right eyelid, microtia with accessory preauricular tags, malar hypoplasia and severe unilateral mandibular hypoplasia (Fig 1, Fig 2 & Fig 3A). History revealed that right sided macrostomia was surgically closed and the scar was seen on the corner of the mouth (Fig 3B) and epibulbar dermoids had been surgically removed by Department of Ophthalmology when the patient was six months old. No behavioral problem was noted during examination. Some authors have also pointed out facial muscle hypoplasia, vertebral abnormalities, anomalies of the eyes1, disturbances of the central nervous system, visceral anomalies4, Cardiac5 and genitourninary6 abnormalities. Correspondence Dr. Arathi Rao, Professor, Department of Pedodontics and Preventive Dentistry, Manipal College of Dental Sciences, Light House Hill Road, Mangalore 575001, Karnataka State, India, E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 128 Fig 1: Right malar hypoplasia Fig 2: Coloboma of middle 3rd of Fig 3: Right side of the face Fig 4: Deviation of mandible to and asymmetry of face upper right eyelid showing right side on opening the mouth (A) Preauricular tags deformed pinna and (B) Scar resulting from surgical closure of macrostomia The patient was already evaluated by a Paediatrician and an Ophthalmologist. His cardiac function, eyes and sight were found to be normal. Audiological testing reports showed that both auricular structures and hearing were normal. Most cases have sporadic autosomal dominant and autosomal recessive modes of inheritance. Trisomy of 7, 22 have been described in association with Goldenhar syndrome11. Reports indicate that several teratogenic agents such as retinoic acid, primidone, and thalidomide, have produced this syndrome in infants born to pregnant women exposed to those agents12. In our case there was no history of maternal drug intake, any febrile illness or diabetes during pregnancy. Dental examination revealed normal intra-oral soft tissues and all deciduous teeth were present. Few of the teeth in the left mandibular molar and upper anterior region were decayed. Mouth opening was not restricted, but the mandible deviated to the right side on maximum opening (Fig 4). Although this syndrome presents some similarities with the Treacher-Collins syndrome, it is now considered a distinct entity. The features of Treacher-Collins syndrome are most frequently bilateral without ocular and aural anomalies13. The patient was subjected to many examinations and treatments since birth and thus was very uncooperative at present in the clinical set up. Hence the patient was very uncooperative and the radiographic evaluation was not possible in this case. Delayed development of a tooth has been encountered in some cases although this is rare14 but was not observed in the present case. In the present case the deviation of the mandible to the right was due to the lack of the vertical and sagittal mandibular development, causing the mandible to rotate bodily to the right. Discussion In approximately 10 to 33 percent of affected individuals, malformations are bilateral affecting both sides of the body, with one side typically more affected than the other (leading to asymmetry). In the majority of such cases, the right side is more severely affected than the left10. The presented case also showed right side of the face more severely affected than left side. Prognosis of this disease is good in otherwise uncomplicated cases without any systemic associations. The treatment of the disease varies with age and systemic associations and is mainly cosmetic in uncomplicated cases. Goldenhar syndrome can be distinguished by varying degrees of vertebral, cardiac and sometimes structural kidney defects which were not present in this case. The patient exhibited clinical characteristics of complex Goldenhar syndrome with, including facial asymmetry, hypoplasia of the mandible, malar hypoplasia, macrostomia, preauricular tags, coloboma of eyelid. The dental treatment rendered to this child was restoration of the decayed teeth. Maxillary and mandibular orthognathic surgery is indicated followed by future orthodontic treatment. Reconstruction of mandibular hypoplasia can be done with rib grafts and underdeveloped maxilla can be lengthened by bone distraction device in future. Plastic surgery for coloboma of eye and reconstruction of external ear has been planned to be done at 6-8 yrs of age by an opthalmologist. Despite the reported frequency of cardiovascular alterations ranging from 5 to 58%, the reported patient had no cardiovascular alterations. Hearing disturbance or Facial nerve dysfunction were also not present. 129 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 References 1. Reddy P. Facio-auricular vertebral syndrome- a case report. Indian Journal of Human Genetics 2005;13:156-8. 2. Altamar R J. Syndrome de Goldenhar – A propósito de um caso. An Otorrinolaringol Iber Am.1998;25:491-7. 3. Pinheiro AL, Araujo LC, Oliveira SP, Sampaio MC, Freitas AC. Goldenhar’s Syndrome - case report. Braz Dent J 2003;14:67-70. 8. Grundfast KM, Guarisco JL, Thomsen JR, Koch B. Diverse etiologies of facial paralysis in children. Int J Pediatr Otorhinolaryngol 1990;19: 223-39. 9. Vatwani V, Verma N, Palta SC. Rare associations with Goldehar Syndrome. Indian Pediatr 1994; 31: 72-3. 10. Rao VA, Rao S. Lamba PA. Goldenhar’s syndrome. Indian J of Opthamol 1982;30: 147-9. 4. Rodriguez JI, Palacios J, Lapunzina P. Severe axial anomalies in the oculo-auriclo-vertebral (Goldenhar) complex. Am J Med Genet 1993;47:69-74. 11. Sugit Kumar GS, Haran R P, Rajshekhar V. Delleman syndrome with Goldenhar overlap. J Pediatr Neurosci 2009;4:53-5. 5. Lessick M, Vasa R, Israel J. Severe manifestations of oculo auriculo vertebral spectrum in a cocaine-exposed infant. J Med Gen 1991;28:803-4. 12. R Kapur, R Kapur, S Sheikh, S Jindal, S Kulkarni. Hemifacial microsomia: A case report. J Indian Soc Pedod Prevent Dent 2008; 26: 34-40. 6. Morrison PJ, Mulholland HC, Craig BG, Nevin C. Cardio vascular abnormalities in the oculo-auriculo-vertebral spectrum (Goldenhar Syndrome). Am J Med Genet 1992; 44: 425-8. 13. Mehta B, Nayak S. Goldenhar syndrome with unusual features: A case report. Indian J Dermatol Venereal Leprol 2008; 74: 254-6. 14. 7. Ritchey ML, Norbeck J, Huang C, Keating MA, Bloom DA. Urologic manifestations of Goldenhar syndrome. Urology 1994; 43: 88-91. Alkumru H, Colok G. Hemifacial microsomia and hypodontia: a case report. J Oral Rehabil 1992; 19: 6715. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 130 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 131-132 Case Note Use of toothbrush in maxillofacial surgery Sagtani A1, Sybil D2 1,2 Assistant Professor, Department of Oral & Maxillofacial Surgery, College of Dental Surgery, BPKIHS, Dharan, Nepal. Abstract Thorough debridement is essential for the initial management of contaminated facial wounds to prevent permanent tattooing of facial scars and remove the need for secondary facial aesthetic surgery. We used a simple toothbrush for cleaning a contaminated wound with satisfactory results. Facial wounds are almost always contaminated and more so if the etiology is road traffic accident. Good cleaning and debridement of a wound is essential for healing in an orderly fashion. Facial tissues have to be delicately handled as esthetics play an important role. We used a simple toothbrush for cleaning a contaminated wound with satisfactory results. Key words: Toothbrush, Debridement of contaminated wounds Case report A 35 year old female patient was brought to the emergency department with history of road traffic accident. Her vitals were stable and she showed no signs of head injury. On local examination, she had extensive soft and hard tissue injury over the left frontozygomatic region. The force of trauma had caused stripping of soft tissue from the underlying bone. The soft tissue wound had ragged margins and was highly contaminated with road debris (Fig 1). There was no loss of tissue. There was a comminuted fracture of left zygomatic complex. Her vision was not impaired. She was taken up for repair under general anesthesia. A medium nylon bristled toothbrush was used to remove the embedded debris from the subcutaneous tissue and muscle (Fig 2). Thorough debridement was done using copius amounts of saline and povidone-iodine solution until the wound was clean (Fig 3). The zygomatic complex fracture was reduced and fixed. The ragged margins were finely trimmed, tissue approximated and sutured in layers. The sutures were removed on 7th post-operative day. The wound healed with no infection and minimal scarring. Fig 1: Facial wound contaminated with dirt Discussion No wound can heal in an orderly fashion unless it is clean, healthy, and free of contamination. Thorough debridement is essential for the initial management of contaminated facial wounds to prevent permanent Fig 2: Use of toothbrush for debridement Correspondence Dr. Alok Sagtani, Deptartment of Oral & Maxillofacial Surgery, College of Dental Surgery, BPKIHS, Dharan, Nepal. E-mail: [email protected] 131 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Facial tissues, especially the subcutaneous tissues and muscles, require gentle handling due to their delicate nature. Aggressive scrubbing to remove dirt or dust with a stiff nylon brush can be used on the facial dermis. But this can damage an already frayed subcutaneous tissue and muscle. A toothbrush, however, provides a suitable alternative. It removes dirt from tissues without damaging them. The small flaps can be held in hand and scrubbed gently using a toothbrush with medium to hard bristles. A toothbrush can also be used in an emergency setting where sophisticated debridement equipment is not available. The other advantages of a toothbrush are it is readily available, can be sterilized and is cost effective. Fig 3: After debridement Thus we recommend the use of toothbrush for cleaning any contaminated facial wound prior to suturing. tattooing of facial scars and remove the need for secondary facial aesthetic surgery. Time spent in removing foreign bodies and dirt at this stage will be repaid one hundred fold in the months to come1. References Although mechanical cleansing with salinesoaked sponges effectively removes bacteria, it damages the wound and impairs its resistance to infection2. Mechanical abrasive scrubbing techniques and surgical excision can lead to blood loss and the loss of viable tissue. The conventional abrasive methods, e.g. plastic scrubbing brush, plastic pan scrub, or diathermy tip scratch pad, are sufficient for debridement of contaminated limb or torso wounds because of their flat skin surfaces3. Ultrasonic debridement is a viable option for the management of contaminated facial wounds3,4. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 132 1. Rowe and Williams. Maxillofacial Injuries. Vol 1. 2nd ed, Churchill Livingstone, 1994. 2. Rodeheaver GT, Smith SL, Thacker JG, Edgerton MT, Edlich RF. Mechanical cleansing of contaminated wounds with a surfactant. Am J Surg 1975; 129: 241–245. 3. L. H.-H. Cheng, J. Stewart, M. Thompson, D. M. Adlam. Ultrasonic debridement of contaminated facial wounds. British Journal of Oral and Maxillofacial Surgery 2002; 40: 149–150. 4. Nichter SN, McDonald S, Gabriel K, Sloan GM, Reinisch JF. Efficacy of debridement and primary closure of contaminated wounds: a comparison of methods. Ann Plast Surg 1989; 23: 224–230. Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 133-136 Case Note Non surgical endodontic retreatment following surgical endodontic failure: A case report Gautam S1, Thapa A2, Pai ARV3, Kundabala M4 Lecturer, Kantipur Dental College and Teaching Hospital, Nepal, 2Specialist Resident, India. 1 3,4 Professors, MCODS, Manipal University, Abstract Retreatment in endodontics provides a second chance for the patient to save the tooth that would otherwise be deemed for extraction. Treatment approach can be either surgical or non surgical. Treatment failure can be due to many reasons from missed canal to iatrogenic perforation which has to be evaluated carefully before initiating the treatment. Sometimes a clinician also has to deal with inter appointment flare ups requiring prompt and efficient patient management. This case report describes the non surgical management of failed root filled teeth which had also been treated surgically. Key words: Calcium hydroxide, Endodontic failure, Retreatment of teeth. Nevertheless, it can show signs of failure due to poor root canal treatment, faulty surgical procedure, lack of retrofilling4. Introduction Conventional endodontic treatment may fail due to various reasons and inadequate root canal treatment with persistent infection remaining in inaccessible areas of the canal being one of them1,2. In case of a surgical failure, re-surgery has showed reduced success rates compared with first-time surgery. It has been reported that success rates were 5%–27% lower for re-surgery compared with first-time surgery5. Further surgical procedure can be a traumatic experience with many disadvantages like pain, edema, discolorations and other post operative complications which can hamper the patients daily activities. Hence it is advisable to select a nonsurgical retreatment wherever feasible with an emphasis on effective sealing of infected root canal. When patient reports to the dental clinic with severe pain/swelling on the tooth that has previously been root filled they are anxious and skeptic about whole of endodontic treatment posing clinician in tricky state of patient management. Endodontic retreatment offers the patient a second chance to save a root canal treated tooth that would otherwise be destined for extraction. Such a retreatment can be carried out either surgically or non surgically. Nonsurgical retreatment when possible often is the first choice for attempting to correct obvious deficiencies in the previous treatment. However, surgical retreatment would be the choice in the presence of certain indications like presence of an apical cyst, anatomical or iatrogenic obstruction etc3. Generally surgical retreatment would be carried out following a nonsurgical endodontic failure, on the contrary, this case report deals with the non surgical retreatment following the surgical treatment failure of a previously endodontically treated maxillary central and lateral incisors. The surgical procedure can effectively remove the infected portion of the root colonized by bacteria either intraradicular or extraradicular or both, thus enhancing the chances of healing. Consequently, complete healing after periapical surgery has been reported in 37%–97% Case Report A 32 years old male patient reported with severe pain on upper front teeth since 2 days. He gave a history of root canal treatment 2 years back followed by immediate Correspondence Dr. Suman Gautam, Lecturer, Department of Conservative Dentistry and Endodontics, Kantipur Dental College Teaching Hospital and Research Center, Basundhara, Nepal, E-mail: [email protected] 133 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 medication. Patient was prescribed with medications and scheduled for subsequent visits. root surgery in the same teeth. He also gave history of on and off pus discharge from the gums in that area since 3 months. On examination, a draining sinus in relation to apical area of left central incisor (21) was seen (Fig 1). There was an acrylic crown in relation to 21 and a GIC restoration on maxillary left lateral incisor (22). The teeth were tender on palpation. On an IOPA radiograph insufficiently obturated canals were noted in relation to 21 and 22 with blunted root apex suggestive of previous root end surgery but with no evidence of any retrograde filling and persistent periapical radioluscency (Fig 2). The subjective and objective findings led to the diagnosis of a surgical endodontic treatment failure with chronic periapical abscess. Patient was explained about the existing condition and the need of retreatment was stressed. However, patient was reluctant to undergo endodontic surgery again, therefore a nonsurgical retreatment of the teeth was agreed. In the following visit, the working length was determined using an apex locator (Root ZX, J.Morita Mfg.Corp.) followed by radiographic confirmation. As the extent of the root canal cleaning and shaping carried out during the previous root canal treatment could not be determined, the canal debridement and shaping was carried out using standardized method by inserting K and H files (MANI, Inc. Japan) up to size 80 and filing the canal walls for the entire working length. The canal irrigation was carried out by alternate use 3%sodium hypochlorite (Novo Dental Pvt Ltd, India) and 2% chlorhexideine. Following canal cleaning and shaping Calcicur was deposited as an intra canal medicament and the access opening was sealed with zinc oxide eugenol cement. The nonsurgical treatment was initiated under local anaesthesia by removing the crown of 21, followed by the removal of the access opening filling and guttapercha obturation from both the teeth (Fig 3). The old gutta percha were removed using H file (MANI, Inc. Japan) and gutta percha dissolving chemical solvent, Xylene(Merck specialities Pvt. Ltd., India).The canal was thoroughly rinsed with normal saline and 2% chlorhexidine(Vishal Dentocare Pvt. Ltd., India). After drying the canals with paper points, Calcicur (Ivoclar Vivadent), a calcium hydroxide based intracanal medicament was placed in the canal and temporised with Zinc oxide eugenol cement. Patient was recalled after one week but patient reported to the clinic after two days with pain due to inter appointment flare up and it was treated by allowing drainage through the root canals of 21 and 22 followed by canal irrigation and access opening sealing as in first visit but without intracanal Fig 1: Clinical photo of the patient showing draining sinus (circled area) J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 After 4 weeks of recall and change of the intracanal medicament, the teeth become asymptomatic and the sinus tract healed. In the next visit, the root canals were obturated with gutta percha(Dentsply Maillefer, Switzerland), using thermoplasticized gutta percha master cone method as described by Kerezoudis6 using AH Plus(Dentsply Maillefer, Switzerland) sealer and access were sealed with composite resin (Z100,3M ESPE) (Fig 4). The acrylic crown of 21 which was cemented temporarily between the visits was cemented using GIC luting cement (GC Corporation, Japan). Patient was followed up after one month, twelve months (Fig 5) and twenty four months (Fig 6) the teeth were found to be asymptomatic and there was decrease in the size of the periapical radiolucency, suggesting progressive healing. Fig 2: Preoperative IOPA Radiograph 134 Fig 3: After Gutta percha removal Fig 4: Immediate post obturation Fig 5: 12 months recall Discussion Retreatment of failed root filled tooth requires thorough examination and evaluation of the tooth in question because decision of whether to retreat and restore or to extract and restore can be made. Post treatment diseases following an endodontic failure occurs due to complex interaction between various factors explained by Sunqvist7. The reason many teeth do not respond to root canal treatment is because of procedural errors that prevent the control and prevention of intracanal endodontic infection8. Undoubtedly, the major factors associated with endodontic failure are the persistence of microbial infection in the root canal system and/or the periradicular area1,2. favourable than that of primary endodontic surgery for post-treatment disease14.Nevertheless, going by the periapical status, a surgical retreatment would have looked appropriate but a nonsurgical retreatment was still required due to the previous faulty root canal obturations. Inter appointment flare up that occurred may be- due to disturbance in the microbial ecosystem -due to inadvertent pushing of debris in the periapex- due to over instrumentation or reaction with irrigating solution and solvents or increased virulence of the persistent bacteria at the periapex15. Other problems that can occur during the retreatment that can even lead to extraction of a tooth would be an irreparable perforation or root fracture16, 17. If root filled tooth has failed, there can be five possible treatment options: To review or do nothing, root canal retreatment, root end surgery, extraction followed by implant or referral. Cross sectional studies from different countries including most recent studies clearly demonstrate that more than 30% of all root filled teeth in the population are associated with apical periodontitis or post treatment disease9,10,11,12. A general guideline has been given by European Society of Endodontology13 for indications of retreatment, they are; • Teeth with inadequate root canal filling with radiological findings and/or symptoms • Teeth with inadequate root canal filling when the coronal restoration requires replacement • Teeth with coronal dental tissue that is to be bleached Fig 6: 24 months recall (decrease in size of periapical lesion is evident) A nonsurgical retreatment regimen employing through canal shaping, effective canal irrigation using combination of 2% chlorhexidine and 3% sodium hypochlorite followed by canal disinfection using calcium hydroxide between the visits was followed. This regimen was employed as its efficiency has been proved in many studies in eliminating the intraradicular infection18, 19,20,21,22. Additionally it has been seen that the non surgical retreatment shows improved outcomes with increasing recall time5, 23. Further, obturation using customized gutta percha facilitated obtaining a good apical seal, which mattered most in this patient as it ensured endodontic success based on nonsurgical treatment alone. In the recall time of one month, one year and two years patient was asymptomatic and there was progressive decrease in the size of the lesion indicating periapical healing. This benefitted the patient by sparing him from the need for a reendodontic surgery. In this patient nonsurgical retreatment was carried out as the patient was reluctant to undergo reendodontic surgery due to its traumatic nature and associated post operative problems. It has also been shown that the outcome of repeated endodontic surgery was less 135 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Conclusion There is enough potential for success of primary root canal filling but fact remains that clinicians are confronted with post treatment disease. Endodontic retreatment could be a suitable option in case of a post treatment disease following an endodontic failure. Nonsurgical procedures could look of minor importance or insignificant during retreatment, for managing surgical endodontic failure especially when reendodontic surgery appears inevitable. However, with non surgical treatment approach and adequate apical and coronal sealing we can achieve favourable clinical outcome even in case of failed surgically treated teeth. 10. Kabak Y. Abbott Prevalence of apical periodontitis and the quality of endodontic treatment in an adult Belarusian population. Int Endod J 2005; 38: 238–45. 11. Loftus JJ, Keating AP, McCartan BE. Periapical status and quality of endodontic treatment in an adult Irish population. Int Endod J 2005 ; 38: 81–6. 12. Tsuneishi M, Yamamoto T, Yamanaka R, Tamaki N, Sakamoto T, Tsuji K, Watanabe T. Radiographic evaluation of periapical status and prevalence of endodontic treatment in an adult Japanese population. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2005; 100: 631–5. 13. Abbott PV.Factors associated with continuing pain in endodontics.Aust Dent J 1994;39(3):157-61. 14. Nair PNR, Sjogren U, Krey G, Sundquvist G. Therapy resistant foreign body giant cell granuloma at the periapex of a root-filled human tooth. J Endod 1990; 16: 589–95. Gagliani MM, Gorni FGM, Strohmenger L. Periapical resurgery versus periapical surgery: a 5-year longitudinal comparison. Int Endod J 2005; 38:320–27. 15. Lin LM, Skribner JE, Gaengler P. Factors associated with endodontic treatment failures. J Endod. 1992; 18(12):6257. Richard E. Walton. Interappointment flare-ups: incidence, related factors, prevention, and management. Endod Topics 2002; 3: 67–76. 16. Stabholz A, Friedman S.Endodontic retreatment case selection and technique.Part 2: Treatment planning for retreatment. J Endod 1988; 14(12):607-14. 17. Kvinnsland I,Oswald RJ,Halse A, Gronningsaeter AG.A clinical and roentgenological study of 55 cases of root perforation. Int Endod J 1989;22(2):75-84. References 1. 2. 3. Min-Kai Wu & Paul R. Wesselink. Timeliness and effectiveness in the surgical management of persistent post-treatment periapical pathosis. Endod Topics 2005;11:25-31. 4. Ingle JI, Bakland LK, Baumgartner JC. Ingle’s Endodontics, 6th ed, Hamilton Ontario: BC Decker Inc; 2008. 18. Edgar Schafer. Irrigation of the root canal. Endo 2007; 1(1):11-27. 5. Torabinejad et al. Outcomes of non surgical retreatment and endodontic surgery: A systematic review. J Endod 2009;35:930-7. 19. 6. Kerezoudis NP, Valavanis D, Prountzos F. A method of adapting gutta-percha master cones for obturation of open apex cases using heat. Int Endod J 1999; 32: 5360. Kuruvilla JR, Kamath MP. Antimicrobial effect of 2.5% sodium hypochlorite and 0.2% chlorhexidine gluconate separately and combined as endodontic irrigants. J Endod 1998;24:472. 20. Sundqvist G, Figdor D. Life as an endodontic pathogen Ecological differences between the untreated and rootfilled root canals. Endod Topics 2003; 6: 3–28. Ahmad Zamany, Kamran Safavi, DMD, Larz S. W. Spangberg. The effect of chlorhexidine as an endodontic disinfectant. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2003; 96:578-81. 21. Siqueira Jr JF, Lopes HP. Mechanisms of antimicrobial activity of calcium hydroxide: a critical review. Int Endod J 1999; 32:361-69. Zahed Mohammadi, and Paul V. Abbott. Antimicrobial substantivity of root canal irrigants and medicaments: A review. Aust Endod J 2009; 35: 131–39. 22. Boucher Y, Matossian L, Rilliard F, Machtou P. Radiographic evaluation of the prevalence and technical quality of root canal treatment in a French subpopulation. Int Endod J 2002; 35: 229–238. Estrela C, Sydney GB, Bammann LL, Felippe Júnior O. Mechanism of action of calcium and hydroxyl ions of calcium hydroxide on tissue and bacteria. Braz Dent J 1995;6(2):85-90. 23. Cristian et al.Treatment outcome in endodontics: The Toronto study-phases 3 and 4: Orthograde retreatment. J Endod 2008;34:131-137. 7. 8. 9. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 136 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 137-139 Case Note Pyogenic granuloma associated with bone loss: A case report Singh VP1, Nayak DG2, Upoor AS3 1 Post Graduate Student, 2,3Professors, Department of Periodontics, Manipal College of Dental Sciences, Mangalore, Karnataka, India. Abstract Diverse group of pathologic process can produce the enlargement of soft tissues in the oral cavity and often present a diagnostic challenge. These soft tissue enlargement may represent a variation of normal anatomic structure, inflammatory reaction, cyst, neoplasm and developmental anomalies. A group of reactive hyperplasias which develop in response to a chronic recurring tissue injury that stimulates an excessive tissue reapair response. The pyogenic granuloma is a reactive enlargement that is an inflammatory response to local irritation such as calculus, a fractured tooth, rough dental restoration and foreign materials and rarely associated with bone loss. This article present a rare case of pyogenic granuloma associated with bone loss in a 28 year old female. Key words: Bone loss, Pyogenic granuloma, Reactive hyperplasias Introduction Pyogenic granuloma (PG) or granuloma pyogenicum is a common tumor-like growth of the oral cavity or skin that is considered to be non-neoplastic in nature. Pyogenic granuloma is a kind of inflammatory hyperplasia. The term pyogenic is a misnomer in that, contrary to the name implies, the lesion does not contain pus. Pyogenic granuloma is a benign lesion; therefore surgical excision is the treatment of choice. To avoid possibility of recurrence the lesion must be excised down to the under lying periosteum and predisposing irritant must be removed. Intraoral examination revealed a solitary diffused growth, red in color, measuring around 2x2x1.5 cm seen in interdental region in relation to the right lateral incisor and canine and extending palatally (Fig 1). Lesion had palatally rough surface, while superior surface showed indentation of the lower teeth as a result of surface ulceration. The growth was pedunculated and attached to the palatal mucosa between the teeth. Mobility of upper permanent lateral incisor was grade-II and that of canine was grade –I. Pathological migration of the canine was also present. Oral hygiene of the patient was fair. Case report A 28 year old systemically healthy female patient presented with a chief complaint of growth in the mouth involving upper right front region of the jaw. The patient had noticed a small painless growth about 6 years back. There was a very gradual increase in size, which led to discomfort while eating as the extent of growth had reached the occlusal plane (Fig 1). Patient also complained of gradual increase in the space between right maxillary lateral and canine. There was no history of intake of any hormonal supplements. Intraoral periapical radiograph of teeth 12 and 13 region revealed widening of periodontal ligament space, horizontal interdental bone loss with change in trabecular pattern of bone. Roots of the involved teeth did not show any signs of resorption (Fig 2). Occlusal radiogarph showed the similar findings as intraoral periapical radiograph and no expansion of bony plates was observed. The hemogram of patient was within normal limits and excisional biopsy was done under local anaesthesia. Lesion was excised deep to the periosteum and the biopsy specimen was sent for the microscopic examination (Fig 3). After complete stoppage of Extraoral examination did not reveal any facial asymmetry. Lymph nodes were not palpable. Correspondence Dr. Vijendra Pal Singh, Post Graduate Student, Department of Periodontics, Manipal College of Dental Sciences, Mangalore, India E-mail: [email protected] 137 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Fig 1: Pre-operative lesion Fig 2: Intraoral periapical radiograph showing interdental bone loss and change in trabecular pattern in between lateral incisor and canine. Fig 4: Complete healing after two month of excision Fig 5: Photomicrograph showing endotheliumlined channels, Mixed inflammatory cell infiltrate consisting predominantly of neutrophils and lymphocytes bleeding periodontal pack was given. Patient revisited after one week for removal of the periodontal pack. The excised area was again repacked with periodontal pack for one more week to facilitate healing. One week later, periodontal pack was removed and satisfactory healing of the gingiva was seen. Complete healing of the excised area was observed at two month follow up visit (Fig 4). Discussion Although pyogenic granuloma may occur in all ages1,2 it is predominant in the second decade of life in young adult females, possibly because of the vascular effects of female hormones3,4 Some authors believe that patients are mostly males under 18 years of age, females in the age range 18 to 39, and older patients with an equal gender distribution. Histopathological findings in the photomicrograph shows Hematoxilin-Eosin stained section showing highly vascular connective tissue exhibiting numerous small and large endothelium-lined channels engorged with red blood cells. Thickened wall of blood vessels, proliferating endothelial cells and few lymphatic vessels were evident. Mixed inflammatory cell infiltrate consisting predominantly of neutrophils and lymphocytes were also seen (Fig 5). The overlying epithelium had hyperplastic parakeratinized stratified squamous epithelium exhibiting areas of pseudoepitheliomatous hyperplasia. The above histopathological features was suggestive of pyogenic granuloma. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Fig 3: Excised lesion The principal oral site affected by pyogenic granuloma is the gingiva. Other oral sites are the lower lip, tongue, buccal mucosa, upper lip, and palate. These findings are consistent with those of others2,5,6. With regard to site, gingival pyogenic granuloma is more common in the maxilla than in the mandible and in the anterior region than in the posterior regions of both jaws5,6. Some studies7,8 concluded that some initial traumatic condition is the main etiologic factor for development of pyogenic granuloma. It has been reported that 80% of patients with extragingival oral pyogenic granuloma gave positive information about preceding injury9 to the site. 138 It is now generally accepted that the lesion is an exaggerated localized connective tissue reaction to minor injury or irritation. Gingival irritation as a result of calculus, overhanging edges or rough restorations might be the predisposing factor for the development of gingival pyogenic granuloma. It is possible that microulceration from these irritants in an already inflamed gingiva allows the ingress into the gingival connective tissue of low virulent oral microflora. This evokes an exaggerated vascular hyperplastic response in the connective tissue resulting in the formation of pyogenic granuloma6. Definitive diagnosis after histolpathologic exeamination was suggestive of pyogenic granuloma. References Clinically, PG is a smooth or lobulated exophytic lesion manifesting as small, red erythematous papules on a pedunculated or sometimes sessile base, which is usually hemorrhagic and compressible. The size varies in diameter from a few millimeters to several centimeters3,4. Rarely does PG exceed 2.5 cm in size and it usually reaches its full size within weeks or months, remaining indefinitely thereafter10. Clinical development of the lesion is slow, asymptomatic and painless3,4 but it may also grow rapidly11. The surface is characteristically ulcerated and friable12 which may be covered by a yellow, fibrinous membrane13 and its color ranges from pink to red to purple, depending on the age of the lesion. Young PGs are highly vascular in appearance3 because they are composed predominantly of hyperplastic granulation tissue in which capillaries are prominent. Thus minor trauma to the lesion may cause considerable bleeding, due to its pronounced vascularity3,13, whereas older lesions tend to become more collagenized and pink3. Rarely, PG may cause significant bone loss, as reported by Goodman-Topper and Bimstein14. In our case also, slight bone loss was associated with pyogenic granuloma. Pyogenic granuloma is a benign lesion; therefore, surgical excision is the treatment of choice. Although conservative surgical excision and removal of causative irritants (plaque, calculus, foreign materials, source of trauma) are the usual treatments3,4,15 for gingival lesions, the excision should extend down to the periosteum and the adjacent teeth should be thoroughly scaled to remove the source of continuing irritation3. Differential diagnosis of pyogenic granuloma includes parulis, peripheral giant cell granuloma, peripheral ossifying fibroma, hemangioma, peripheral fibroma, leiomyoma, hemangioendothelioma, hemangiopericytoma, bacillary angiomatosis, kaposis sarcoma, metastatic tumour, pregnancy tumor and post extraction granuloma16. In our case, the differential diagnosis after clinical examination and radiographic observation were peripheral giant cell granuloma and pyogenic granuloma. 139 1. Lawoyin JO, Arotiba JT, Dosumic OO. Oral pyogenic granuloma: A review of 38 cases from Jhadan, Nigeria. Br J Oral Maxillofac Surg 1997; 35:185-9 2. Al-Khateeb T, Ababneh K. Oral pyogenic granuloma in Jordanians: a retrospective analysis of 108 cases. J Oral Maxillofac Surg 2003;61:1285-8 3. Neville BW, Damm DD, Allen CM, Bouquot JE. Oral & maxillofacial pathology. 2nd ed, Philadelphia: WB Saunders; 2002. p. 437-95 4. Regezi JA, Sciubba JJ, Jordan RCK. Oral pathology: clinical pathologic considerations. 4th ed, Philadelphia: WB Saunders; 2003. p. 115-6. 5. Lee L, Miller PA, Maxymiw WG, Messner HA, Rotstein LE. Intraoral pyogenic granuloma after allogeneic bone marrow transplant. Report of three cases. Oral Surg Oral Med Oral Pathol 1994;78: 607- 10 6. Bragado R, Bello E, Requena L, Renedo G, Texeiro E, Alvarez MV, Castilla MA, Caramelo C. Increased expression of vascular endothelial growth factor in pyogenic granulomas. Acta Derm Venereol 1999;79: 4225 7. Hagiwara K, Khaskhely NM, Uezato H, Nonaka S. Mast cell “densities” in vascular proliferations: a preliminary study of pyogenic granuloma, portwine stain, cavernous hemangioma, cherry angioma, Kaposi’s sarcoma, and malignant hemangioendothelioma. J Dermatol 1999;26:577-86 8. Macleod RI, Soames JV. Epulides: a clinicopathological study of a series of 200 consecutive lesions. Br Dent J 1987;163:51-3 9. Bouquot JE, Nikai H. Lesions of the oral cavity. In Diagnostic surgical pathology of the head and neck, Gnepp DR ed, Philadelphia: WB Saunders; 2001. p. 141233 10. Sternberg SS, Antonioli DA, Carter D, Mills SE Oberman H. Diagnostic surgical pathology 3rd ed, Philadelphia: Lippincott Williams & Wilkins; 1999.p. 69, 174. 11. Esmeili T, Lozada-Nur F, Epstein J. Common benign oral soft tissue masses. Dent Clin North Am 2005;49:223-40 12. Greenberg MS, Glick M. Burket’s oral medicine: diagnosis and treatment. 10th ed, Hamilton: BC Decker; 2003. p. 141-2 13. Bachmeyer C, Devergie A, Mansouri S, Dubertret L, Aractingi S. Pyogenic granuloma of the tongue in chronic graft versus host disease. Ann Dermatol Venereol 1996;123:552-4 (in French) 14. Goodman-Topper ED, Bimstein E. Pyogenic granuloma as a cause of bone loss in a twelve-yearold child: report of case. ASDC J Dent Child 1994;61:65-7 15. Eversole LR. Clinical outline of oral pathology: diagnosis and treatment. 3rd ed, Hamilton: BC Decker; 2002 p. 113-4 16. Kerr DA. Granuloma pyogenicum. Oral Surg Oral Med Oral Pathol 1951;4:158-76. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 140-146 Case Note Orthodontic mini implant: Versatile application for clinical enhancement Xia CS1, Ding Y2, Kafle D3 Professor, 3Resident, Department of Orthodontics, Zhengzhou University, Henan, China, 2Associate Professor, Department of Orthodontics, Beijing University Second Dental Centre, Beijing, China. 1 Abstract The use of Orthodontic mini implant (OMI) anchorage is rapidly growing these days. In the recent years it has become a compulsory tool for orthodontist. With the better understanding of the biomechanics not only all kinds of tooth movement is possible with mini implant but orthopedic and orthognathic like effects can also be produced with judicious application of this device. Here we present two cases treated with the help of OMI. The first case needed maximum anchorage due to the degree of crowding and protrusive facial profile. The conventional orthodontic treatment could have produced good result but the ideal result was possible only with the absolute anchorage using mini implant. In the second case there was supra eruption of left maxillary second premolar and first molar. The OMI was used to intrude the supra erupted teeth. The almost impossible tooth movement with conventional orthodontic treatment was possible with the insertion of these implants buccally and palatally, within a period of six months and without any side effects. Key words: Orthodontic mini implant(OMI), Anchorage, Centre of resisitance, Intrusion, Retraction During the last two decades, the orthodontic mini implant (OMI) has progressed so much that now it is the everyday armamentarium of an orthodontist. A thorough review of the literature finds that implants for the orthodontic purposes were tried even before Branemark who introduced the dental implant1,2. The screws used for the internal fixation of the fracture sites were used for the orthodontic purposes. Initially stainless steel, then vitallium and now titanium screws are used. However, except few case reports the regular and advanced use of orthodontic mini implants started around the beginning of the new millennium. In 1970 Linkow described the prosthetic implant for orthodontic purpose in a case report3. He presented six cases treated with the help of blade implants. After that regular prosthetic implants were used for the orthodontic anchorage. It undoubtedly served the orthodontic speciality for many years and still are used in some multi disciplinary cases. Those implants were tried even in retro molar area and tuberosity areas for the sake of orthodontic anchorage. However the biggest disadvantage of these implants was their size which confined their placement only in edentulous ridges or retro molar areas. In the search of small dimension implants and with the idea of surgical screws, the present day orthodontic mini implants were developed. The first purely orthodontic implant dates back to 1983. Greekmore et al inserted surgical screw just below the anterior nasal spine to reduce the anterior deep bite4. The implant was made of vitallium and served the orthodontic purpose reducing the deep bite by 6 mm in one year time period. Roberts et al did several animal experiments in the eighties. They had inserted 2mm diameter implants in the femur of the dogs and rabbits with high success rate but similar result were not found in oral cavity5. Block and Hoffman in 1995 discovered onplant and used palate as an anchorage source6. In 1997 Kanomi used the 1.2mm diameter implant for orthodontic purpose7. Since then there have been floods of case reports and clinical researches on mini-implant anchorage. Now there are different designs of orthodontic implants in the market. The continuous modification of the design is still going on and is an on going process. Due to its small dimension (< 2mm in diameter), it can be placed in most of the areas like inter radicular space, mid palatal suture, paramedian area of palate, retro molar areas etc. and can be Correspondence Dr. Dashrath Kafle, Resident, Department of Orthodontics, Zhengzhou University, Henan, China E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 140 used for multiple purposes like de-crowding, orthodontic camouflage, molar distalization, mesialization, intrusion, segmental intrusion, vertical control and treatment of the canted occlusal plane. and forward flairing teeth (Fig 1). Her cephalometric analysis (Fig 2) revealed her ANB angle to be 5 degrees with slightly high mandibular plane angle. She was diagnosed to be class II skeletal malocclusion with crowding due to maxillary excess. Her detailed pre treatment cephalometric analysis is shown in Table 1. Another important advantage of orthodontic implant is its non invasive placement procedure. Flap raising in not needed and most of the implants are drill free (self drilling) which eliminates the extensive surgical procedures and expensive implant kits. They can be inserted under topical anesthesia. The local anesthesia of adjacent teeth is better avoided for the purpose of patient having sensation of pain if implant touches the tooth roots or periodontal ligaments instead of interradicular alveolar bone. This phenomenon is described as bio-feedback mechanism in a recent article by Brumgartel S8. Considering her facial profile and degree of crowding, the treatment plan was to extract the upper and lower first premolars. Her anchorage plan was either to put two micro implant in maxilla or use Trans Palatal Arch (TPA) and headgear. After discussing the treatment plan with the patient, she agreed with the first option. The treatment was started with pre-adjusted edgewise appliance, 0.022 ×0.028 inch MBT bracket. Two OMIs were inserted in between upper first molar and second premolar, one on each side. The anterior teeth were retracted by active tie-back from the crimpable hook to the implant (Fig 3). 200gram of force was applied on each side. The post treatment photographs shows improved facial profile and ideal occlusion with class I molar and canine relation, ideal over jet and overbite (Fig 4). Her post treatment cephalometric analysis is shown in Table 1. Total duration of treatment time was 20 months. Noteworthy to mention here, the prosthetic implants are invariably osseo-integaterd. Due to this property, their retention is very stable but one must wait at least 4-6 months before using them for occlusal restoration or orthodontic loading. The orthodontic mini implants used today interestingly are not Osseo-integrated rather they are attached with the bone mechanically. Using the property of mechanical stability, the orthodontic implants can be loaded immediately for orthodontic purpose unlike prosthetic implants in which we have to wait at 4-6 months. Initially a light force (50-100 grams) is used, later this force can be increased up to 200-250 grams which is adequate enough for the orthodontic tooth movement. The success rate of these implants is very high but of course proper selection of anatomic site is very important. The success rate of more than 90% is reported in many clinical trials9-12. However overnight success of this frequency should not be expected. The learning and experiencing curve is always very steep. OMI can be used to move teeth with absolute preservation of anchorage on regular basis. However implant assisted orthopedic and orthognathic like treatment is now possible13,14. Molar intrusion once considered to be almost impossible tooth movement by conventional orthodontic mechanism, is now easily possible with orthodontic mini implants. Finally the orthodontic implants are far cheaper than dental implants, non-invasive, predictable and reliable. They can be easily removed even with out any kind of anesthesia. Table 1: Cephalometric data Measurement SNA SNB ANB Interincisal(II) SN-GO ME MX1-SN MX1-NA (angle) MX1-NA(mm) MAN1-NB(angle) Man1-NB(mm) Normal 82±3 80±3 2±2 131±6 32±4 108±4 22±3 4±2 25±3 4±2 Pretreatment 84 79 5 115 33 114 30 6 30 6 Post treatment 82 80 2 128 30 107 24 6 24 3 Case 2 A 36 years old female patient was referred to the orthodontic department by her prosthodontist. Her lower left second premolar and molars were missing due to which the upper second premolar and first molar had supra erupted (Fig 6). Due to this supra eruption, the restoration of lower edentulous area was not possible. The treatment plan was OMI assisted orthodontic intrusion of upper left second premolar and first molar so that lower edentulous area could be restored with dental implant. Two mini implants were inserted, one buccally and the other palatally. Second pre-molar was bonded while first molar was banded. The teeth were then intruded with elastic chain and Ni-Ti closed coiled spring (Fig 7). The total treatment duration was 6 months. The post-treatment photographs show well intruded teeth and lower edentulous area restored with dental implant (Fig 8). Here we report two cases which were treated in the Department of Orthodontics, Second dental centre of Beijing University and Department of Orthodontics, Zhengzhou University, China. Case 1 A 23 years old female patient came to the Department of Orthodontics with the chief complaints of irregular 141 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Case 1 Figs 1: (Case 1) Pre-treatment photographs showing crowding and protrusive profile Figs 2: (Case 1) Pre-treatment OPG, Cephalogram and Cephalometric Tracing J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 142 Figs 3: (Case 1) During treatment, upper en-masse retraction with orthodontic mini implant Figs 4: (Case 1) Post-treatment facial and intra-oral photographs 143 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Figs 5: (Case 1) Post treatment OPG, Cephalogram and Cephalometric tracing Case 2 Figs 6: (Case 2) Pre-treatment facial and intra-oral photograph Figs 7: Photographs at the start of treatment, during treatment and at the completion of treatment Figs 8: Extra-oral and intra-oral photographs after occlusal restoration with dental implant J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 144 Conclusion Mini-implant anchorage can produce highly predictable results with decreased treatment time and decreased side effects. Mini implant anchorage has expanded the horizon of orthodontic treatment towards orthognathic like effects remaining within the boundary of orthodontic domain. Discussion In the first case, we decided to put two mini-implants in maxilla because of the need of maximum anchorage. Maximum anchorage can be obtained by the use of extra oral appliance e.g. headgear,TPA and OMI. But the patient compliance is the major factor. Especially the adult patients have poor compliance for the extraoral appliances. TPA is commonly used to preserve the anchorage. But in cases of maximum anchorage needs, TPA is not the reliable option. To retract the teeth bodily, the line of applied force should pass through the centre of resistance15,16. In our case the crimpable hook was not long enough to reach up to the centre of resistance of anterior teeth. This produced intrusive component in addition to retractive component which is beneficial in deep bite case. Orthodontic mini implant reduced the overall treatment time8. References Implant anchorage cannot increase the rate of tooth movement but it can definitely reduce the unwanted tooth movements. Nanda described the duration of orthodontic treatment still approaches 2 years: arguably because of the time it takes to correct the unintended side effects (undesirable tooth movements) that occur during tooth treatment17. The mini-implant anchorage has predictable outcome which eliminates side effects. This may be the reason for decreased treatment time. Another reason for decreased treatment time is the anterior en-masse retraction. Canine does not need to be retracted individually which is usual procedure to preserve anchorage in conventional orthodontic treatment. Mini implant anchorage can be used to retract all the anterior teeth together. In the second case of molar intrusion we placed two mini implants one on the palatal side and the other on the buccal side. Different ways of molar intrusion has been described in literature18,19. To obtain the pure intrusion of molar and premolar the force should again pass through the centre of resistance, buccolingually as well as mesiodistally. Otherwise unwanted tipping of the tooth will result. If we can control the palatal force, then the tooth can be intruded with implant only on the buccal area. To obtain this mechanics, the heavy wire trans-palatal arch can be placed which prevents buccal tipping of the tooth. We can add palatal crown torque in TPA to add the intrusive effect of the buccal mini implant. If the line of force is applied through the centre of resistance, the molar intrusion can result in a short period of time. Usually the result can be seen within months of treatment. In our case, it took us six months to intrude the molar and sufficient space was available to put implant supported teeth in the lower jaw. 145 1. Gainsforth BL, Higley LB. A study of orthodontic anchorage possibilities in basal bone. Am J Orthod Oral Surg 1945;31:406-17. 2. Branemark PI, Adell R, Breine U, Hansson BO, Lindstrom J, Ohlsson A. Intra-osseous anchorage of dental prosthesis. 1. Experimental studies. Scand J Plast Reconstr Surg 1969;3:81-100. 3. Linkow LI. Implant-orthodontics. J Clin Orthod 1970;4:68590. 4. Creekmore TD, Eklund MK. The possibility of skeletal anchorage. J Clin Orthod 1983;17:266-9 5. Roberts WE:Endosseous miniscrews:Historical, vascular,and integration perspectives. In: Nanda R and Uribe FA, editors:Temporary Anchorage Devices in Orthodontics St.Louis :Mosby-Elsevier; 2009. p. 3-13. 6. Block MS, Hoffman DR. A new device for absolute anchorage for orthodontics. Am J Orthod Dentofacial Orthop 1995;107:251-8. 7. Kanomi R. Mini-implant for orthodontic anchorage. J Clin Orthod 1997;31:763-7. 8. Baumgaertel S, Razavi MR, Hans MG. Mini-implant anchorage for the orthodontic practitioner. Am J Orthod Dentofacial Orthop 2008;133:621-7. 9. Wilmes B, Rademacher C, Olthoff G, Drescher D. Parameters affecting primary stability of orthodontic miniimplants. J Orofac Orthop 2006; 67:162-74. 10. Park HS, Jeong SH, Kwon OW. Factors affecting the clinical success of screw implants used as orthodontic anchorage. Am J Orthod Dentofacial Orthop 2006; 130:18-25. 11. Cheng SJ, Tseng IY, Lee JJ, Kok SH. A prospective study of the risk factors associated with failure of mini-implants used for orthodontic anchorage. Int J Oral Maxillofac Implants 2004;19:100-6. 12. Kravitz ND, Kusnoto B. Risks and complications of orthodontic miniscrews. Am J Orthod Dentofacial Orthop 2007;131(4Suppl):43-51. 13. Kuroda S,Katayama A,Takano-Yamamoto T. Severe anterior open-bite case treated using titanium screw anchorage Angle Orthod 2004;74:558-67. 14. Liou EJW:Appliances,mechanics,and treatment strategies toward orthognathic-like treatment results. In Nanda R and Uribe FA Editors:Temporary Anchorage Devices in Orthodontics, St. Louis: Mosby-Elsevier; 2009. p. 16797. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 15. Burstone,C.J. and H.A.Koenig.Optimizing anterior and canine retraction. Am J Orthod 1976;70: 1-19. 16. Yoshida N, Jost-Brinkmann PG, Koga Y, Mimaki N, Kobayashi K. Experimental evaluation of initial tooth displacement, centre of resistance and centre of rotation under the influence of an orthodontic force. Am J Orthod Dentofacial Orthop 2001;120:190- 7. 17. strategies in Clinical orthodontics, St. Louis; ElsevierSaunders; 2005.p. 1-16. Kulberg A, Nanda R. Principles of Biomechanics. In Ravindra Nanda editor: Biomechanics and Esthetic J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 146 18. Park HS, Jang BK, Kyung HM. Maxillary molar intrusion with micro-implant anchorage(MIA). Aust Orthod J 2005; 21:129-35. 19. Melson B, Fiorelli G. Upper Molar intrusion. J Clin Orthod 1996; 30:91-6. Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 147-150 Case Note Endodontic management of trumatized immature nonvital permanent anterior teeth: A case report Pradhan RJ1 1 Lecturer, Dental Department, KIST Medical College & Hospital, Imadol, Lalitpur Abstract Patients who present with non-vital immature permanent teeth pose a special challenge to dentists and require a specially tailored treatment plan. Wide tubular canals usually seen in young permanent anterior teeth often affected by trauma pose an endodontic situation where achieving apical seal is difficult because of the wide apical foramen with a nonconstrictve terminus. This case report presents the clinical procedure used to produce a hard tissue barrier in the open apex, and into which gutta percha along with the sealer was condensed by a special custom made technique. Key words: Open apex, Calcium hydroxide, Apexification, Custom made obturation technique Introduction Teeth with incomplete rhizogenesis, pose a special challenge to dentists all over because of large open apices, divergent root walls, thin dentinal walls that are susceptible to fracture and frequent periapical lesions. This group requires a specially tailored treatment plan, different from the other patients1. The calcified material that forms over the apical foramen has been histologically identified as an osteoid or cementoid. Radiographic interpretation of apical closure is often misleading3. It may need clinical determination. Obturation of an immature tooth that has undergone apexification is difficult as the apical portion of the canal is often larger than the coronal portion and since the cross-section of the canal is much wider in the labiolingual (or labiopalatal) direction than mesio distally2. Widely accepted endodontic management of these teeth requires cleaning and filing of the canal with temporary paste to induce a complete calcific barrier at the apex of the tooth for a root end closure of incompletely developed apex. Apexification is the term to describe this procedure. Finally different special techniques of obturation are used against which a guttapercha root filling can be condensed without the possibility of sealant or gutta-percha root filling going through the apex into the periapical tissues2. Guttapercha is obviously the filling material of choice because it can be packed into the irregularities that are present in these large canals. Lateral compaction is not the technique of choice because the resistance of the canal walls for lateral pressure is reduced in immature teeth and the greater bulk of gutta-percha require an even greater force to deform. Warm guttapercha techniques are best suited for filling immature canals and apices. The method to be employed will depend upon the operators preference and expertise. Many materials have been reported to successfully stimulate apexification. But calcium hydroxide has its histological importance3. This medicament has also been shown to change the environment in the dentin and bone to a more alkaline pH, which has been postulated to slow down the action of the resorptive cells and promote hard tissue formation and repair4. Correspondence Dr. Reema Joshi Pradhan, Lecturer (Conservative Dentistry & Endodontics), KIST Medical College & Hospital, Imadol, Lalitpur E-mail: [email protected] 147 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Case Report A 10 years old boy came to the Dental Department, KIST Medical Collge, Imadol, for the treatment of the traumatized maxillary central incisors (Fig 1). The patient reported that the trauma occured 6 months back and that no treatment had been performed. There was pain associated with both the fractured upper anterior teeth. Clinical examination revealed crown fractures exposing the pulp chamber of both maxillary central incisors. One month later a radiograph of the teeth were made. The canal were then dried and checked with 30 size paper point for apical barrier formation. The barrier formation was incomplete which was confirmed due to the presence of sensitivity in the apical area and also with the presence of blood and tissue fluid on the tip of the paper point. On the visit after 2 months, the same procedure was repeated. Radiological examination showed initiation of apical barrier formation with the reduced diameter of the apical foramen (Fig 5). The root canal dressings were renewed in each visit. The tooth failed to respond to cold test with ice stick and heat test using gutta percha cone. There was mild pain on percussion as well. There was absence of any sinus tract. Periapical radiographs revealed immature teeth with open apex (Fig 2). In the next visit which was in 3 months interval, another radiograph was made and formation of apical barrier was checked. On insertion of no. 30 paper point, resistance was felt at the barrier region. The paper point was totally dry and the tip was also frayed (Fig 6). This indicated that the barrier formation was complete. In first visit, access was opened using a no. 4 round bur and coronal preparation was done by Gates Glidden bur. Initial working length was predicted by gently advancing a number 30 absorbent paper point along the root canal until it was pressed against tissue at the apex and the length was calculated by deducting the length soaked with blood. Then the working length radiograph was made (Fig 3) and working length was established at 1 mm short of the radiographic apex. Irrigation with 1% sodium hypochlorite was done throughout the cleaning and shaping procedures. The final canal preparation was up to 130 no. file. Obturation was done in both the teeth using customized gutta percha technique. 2-3 standard sized gutta percha were selected (Fig 7). The cones were then softened with minimal amount of heat and were rolled in a glass slab with spatula until it formed a single smooth thick cone about the size of the canals (Fig 8 & 9). Resin based sealer (AH plus, Dentsply) was mixed and coated on to the manually modified guttapercha which was inserted up to the working length. Filling was done with glass ionomer cement (Fuji IX, GC corp). Radiograph was made (Fig 10). Gentle instrumentation was done with H-file from 60 to 120 no. in rasping movement. Canals were dried with larger number of sterile absorbent paper points. A slurry of radiopaque calcium hydroxide paste (Endocalpaste, Insta Chemical Ltd.) was placed in the canal with a lentulo spiral up to the full working length so that the paste contacted the tissue at the apex. Temporary restoration was given with reinforced zinc oxide-eugenol cement (Fig 4). One week later, a dressing of calcium hydroxide paste was again placed. Fig 1: Fractured maxillary central incisors Fig 2: Pre-treatment radiograph J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 One week later, little bit of the gutta percha was removed from the pulp chamber, and final restoration comprising of a glass ionomer lining and composite filling was placed. Follow up visits were done at 6 months interval. Fig 3: Working length Fig 4: Radiograph after radiograph placement of Calcium hydroxide 148 Fig 5: Radiograph showing reduced diameter of root apex Fig 6: Frayed end of paper point after barrier formation Fig 7, 8 & 9: Preparation of customized gutta percha cone Discussion The endodontic management of traumatized nonvital immature permanent anterior teeth has been reviewed. Some traditional treatment options have stood the test of time and are still valid to this day. Others have been reviewed and modified with the passage of time, as new science and new materials evolve to prove, disprove or facilitate approaches to the management of these cases. Practitioners need to always be aware of changes that occur from time to time with respect to the recommendations for treatment, and of scientific studies that support or disprove treatment rationales1. Fig 10: Radiograph of root canals after obturation with customized gutta percha cones growth factors and MTA (Mineral Trioxide Aggregates) have been reported to promote apexification similar to that found with calciumhydroxide7. Although apexification occurs with many materials, it has been reported even without the presence of canalfilling material after removal of the necrotic pulp tissue. The most important factors in achieving apexification seem to be thorough debridement of the root canal and sealing of the tooth4. Apical barrier formation can be expected to occur in over 90% of teeth treated by this clinical technique. The average length of time to achieve an apical hard tissue barrier is 5-7 months, necessitating 2-4 visits and clinical technique which has been shown to be successful in 96% of teeth treated with a 5-year survival rate of 86%.8 Failures are usually due to poor root canal therapy, inadequate coronal seal or further trauma of a tooth with an adequate root canal treatment2. Apexification is aimed at the formation of a mineralized barrier in the root apex in such a way that gutta-percha can be condensed properly in the main canal space2. Induction of apical closure has been the most widely used approach to treating open apex3. Calcium hydroxide has been extensively used to accomplish apical closure due to its apparent ability to stimulate hard tissue formation5 It was originally introduced to the field of endodontics by Herman in 1930 as a pulp-capping agent, but its uses today are widespread in endodontic therapy6. Then, Kaiser first introduced the use of calcium hydroxide mixed with camphorated monopara-chlorophenol (CMCP) to induce apical closure. The technique was popularized later in 1966 by Frank7. During the course of treatment by multiple visit apexification, it showed many teeth were lost while waiting for a calcific bridge to develop. In 1999 the revolutionary MTA material was advocated for cases with open apices as an apical barrier against which guttapercha was condensed, compacted or even injected6. A one-step alternative to conventional apexification procedures has been proposed by Koeings7. Successful performance of a one-step procedure may benefit both the patient and the practitioner because of the reduced amount of office time required. The potential problem of patient compliance is also reduced, and it appears that reopening the root canal and recleaning during multiple visits may disturb the process of apexification7. Calcium hydroxide can be mixed with a number of different substances (CMCP, distilled water, sterile saline, anesthetic solutions and recently chlorohexidine) to induce apical closure. The relatively good success rate of this procedure has been attributed to one or more of the following properties: (a) the high pH; (b) the calcium ion; (c) the hydroxyl ion; and (d) the antibacterial effect2. The aim of the root filling is to completely obturate the root canal. Instead of the lateral condensation of guttapercha points in cases of wide canals, other methods of filling Various other materials such as tricalcium phosphate, collagen calcium phosphate, osteogenic protein-1, bone 149 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 regular follow up leads to optimal outcome in such types of cases. the root canal with guttapercha may be employed, these include constructing a custom guttapercha point or use of one of the heated guttapercha techniques3. The method to be employed will depend upon the operator’s preference and expertise. References Conclusion Accidents at home, school or playground due to common childhood activities can result in traumatic injuries to the teeth. Upper anterior permanent central incisors are the teeth most frequently traumatized. The comprehensive management of these cases can increase the better outcome of treatment. An immature tooth that develops pulpal or periapical disease presents special problems. Conventional root canal treatment or any surgical approach would be unpredictable. Apexification has been widely accepted procedure for such cases and calcium hydroxide plays a great role as an intracanal medicament for inducing apical closure by formation of an apical stop8. Though, time consuming, apical closure can be expected to occur in over 90 per cent of non vital immature incisor teeth treated by intracanal dressings of calcium hydroxide paste. The five year success rate is over 85 per cent for teeth with adequate root fillings2. For wide canals and divergent apical portions, customized guttapercha cone technique is a simple procedure for obturation, which adapts easily on walls without voids8. A thorough clinical knowledge, accurate diagnostic techniques and meticulous endodontic procedures with J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 150 1. Moule AJ, Moule CA. The endodontic management of traumatized permanent anterior teeth: A review. Aust Dent J 2007;52:(1 Suppl):S122-37. 2. National Clinical Guidelines and Policy Documents 1999 -management and root canal treatment of nonvital immature permanent incisor teeth, Dental Practice Board for England and Wales. www.nhsbsa.nhs.uk/ Documents/.../paediatric_dentistry_uk, 1999 (downloaded on 21 October 2009) 3. Cohen S, Hargreaves KM. Pathways of the Pulp, 9th ed, Mosby Elsivier; 2009. p. 871 4. Nunes E, de Moraes IG, de Novaes PM, Sousa SM. Bilateral fusion of mandibular second molars with supernumerary teeth: Case Report. Braz Dent J. 2002;13:137-41. 5. Fidel RA, Carvalho RG, Varela CH, Letra A, Fidel SR, Complicated crown fracture: a case report. Braz Dent J. 2006;17:83-6. 6. Finucane D, Kinirons MJ.Non-vital immature permanent incisors factors that may influence treatment outcome. Endod Dent Traumatol 1999;15:273-7. 7. Koeings JF, Heller AL, Brilliant JD, Melfi RC, Driskell TD. Induced apical closure of permanent teeth in adult primates using a resorbable form of tricalcium phosphate ceramic. J Endod 1975; 1:102-6. 8. Dominguez Reyes A, Mun˜oz Mun˜oz L, Aznar Martin T. Study of calcium hydroxide apexification in 26 young permanent incisors. Dent Traumatol 2005;21:141–5. Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 151-157 Review Article The dental applications of titanium and its alloys: A review Rodrigues S1, Shenoy V2, Shetty T3, Jain N4 1 Associate Professor, 2,3Professors, 4Assistant Professor, Department of Prosthodontics, Manipal College of Dental Sciences, India Abstract The advances made in dental materials science suggest that intriguing changes will continue to occur in the practice of dentistry. Titanium is one dental material that promises to play an important role in the materials of the future and is a potentially important metal for medical and dental applications, currently being at the heart of most dental implantology. Being biocompatible it is also a suitable replacement for existing alloys in fixed and removable prostheses. Its future use in Prosthodontics would increase based on advanced research and clinical trials. Although the reports on the prosthodontic application of titanium have been increasing, its use in clinical dentistry for conventional removable partial denture is rather limited. This article will present the applications of titanium and reviews the literature on its status in Prosthodontics, especially Removable Prosthodontics by conducting an electronic search of Pub Med and reviewing English language peer reviewed articles from the years 1996-2008 coupled with additional references from citations within the articles. The articles were accessed by using the keyword “titanium, titanium alloys, pressure casting, removable partial denture framework”. Key words: Titanium, Titanium alloy Introduction Titanium is a fascinating material being the focus of attention of dental researchers and clinicians. It has been referred to as, “the wonder metal”, for two different reasons1. One was because it had many unique and wonderful properties. The other being one just had to wonder what role titanium would play in the materials of the future. and devices for titanium casting has resulted in clinical and laboratory success with titanium based alloys. Its further use in Prosthodontics would increase based on research and trials to compare its effectiveness to other existing and commonly used metals. The purpose of this article is to describe the properties of Titanium and to review its status in Prosthodontics. A literature search of Pub med was performed and English language peer reviewed articles published from 1998- 2008 that addressed the question of the properties of Titanium and its application in Prosthodontics were included. The Medline search was supplemented with a hand search to identify relevant peer reviewed articles published in dental journals. The controversy surrounding the biocompatibility of cobalt and nickel containing alloys as potential allergenics and the biological risks of metal ions released in the mouth during corrosion suggests the merits of another base metal alloy as an alternative2. Although none of the materials used in dentistry are totally inert, the evolution of titanium as an economical and nontoxic biocompatible replacement for existing alloys for fixed and removable prosthesis has rekindled interest in this wonder metal. Titanium: A historical perspective Although first identified by Gregor in 1791 as Mechanite and rechristened as Titanium by Klaproth after the Titans of the Greek mythology it was Dr. Wilhelm Kroll who invented useful metallurgical processes for the commercial production of titanium and is considered to be the father of titanium industry3,4. Until recently, the use of titanium for casting and its prosthodontic application was limited, probably because of technical difficulties in the casting procedure. Advances in research, development of new materials Correspondence Dr. Shobha Rodrigues, Associate Professor, Department of Prosthodontics, Manipal College of Dental Sciences, India E-mail: [email protected] 151 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 General properties A comprehensive review of the properties of titanium is essential to understand its working and applicability. Concepts have been organized to understand its applications despite deterrents to its use. Titanium has physical and mechanical properties, which have led its increased use in dental prosthesis despite casting difficulties due to high melting point (17000C), low density, high affinity to gases, and its reactivity with most components of most investment materials resulting in surface contamination, the removal of which is difficult, and complicating5,6,7. Although manufacturers do not recommend electrolytic polishing, this procedure may minimize residual irregularities not reached by conventional polishing, thereby optimizing the polishing process and providing a smoother surface8. Titanium has low thermal conductivity (22 W/m2)9 and is considered more physiological material than gold since its thermal conductivity is the closest one to the enamel’s proper value. This feature also allows for excellent localized electric arc spot welding, though when cutting heat will not be dissipated quickly1. Another important feature of titanium its is ability to form a very stable oxide layer which contributes to corrosion resistance, osseointegration and permits close apposition to physiological fluids, proteins and hard tissues to the metal surface10. 1) Inert gas arc- melting /gas pressure casting machines that consist of 2 chambers: an upper chamber (melting chamber) for arc melting under an inert atmosphere (Argon gas) and • Lower chamber (mold Chamber) with a muffle in which the molten metal is forced under Gravitational acceleration and inert gas pressure. e.g. Castamatic, Dentaurum. 2) Inert gas melting /centrifugal casting machines with vertical or horizontal centrifugal casting e.g. Cyclarc, J Morita 3) High frequency induction melting/ gas pressure casting machines.e.g. Tycast, Jeneric/Penetron and Titaniumer, Ohara Regardless of these new developments and the advance in the equipment used, porosity associated with titanium casting remains a problem resulting in inferior restorations19-22. Porosity is mainly on account of the gas entrapment due to vast temperature difference in molten Ti and that of the investment material causing rapid solidification, reducing the chances of gas to escape, and eventually trapping these bubbles in the metal casting and metal shrinkage upon solidification21,23. These differences are more than 11000C for magnesia based investment alloys and 16000C for silica based investment materials23. Radiographic digital imaging study analyses have confirmed that among the different casting systems, the centrifugal casting systems showed better results than other pressure differential casting systems and Ti castings made under an argon pressure of 50 mm Hg are significantly more porous than are castings made under a pressure of 400 mm of Hg. The non vented molds of a highly permeable refractory material yield the soundest castings20,21. The turbulent flow of molten titanium is responsible for gas incorporation and increasing albeit smaller casting defects in centrifugal systems. On the other hand the laminar flow of molten metal produces fewer but larger defects in the gas pressure/ vacuum systems5, 24-26. Studies on the in vitro corrosion of titanium found that the titanium ion release increased in the presence of fluoride ions; hence chemical agents primarily fluoridated solutions must be avoided even though no corrosion effects were observed clinically11,12,13. Similar studies on the corrosion resistance revealed that corrosion resistance was inversely proportional to surface roughness and pH of the solution12,14,15. Spectrophotometry studies further revealed that all titanium alloys were covered mainly with rutile type oxide after corrosion tests16. Studies done by Ikeda and Igarashi demonstrated that titanium plates anodized by being discharged in various concentrations of NaCl, Na F and KI solutions acquired antibacterial activity, which were found to be cell compatible suggesting greater clinical success of implants, due to reduced colonization of oral bacteria thus reducing one of the causes of peri-implantitis17,18. In some situations, larger sized pores are more beneficial than the smaller sized pores because they can be easily detected by the laboratory radiographic units and can be eliminated by laser welding27. However in the case of extremely large pores, welding repair is questionable due to the high energy required resulting in a possible alteration of the mechanical properties28. Titanium casting machines The casting of titanium dental appliances was noted in the early 1970 with the work of Water Stratt1of the US National Institute of Standards and Technology. This was followed by numerous studies in Japan, Europe and USA towards the precision casting of dental prostheses, and the development of casting machines and suitable investment materials. Titanium casting machines are classified into 3 types19. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 • Cast titanium removable partial denture Titanium is a relative new material for removable partial denture (RPD) frameworks. Because of its unique mechanical and chemical properties, Titanium is an ideal biomaterial and a suitable alternative for patients sensitive and allergic to other metals. The combination 152 of high strength and low weight makes Titanium and its alloys some of the highest strength/weight ratio materials, second only to fiber glass and other highly reinforced polymers1. On account of its low elastic modulus Titanium requires more bulk to prevent permanent deformation during function therefore clasps have to be wider than usually seen with Co-Cr or stainless Steel Another benefit of the low elastic modulus is that titanium can engage deeper retentive undercuts on teeth without applying lateral forces to the abutment teeth during insertion and removal of the appliance. fatigue life, but decreases their retention. They suggested that activation of titanium clasps to be avoided as they had lower fatigue resistance. On the other hand, due to its inherent large flexibility, cast bilateral long span RPD made in titanium are contraindicated. These appliances are better made of stiffer Co- Cr alloys1. One of the most common problems that necessitate replacement of RPD’s is fracture of metal framework. Within the framework, clasp assemblies are cited as fracture sites29. Internal porosity is reported as a potential factor in the fracture mechanism because it reduces bulk of the metal and causes stress concentration. Even with special casting methods, titanium is prone to porosity, especially with complicated structures. Therefore castings should be examined with non destructive methods, for example with radiographs. Removable partial denture frameworks that were 0.70mm thick had better castability than did 0.35 mm thick RPD frameworks. The same study also showed that Ti commonly failed to cast perfect mesh specimens, although the same problem was not seen in Co-Cr alloys30. Baltag.I. et al22 investigated the influence of sprue design on internal porosity of circumferential clasps of cast titanium removable partial dentures and concluded that curved sprue design produced significantly less porosity than conventional straight design. Bridgeman et al34 investigated the retentiveness of titanium and cobalt chromium removable denture clasps over a 3 year period of simulated clinical use, and concluded that the flexibility and long term retentive resiliency of the clasps made Ti and its alloys suitable for Removable partial dentures especially for situations involving deep undercuts. They also suggested that though casting defects contribute to material degradation and loss of retention in a small percentage of the titanium and titanium alloy clasps, the risk of fracture was actually greater for the Cobalt Chromium clasps than for the pure titanium or titanium alloy clasps. Vander Brink et al33. compared various RPD clasp materials and fabrication procedures including Nickel Titanium alloys (Ni-Ti). The alloy was found to be unacceptable for an RPD clasp even when a 0.8 mm diameter was used. One outcome of the study was the need to compare materials in a curved clasp configuration rather than in straight specimens. Dong Suk Kim et. al35 compared the clasp retention of Cast Ti-Ni alloys with conventional removable partial denture clasps and found that though the end point retention for all the clasps were similar, there was less change in the retentive force of the cast Ti-Ni alloys after repeated cyclic sequences of simulated placement and removal, finding them a very desirable option for RPD fabrication. Titanium in crowns and bridges A study on the marginal fit of Titanium crowns was found to be intermediate between a group of high noble alloy (Au-Pd-Ag) and Ni-Cr alloy crowns36. In 1989, Andersson et.al37 introduced a new system of titanium crowns that used a copy milling spark erosion technique to fabricate titanium copings and veneered them with composite resin. In this technique the external contour of the titanium crown or coping can be shaped out of a solid piece of titanium by a milling machine, while the internal contour of the titanium crown is spark eroded with a carbon electrode. Single titanium crowns can be fabricated with this method, and multiple unit fixed prostheses can be made by laser welding individual units together. The advantages of this system includes low cost, standardized fabrication and biocompatibility38. A study on the fit of 20 cast titanium copings divided into two equal groups with 45 and 90 degree shoulders revealed the surface of marginal discrepancy was greatest with the 90-degree configuration39. Casting shrinkage occurred particularly along the horizontal axis in the plane of the shoulder. Blackman et al31 investigated the dimensional changes during casting of titanium for RPD frameworks. The authors concluded that dimensional changes in both horizontal and the vertical planes occurred, with mean cross arch shrinkage of 2.6% horizontally and expansion of 1.8% vertically. Shrinkage in the premolar region was less than that in the molar region. They concluded that methods for best controlling factors influencing dimensional changes need to be fully investigated. Pekka K Vallittu et al32 studied the deflection fatigue of cobalt chromium, titanium and gold alloy cast denture clasp. The results of the study suggested that significant differences exist in the fatigue resistance of removable denture clasps made from different commercial cast metals, which may cause loss of retention of the removable partial denture and clasp failures. They concluded that from a clinical standpoint activation of cobalt chromium and gold alloy clasps lengthens their 153 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 The overall fit of the spark eroded titanium crowns on the basis of the size and character of the cement film at three selected sites from inside the finish line was found to be less than cast gold alloys40. oxidation during porcelain firing and therefore improved ceramic bonding51. Changing titanium surface to control its high temperature oxidation has been examined. Published studies showed that titanium surface nitridation52 or a thin Chromium coating is an effective method of limiting titanium oxidation at high temperature53. Regardless of the interfacial variables, conventional noble ceramic bonding was superior to titanium bonding51. Porcelain bonded to titanium If titanium’s distinct advantage is to be used, for aesthetic crowns and bridges, the ability to apply porcelain veneer becomes important. Fusion of porcelain on titanium is not without difficulties. The characteristic high temperature oxidation of titanium is the main obstacle to strong titanium bonding5, 41-44 Kirmura et al45 reported the oxidation effects of the porcelain titanium interface reaction. They concluded that the thickness of TiO2 on commercially pure titanium surface increased with the increase in oxidation temperature. Titanium surface hardness also increased substantially after oxidation at and above 9000C. Lower titanium bond strength was attributed to a thick TiO2 on the metal surfaces when titanium was oxidized at higher temperatures46. Menis et. al47 attempted to bond low fusing porcelain to cast titanium at approximately 8000C. Although the bond strength was nominally comparable with the bond strength of porcelain bonded to Ni-Cr alloy, separation of porcelain from the cast titanium occurred at the oxidemetal interface. Currently at least one system Procera ( Noble Biocare, Gothenburg, Sweden) has had success in fabricating single unit crowns and multiple unit bridges from commercially pure wrought titanium. A compatible low fusing porcelain, Ti-Ceram has been developed for veneering these restorations. The advantage of the Procera system over cast Ti is that it overcomes the hardened surface layer that is encountered with Ti castings, therefore providing adequate porcelain titanium bonding1, 54, 55. Boeing et al56 in an invitro study indicated that Procera crowns had a good marginal fit, if a feather edge or chamfer preparation is used. Marginal gaps range from 270 to 750 microns with shoulder preparation because of the construction of the duplication milling machine. Their results also showed that the Ti ceramic bond passed the Deutsche Industrie Norm test but failed the International Standards Organization test. Togaya et al48. investigated the compatibility of porcelain from the cast titanium and suggested that appropriate bond strength between porcelain and titanium was possible by reducing the thermal expansion coefficient of the porcelain to approximate that of titanium. Pang et al57 studied the bond strength of palladium copper (Ney) to VMK68 (Vident), cast Ti to Duceratin (Degussa) and machined milled Titanium to Procera. The bond strength of palladium-copper to VMK68 porcelain was greater than that of the two Ti porcelain combinations. There was no significant difference in the bond strength of porcelain bonded or cast to machined Ti. The multiple firing schedules did not significantly affect the bond strength between low fusing porcelain and grade2 Titanium. Adachi et al49 evaluated the bonding of low fusing porcelain to titanium and Ti-6Al-4V alloy by an x-ray spectrometric technique. Oxide adherent strength values were measured at 7500C and10000C via simulated porcelain firings and actual porcelain application. The porcelain delaminated completely from the metal substrate in the constant flexural test, leaving less than 1% of the surface covered with porcelain. The oxide adherence of the specimen oxidized at 7500C was good; however was too thin to be visualized in the scanning electron microscope. Little or no residual stress due to thermal mismatch should exist in the final titanium / porcelain bond interface. The significant discrepancies already noted in their thermal coefficients of expansion will have to be more closely matched. An interfacial oxide layer some 100 to 1000 microns thick, forms during firing and the thicker this layer becomes, the weaker the bonding between the porcelain and the titanium. Nilson et al58 conducted a year clinical study on 44 Procera ceramic crowns and indicated that two crowns had ceramic fracture, ratings for surface and color had changed markedly from the excellent to the acceptable level and anatomic form had a small shift from the excellent to the acceptable level. Further studies on clinical trial of Procera crowns veneered with resin composites were performed by Bergman et al59. Ten (5.2%) of 192 titanium crowns had fractures of the resin composite veneer, but 99.5%of the crowns were rated excellent or satisfactory. There was a decrease from 83.4% to 70.1% in anatomic form An enhanced titanium ceramic bond was reported when porcelain was fired on cast titanium in a reduced argon atmosphere50. An argon atmosphere limited the titanium J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 154 easier to laser weld titanium62. Short span multiple bridges and bridges with pier abutments may be simple to fabricate, since individual case units can be welded together rather than being brazed. Since the bulk of the titanium framework is unaffected by local heating, room temperature assembly of appliances using accurate casts can eliminate many factors where distortion might be otherwise introduced. and marginal integrity after 1 year of follow up. 96.8% of the crowns showed excellent or satisfactory clinical properties for their surfaces or colors. The authors summarized that the initial marginal integrity was satisfactory and remained so throughout the 2-year follow up period. Titanium as a dental implant material Ossoeintegration has had a dramatic influence on Prosthodontic practice. The best long term results obtaining effective osseointegration have been produced with commercially pure titanium (CPT). Another material, Ti6Al4V which produces similar in vitro tissue reactions as CPT has not produced as much clinical success, probably though not conclusively due to leak of aluminum ions that compete with calcium during early stage of calcification2. Yamagishi et al63 examined the mechanical properties of Nd:YAG laser welds of titanium plates (1mm thick) and found that there is a significant relationship between three point bending strength and the irradiation atmosphere, irradiation intensity and the combination of atmosphere and intensity. Laser welding is effective when performed in an argon atmosphere. Results vary with various intensities of radiation. Sjogren27 evaluated the tensile strength of welded titanium rods and concluded that the penetration of laser energy could be up to 0.9mm, leaving the central portion of the rods unwelded. The welded specimens showed different defects such as gas pores and cracks at the fractured surfaces. The size and distribution of such defects seemed to be dependent on the laser variables used. While titanium is the material of choice mainly on account of its biocompatibility, its low modulus of elasticity, its machinability into strong hollow tubes, and its potential to be plasma sprayed or heat sintered in powder form to create porous implant surface makes it a preferred metal1. Modulus of Titanium is much closer to that of bone than either stainless steel or Cobalt chromium, although it is still five times that of cortical bone60. This property leads to a more even distribution of stress at the critical bone-implant interface, because bone and implant will flex in a more similar fashion. Another classical way to further make a device less stiff is to reduce cross sectional area or to make it porous. Titanium lends itself well to both these methods. It can be machined to hollow and perforated designs and the implant surface can be porous coated either by a plasma jet spraying it with powder or by heat sintering Titanium or Titanium alloy beads. Although there is some controversies regarding optimal pore size, in general, openings of 100 micrometers or larger appear to permit bone in growth and calcified bone ground substance may invade pores in 1-10 micron size2. However if pores become too large or too numerous, there is a danger of weakening the coating to the point of mechanical instability. Also porosity increases the exposed titanium surface area. So even though the corrosion type reactions per unit area are minimal, the significant increase in surface area will increase the amount of reaction products61. Success of dental implants would not only depend on the material selection alone but also on the continual improvements in the device design and clinical implantation techniques. Berg et al64 evaluated the mechanical properties of laser welded cast and wrought titanium base and compared them to those of a brazed type IV cast gold alloy. No significant difference in tensile strength was demonstrated between cast and wrought titanium. When the ductility of the Ti specimen was reduced the welded titanium was found to be as strong as brazed gold, suggesting that experimentally restorations made up of cast and wrought titanium would satisfy clinical requirements. Wang and Welsch65 compared three joining methods for pure Ti and Ti6AlV alloys, using laser, tungsten inert gas and infrared radiation and concluded that tungsten inert gas method demonstrates overall better results in terms of tensile strength and ductility, was also easy to operate, and economically feasible. In this study lack of complete joining was found among all the laser welded samples, corroborating with similar results by Sjogren. Summary Selection of materials is based on a reconciliation of their biocompatibility, optimum physical and mechanical properties and where indicated their superior esthetic qualities. A fundamental knowledge of the properties as well as the limitations of dental materials is crucial, so that the dentist can manipulate these materials to the best benefit of the patient Titanium Joining Tungsten inert gas (Tig), laser beam welding and brazing by infrared radiation heating techniques have been used to join titanium metal in a protective environment. Because of the low thermal conductivity of Titanium, and greater rate of laser beam absorption makes it Titanium and its alloys are known to have lightweight, high strength to weight ratio, low modulus of elasticity 155 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 and excellent corrosion resistance. In addition it is biocompatible and can be shaped and finished finding its way into dental applications like implants and restorative castings. Although more research is needed in areas such as development of optimal casting investments, porcelain veneering systems and controlled biological responses its future use in dentistry appears very bright. 15. Khan MA, Williams RL, Williams DF. The corrosion behavior of Ti-6Al-4V, Ti-6Al-7Nb, and Ti-13Nb-13Zr in protein solutions. Biomaterials 1999; 20:631-7. 16. Kuphasuk C, Oshida Y, Andres CJ, Hovijitra ST, Barco MT, Brown DT. Electrochemical corrosion of titanium and titanium based alloys. J Prosthet Dent 2001; 85:195-202. 17. Ikeda S, Igarashi T. Titanium plate anodisation by discharging in NaCl, NaF and KI solution acquires antibacterial activity to oral bacteria. Jpn J Dent Mater 2001; 20:68-76. 18. Shibata Y, Kawai H, Yamamoto H, Igarashi T, Miyazaki T. Antibacterial Titanium plate anodized by being discharged in NaCl Solution exhibits cell compatibility. J Dent Research 2004; 83:115-117. 19. Zinelis S. Effect of pressure of helium, argon, krypton and xenon on the porosity, microstructure, and mechanical properties of commercially pure titanium castings. J Prosthet Dent 2000; 84:575-582. References 1. Lautenschlager EP, Monaghan P. Titanium and titanium alloys as dental materials. Int. Dent J 1993; 43: 245-253. 2. Zarb, Bolender, Carlsson: In Boucher’s Prosthodontic treatment for edentulous patients. 11th Ed. Mosby Publications Harcourt India Indian reprint 2001. pg 493,502. 3. Brown D. All you wanted to know about titanium but were afraid to ask. Br. Dent J 1997; 182:393-394. 4. Wang RR, Fenton. A. Titanium for prosthodontic applications: a review of literature. Quintessence Int.1996; 27:401-408. 20. Chai TI, Syverud M, Stein RS. Porosity and accuracy of multiple unit titanium castings. J Prosthet Dent 1995; 73:534-541. 5. Okabe T, Hero H. The use of titanium in dentistry. Cells And Materials 1995;5:211-30. 21. Hero H, Waarli M. Mold filling and porosity in casting of titanium. Dent Mater 1993; 9:15-18. 6. Papadopoulos T.R, Zinelis S, Vardavoulias M. A metallurgical study of the contamination zone at the surface of dental Ti castings due to the phosphate bonded investment material: the protection efficacy of a ceramic coating. J Mater Sc 1999;34:3639-46. 22. Baltag I, Watanabe K, Kusakari H, Miyakawa O.Internal porosity of cast titanium removable partial dentures: Influence of Sprue direction on porosity in circumferential clasps of a clinical framework design. J Prosthet Dent.2002; 88:151-158. 7. Papadopoulos T, Tsetsekou A, Eliades G. Effect of aluminum oxide sand blasting on cast commercially pure titanium surface. Eur J Prosthodont Restor Dent 1999;7:15-21. 23. Dimitris Eliopoulos, Spiros Zinelis, Papadopoulos T. Porosity of cpTi casting with four different casting machines. J Prosthet Dent 2004; 92:377-381. 24. Guilherme A.S., Guilherme E.P., Zavanellui R.A., Mesquita M.P. Surface roughness and fatigue performance of commercially pure titanium and Ti-6Al-4V alloy after different polishing protocol. J Prosthet Dent 2005;93:378-85. Wu M, Schadlich-Stubenrauch J, Augthun M, Sahm PR, Spiekermann H. Computer aided prediction and control of shrinkage porosity in titanium dental castings. Dent Mater 1998;14:321-8. 25. Bondioli IR, Bottino M.A. Evaluation of shear bond strength at the interface of two porcelains and pure titanium injected into the casting mold at three different temperatures. J Prosthet Dent 2004; 91:541-7. Watanabe K, Okawa S, Miyakawa O, Nakano S, Shiokawa K, Kobayashi M. Molten titanium flow in a mesh cavity by the flow visualization technique. Dent mater J 1991; 10:128-37. 26. Branemark PI, Zarb G.A, Albrektson T. Tissue Integrated Prosthesis. Quintessence Publishing Co. Chicago 1985. pg101-102, 108-115. Watanabe K, Miyakawa O, Takada Y, Okuno O, Okabe T. Casting behavior of titanium alloys in a centrifugal casting machine. Biomaterials 2003; 24:1737-43. 27. Sjogren G, Andersson M, Bergman M. Laser welding of titanium in dentistry. Acta Odontol Scand 1988; 46:247253. 8. 9. 10. 11. Strietzel R, Hosch A, Kalbfleisch H, Buch D. In vitro corrosion of titanium. Biomaterials1998; 19:1495-9. 12. Boere G. Influence of fluoride on titanium in an acidic environment measured by polarization resistance technique. J Appl. Biomater 1995;6:283-6. 28. Muller M, Manthey H, Lange K, Gundlach H, Plank T. Electrochemical characterization of laser welding tracks. Analytic Bioanalytic Chem. 1998;361:662-6. 13. Zavanelli RA, Pessanna Henriques GE, Ferriera I, De Almeida Rollo J.M. Corrosion fatigue life of commercially pure titanium and Ti-6Al-4V alloys in different storage environments. J Prosthet Dent 2000;84:274-9. 29. Vermeulen AH, Keltjens HM, Van’t Hof MA, Kayser AF. Ten year evaluation of removable partial dentures: survival rates based on retreatment, not wearing and replacement. J Prosthet Dent 1996; 76:267-72. 14. Chen G, Wen X, Zhang N. Corrosion resistance and ion dissolution of titanium with different surface roughness. Biomed Mater Eng 1998; 8:61-74. 30. Yamauchi M, Sakai M, Kawano J. Clinical application of pure titanium for cast plate dentures. Dent Mater J 1988; 7:39-47. J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 156 31. Blackman R, Barghi N, Tran C. Dimensional changes in casting titanium removable partial denture frameworks. J Prosthet Dent. 1991; 65:309-315. 48. Togaya T, Suzuki M, Tsutsumi S, Ida K. An application of pure titanium to the metal porcelain system. Dent Mater J 1983; 2:210-9. 32. Vallittu PK, Kokkonen M. Deflection fatigue of cobalt chromium, titanium and gold alloy cast denture clasp. J Prosthet Dent.1995; 74:412-419. 49. Adachi M, Mackert JR, Parry EE, Fairhurst CW. Oxide adherence and porcelain bonding to Ti and Ti-6Al-4V. J Dent Res 1990; 69:1230-1235. 33. VandenBrink JP, Wolfaardt JF, Faulkner MG. A comparison of various removable partial denture clasp materials and fabrication procedures for joining clasps on canine and premolar teeth. J Prosthet Dent 1993; 70:180-8. 50. Atsu S, Berksun S. Bond strength of 3 porcelains to two forms of titanium using two firing atmospheres. J Prosthet Dent. 2000; 84:567-74. 51. 34. Bridgeman JT, Marker VA, Susan K, Byron H, Benson W, Pace LL. Comparison of titanium and cobalt chromium removable partial denture clasps. J Prosthet Dent.1997; 78: 187-192. Abdulaziz S, Zhuo Cai, Ronald DW, Amp WM. Effects of interfacial variables on ceramic adherence to cast and machined pure titanium. J Prosthet Dent. 2003; 90:10-17. 52. Oshida Y. Hashem A. Titanium –porcelain system. Part I: Oxidation kinetics of nitrided pure titanium, simulated to porcelain firing process. Biomed Mater Eng 1993; 3:85-98. 53. WangRR, Fung KK. Oxidative behavior of surface modified titanium for titanium ceramic restorations. J Prosthet Dent 1997; 77:423-34. 54. Derand T, Hero H. Bond strength of porcelain on cast vs. wrought titanium. Scand J Dent Res 1992; 100:184-8. 55. Gilbert JL, Covey DA, Lautenschlager EP. Bond characteristics of porcelain fused to milled titanium. Dent Mater 1994; 10:134-40. 56. Boeing KW, Walter MH, Reppel PD. Non cast titanium restorations in fixed prosthodontics. J Oral Rehabilitation 1992; 19:281-287. 57. Pang IC, Gilbert JL, Chai J, Lautenschlager EP. Bonding characteristics of low fusing porcelain bonded to pure titanium and palladium copper alloys. J Prosthet Dent 1995; 73:17-25. 35. KimD, Park C, Yi Y, Cho LR.Comparison of cast Ti-Ni alloy clasp retention with conventional removable partial denture clasps. J Prosthetics Dent 2004; 91:374-382. 36. Ida K, Tani Y, Tsutsumi S, et al.Clinical applications of pure Ti-crowns. Dent Mater J 1985; 4:191-5. 37. Andersson M, Bergman B, Bessing C, Ericson G, Lundquist P, Nilson H.Clinical results with titanium crowns fabricated with machine duplication and spark erosion. Acta Odontol Scand1989; 47:279-86. 38. Van Roekel NB. Electrical discharge machining in dentistry. Int J Prosthodont 1992; 5:114-21. 39. Blackman R, Baez R, Barghi N. Marginal accuracy and geometry of cast titanium copings. J Prosthet Dent. 1992; 67:435-440. 40. Harris IR, Wickens JL. A comparison of the fit of spark eroded titanium copings and cast gold alloy copings. Int J Prosthodont 1994; 7:348-355. 58. 41. Hruska AR, Borelli P. Quality criteria for pure titanium, laboratory soldering, intraoral welding and a device to aid in making uncontaminated castings. J Prosthet Dent 1991;66 :561-5. Nilson H, Bergman B, Bessing C, Lundquist P, Andersson M. Titanium Copings veneered with Procera ceramics. A longitudinal clinical study. Int J Prosthodont 1994; 7:115119. 59. 42. Kaus T, Probster L, Weber H. Clinical follow up study of ceramic veneered titanium restorations-three year results. Int J Prosthodont 1996;9:9-15. Bergman B, Bessing C Ericson G, Lundquist P, et al. A 2 yr follow up study of titanium crowns. Acta Odontol Scand 1990; 48:113-117. 60. 43. Walter M, Reppel P, Boning K, Freesmeyer W. Six year follow- up of titanium and high gold porcelain fused to metal fixed partial dentures. J Oral Rehabilitation 1999;26:91-6. AnusaviceK.J. Phillips Science of Dental Materials.In Dental Casting and soldering Alloys,Dental Implants. ed11th Elsevier Saunders 2003:55,362,579-580,597598,616-617 769-770. 61. 44. Bergman B, Marklund S, Nuilson H, Hedlund S. An intra-individual clinical comparison of 2 metal –ceramic systems. Int J Prosthodont1999;12:444-7. Lautenschlager EP, Sarkar NK, Acharya A et.al. Anodic polarization of porous fibre metals. J Biomed Mater Res 1974 8: 189-191. 62. 45. Kirmura H, Horng CJ, Okazaki MI. Oxidation effect on porcelain titanium interface reaction and bond strength. Dent Mater J 1990; 9:91-99. Watanabe I, Liu J, Atsuta M. Effects of heat treatments on mechanical strength of laser welded equi atomic AuCu6at%Ga alloys. J Dent Res 2001; 80:1813-7. 63. 46. Hautuaniemi JA, Hero H. Porcelain bonding on Ti. Its dependence on surface roughness, firing time and vacuum level. Surfa Interface Analysis 1993;20:421-426. Yamagishi T, Michio I, Fujimura Y. Mechanical properties of laser welds of titanium in dentistry by pulsed Nd:YAG laser apparatus. J Prosthet Dent 1993; 70:254-273. 64. 47. Menis DL, Moser JB, Greener EH. Experimental porcelain compositions for application to cast titanium. (special issue). JDent.Res1986; 65:343. Berg E, Wagner WC, Davik G, Dootz ER. Mechanical properties of laser welded cast and wrought titanium. J Prosthet Dent 1995; 74:250-257. 65. Wang RR, Welsch GE. Joining titanium materials with tungsten inert gas welding, laser welding and infrared brazing. J Prosthet Dent 1995; 74:521-530. 157 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 158-161 Review Article Management of obstructive sleep apnea using oral appliances: A Review (Part I) Kavitha PR1, P Vivek2, Bhat S3 Assistant Professor, Department of Orthodontic and Dentofacial Orthopedics, 3Professor, Vyas Dental College and Hospital, Jodhpur, Rajasthan, 2Assistant Professor, Department of Pedodontics and Preventive Children Dentistry, A.B. Shetty Memorial Institute of Dental Sciences 1 Abstract Sleep-Disordered breathing (SDB) describes a group of disorders characterized by abnormalities of respiratory pattern (pauses in breathing) or the quantity of ventilation during sleep. Obstructive sleep apnea (OSA) is one of the commonest types of SDB, it is a condition characterized by the repetitive total or partial collapse of the pharyngeal airway during sleep leading to oxygen desaturation or arousals. The first part of our review tries to give an explanation of etiology, signs and symptoms, pathophysiology, diagnosis and management of OSA. The second part focuses on the role of a dentist in treating OSA using various oral appliances (OAs) and the dental changes brought about, side effects of appliances and patient compliance. Key words: Sleep-disordered breathing (SDB), Obstructive sleep apnea (OSA) Introduction Obstructive sleep apnea (OSA) is a common upper air way disorder characterized by repetitive, complete or partial closure of the upper airway during sleep, resulting in sleep fragmentation and oxygen desaturation, the condition is also associated with loud snoring1,2. When there is a cessation of airflow at the mouth and nose for 10 seconds or more, then such a condition is termed apnea (Greek word ‘apnea’ means-without breath)3. During this time, the individual's oxygen levels will drop. If a person experiences 30 or more apneic episodes during a sevenhour sleep period, that person is believed to be suffering from sleep apnea syndrome. These episodes can last from 10 to 120 seconds. These apnea events terminate with a partial awakening or an arousal. It is important to understand that these arousals are necessary for the person to begin breathing again4, as these arousals increase the activity of tongue and throat muscles that enlarge the airway5. OSA is a relatively common condition occurring in 2 to 4% of males and 1 to 2 % of females in middle age6. Though it can occur in any age, the prevalence increases with the age. The problem is even more common among obese people, with 40% of men and 3% of women having the disorder6. Pathophysiology The underlying pathophysiology of OSA is complex and not fully understood. The causes are multifactorial and may vary considerably between individuals. Important risk factors include obesity, male sex, and aging. However, it is generally accepted that stability and patency of the upper airway plays an important role3,7. An obstruction in the upper airway can occur in three areas. They are the nasopharyngeal, oropharyngeal, and hypopharyngeal regions. The nasopharynx is the part of the pharynx that lies above the level of the soft palate. The oropharynx is the division of the pharynx that lies between the soft palate and the upper edge of the epiglottis. The hypopharynx is the division of the pharynx that lies below the upper edge of the epiglottis and opens into the larynx and esophagus4,8,9. The upper airway obstruction during sleep may occur as a result of narrowing of the respiratory passages. Partial obstruction results in loud, irregular snoring sounds caused by air rushing through the narrow passage and stimulating the soft palate, uvula, throat walls and tongue to vibrate. The narrower the airway passage, Correspondence Dr. Vivek P., Assistant Professor, Department of Paediatric and Preventive Children Dentistry, A.B. Shetty Memorial Institute of Dental Sciences, Mangalore, India, E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 158 the greater the negative pressure. When the negative pressure increases to a certain point, the airway may completely collapse. This is what is known as an apneic episode, during which breathing ceases7,8,10,11. The apneic episode terminates in an arousal, which results in increased muscle tone of the airway, opening up the pharynx so breathing is re-established9. Nocturnal symptoms include difficult breathing whilst asleep, heavy snoring, gasping and choking, restless sleep, heavy sweating, nightmares, frequent arousals during sleep (fragmented sleep), kicking and leg movements and bed wetting in children4,13,15,16,17. Diagnosis Medical diagnosis Diagnosis can be made on history, examination, polysomnography, split night testing and oximetry.13 The most reliable method to identify OSA is a nocturnal polysomnograph The necessary parameters recorded are: mobility of thoracic and abdominal muscles, cardiac rate, ECG, air flow through nasal and oral cavities, hemoglobin saturation in oxygen and exhaled carbon dioxide4,10,13,15,19. A number of imaging modalities like nasopharyngoscopy, fluoroscopy, MRI and computed tomography have also been used to assess the airway15. Also it is been hypothesized that individuals with OSA have impaired genioglossal function, allowing the prolapse of tongue against the posterior pharyngeal wall with inspiration effort during sleep3. Etiology The commonest cause of a narrow upper airway is obesity7,12. One possible explanation for the relationship between obesity and OSA is that the upper airway is narrowed in obese patients as a result of increased fat deposition in the pharyngeal walls7,12. In nonobese individuals, craniofacial anomalies like micrognathia and retrognathia resulting in insufficient room for the tongue thus predisposing to OSA13,14. Other craniofacial features predisposing to OSA include enlarged palatine tonsils, enlarged uvula, high arched palate, deviated nasal septum, long anterior facial height, inferiorly displaced hyoid bone, macroglossia and decreased posterior airway space13,14. In addition ethnic background, genetics, habits such as alcohol consumption, smoking and sedatives can aggravate the chances of OSA7,13. Apnea severity is usually categorized by the frequency of apnea events that occur per hour. The apneahypopnea index, or AHI—also known as the respiratory disturbance index—is used by many clinicians to confirm the diagnosis and quantify the illness severity. The categories are as follows4: The causes of Obstructive Sleep Apnea (OSA) are discerned as follows15: • Mild -- 5 to 20 episodes per hour; • Moderate -- 20 to 40 episodes per hour; and • Severe -- 40 or more episodes per hour. Dental diagnosis A dentist may be the first health care provider to identify a person with OSA because its salient signs and symptoms often are recognizable in the dental office10. Dental assessment includes history and oral examination focusing on occlusion, periodontal status, tooth mobility, parafunctional habits, TMJ evaluation, wear facets, DMFT, recording sensitivity of teeth, tori, and amount of over jet and overbite present.13 The lateral cephalometric radiographs of people with OSA usually show an elongated soft palate, a large tongue, a retropositioned maxilla and mandible, an inferiorly positioned hyoid bone, a narrowed posterior airway space or calcified carotid artery atheromas10. (a) Anatomic anomalies: such as hypertrophic tonsils and adenoids, choanal atresia or stenosis, anomalies of the nasal septum and soft tissue thickening of the upper respiratory system. (b) Neuromuscular diseases: such as cerebral palsy, myotonic dystrophy, congenital myopathies. These diseases may coexist with decreased muscle tone of the upper respiratory muscles and defective breathing control by the central nervous system. (c) Craniofacial anomalies:such as midfacial hypoplasia, micrognathia, hypotony, and sometimes mental retardation. Signs and Symptoms OSA is associated with a series of daytime and nocturnal signs and symptoms. The daytime symptoms include excessive sleepiness and abnormal behavior ranging from aggressiveness, hyperactivity and social withdrawal. Morning headaches, poor job performance, loss of alertness, clouded memory, intellectual deterioration and occupational accidents are also some presenting symptoms4,13,15,16,17. Treatment modalities Treatment of OSA is aimed at the reduction or eliminating the collapse of pharyngeal tissues. Treatment for OSA must be based on the assessment of severity of the sleep disorder, patient’s preference and general health. The treatment options must be less invasive whenever possible. Simplest options are lifestyle modification and oral appliance therapy for mild to moderate cases. Continuous positive airway pressure and surgical options are for moderate to severe cases11,13. 159 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 have been proposed by which drugs could reduce the severity of OSA. These include an increase in tone in the upper airway dilator muscles, an increase in ventilatory drive, a reduction in the proportion of REM sleep, a reduction in airway resistance and a reduction in surface tension in the upper airway. Physostigmines, nasal lubricant, topical nasal steroid, acetazolamide are some of the drugs which are used21. The treatment options can be non-surgical or surgical based on the preference of the patient. Non-surgical options • Lifestyle modification 1. Loose weight. People with severe sleep apnea are often overweight. Loss of weight will result in reduced adipose tissue volume in the upper airway, decrease the load on the chest wall and abdomen, and improve respiratory muscular efficiency4,12. Surgical treatment Surgery aims to alleviate anatomic sites of obstruction in the naso-, oro-, and hypopharynx22. Surgical treatment increases the upper airway cross-sectional area, removes obstructive tissues, such as enlarged tonsils, or bypass the pharyngeal airway23,24. 2. Sleep on one side. The patients who sleep on their backs have a significantly higher level of sleep disturbance as the supine position causes a gravitational pull on the tongue forcing it to come in contact with the posterior pharyngeal wall. Therefore, any technique that allows one to sleep on a side could be beneficial.4 The principal interventions can be considered as23: 1. Tracheostomy (which bypasses the pharyngeal airway) 3. Avoid alcohol within two to three hours of bedtime. Alcohol is a central nervous system depressant and changes motor activity in the muscles that control normal inspiration. These changes include relaxation of the walls of the upper airway causing it to collapse4. 2. Uvulopalatopharyngoplasty (UPPP) which increases the area of the retro palatal airway by resection of the free edge of the uvula and soft palate, and may be combined with tonsillectomy- a modification is laser-assisted uvulopalatoplasty (LAUP) 4. Avoid certain pharmacological agents. Benzodiazepines, narcotics, barbiturates, and testosterone have all been reported to affect the occurrence of apneic episodes4. 3. Tonsillectomy and adenoidectomy treatment of OSA in children accepted 4. Inferior sagittal mandibular osteotomy and genioglossal advancement with hyoid myotomy and suspension (GAHM) aims to create an enlarged retrolingual airway. Other life style modifications are designed to improve ‘sleep hygiene’. These include measures to improve the sleep environment like to keep the bed comfortable and the bedroom warm, quiet and dark, avoiding caffeinated drinks in the evenings and avoiding daytime napping12. 5. Laser midline glossectomy and lingualplasty also create an enlarged retrolingual airway. 6. Maxillo-mandibular osteotomy and advancement enlarges both retrolingual and retropalatal airway. Medical treatment 7. Epiglottoplasty laryngomalacia. 1. Nasal Continuous Positive Airway Pressure The gold standard treatment for OSA is nasal continuous positive airway pressure (nCPAP) delivered via a nasal mask. This technique involves wearing a mask tightly over the nose during sleep. A high flow blower delivers a continuous stream of air into a sealed nasal mask. This forced air creates a pneumatic splint, keeping the airway open and allowing the person to sleep normally. This is a highly effective therapy and is the most common approach for moderate and severe apnea patients4,8,10,21. Unfortunately, compliance with nCPAP has been very poor. nCPAP has its own side effects such as claustrophobia, air leaks, pressure sores, nasal stuffiness, dry mouth, and mask discomfort8,10,20. for selected cases of 8. Removal of local specific obstructing pathological lesions. Surgical success depends on appropriate patient selection, the type of procedure performed, and the experience of the surgeon. Surgery is considered appropriate on a case-by-case basis in patients with usually moderate to severe OSA with associated symptoms of excessive daytime sleepiness or with significant medical morbidities22. Untreated OSA can result in serious morbidity8. Cardiovascular disease is common in patients with OSA. The prevalence of angina, cardiac arrhythmias and myocardial infarction is increased in patients with apnea8,18. Cerebrovascular diseases may also be more prevalent in these patients8,18. There are metabolic and other systemic complications that also may occur as a result of untreated sleep apneas18. 2. Drug therapy Drug therapy has been proposed in some patients with mild to moderate sleep apnea and could be of value in patients intolerant to nCPAP. A number of mechanisms J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 - 160 Conclusion Obstructive sleep apnea (OSA) is a common upper air way disorder characterized by repetitive, complete or partial closure of the upper airway during sleep, resulting in sleep fragmentation and oxygen desaturation, the condition is also associated with loud snoring. In this first part the authors have reviewed the etiology, signs and symptoms, diagnosis and treatment modalities in offer and the following second part reviews on the role of a dentist in the treatment perspective of OSA. 13. Padma A, Ramakrishnan. N, Narayanan V. Management of obstructive sleep apnea: A dental perspective. Indian J Dent Res. 2007; 18:4: 201-209. 14. Solow B, Skov S, Ovesen J, Norup P, Wildschiodtz G. Airway dimensions and head posture in obstructive sleep apnea. Eur J Ortho.1996; 18: 571-579. 15. Papazoglou K, Papagrigorakis MJ. Sleep apnea in children. Hell Orthod Rev 2004; 7:33-43. 16. Carvalho FR, Lentini-Oliveira DA, Machado MAC, Saconato H, Prado LBF, Prado GF. Oral appliances and functional orthopaedic appliances for obstructive sleep apnea in children. Cochrane Database of Systematic Reviews 2007, 2:CD005520. DOI: 10.1002/14651858. CD005520.pub2. 17. Joshi AS, Steven A, Bielamowicz SA, Alexander AAZ, Truelson M, Roberts DH. Snoring and Obstructive Sleep Apnea, Prosthetic Management. eMedicine Specialties: Jun 28, 2007. Available from http://emedicine.medscape. com/article/870192-diagnosis. 18. Simmons MS, Clark GT. The potentially harmful medical consequences of untreated sleep-disordered breathing. The evidence supporting brain damage. J Am Dent Assoc. 2009; 140: 5:536-542. 19. Pae EK, Lowe AA, Sasaki L, Price C, Tsuchiya M, Fleetham JA. A cephalometric and electromyographic study of upper airway structures in the upright and supine position. Am J Orthod Dentofac Orthop. 1994; 106: 52–59. 20. Chai CL, Pathinathan A, Smith B. Continuous positive airway pressure delivery interfaces for obstructive sleep apnea. Cochrane Database of Systematic Reviews 2006; 4:CD005308. DOI: 10.1002/14651858.CD005308.pub2. 21. Smith I, Lasserson TJ, Wright JJ. Drug therapy for obstructive sleep apnea in adults. Cochrane Database of Systematic Reviews 2006; 2: CD003002. DOI: 10.1002/14651858.CD003002.pub2. 22. Won CHJ, Li KK, and Guilleminault C. Surgical Treatment of Obstructive Sleep Apnea - Upper Airway and Maxillomandibular Surgery. Proc Am Thorac Soc. 2008; 5: 193–199. 23. Sundaram S, Lim J, Lasserson TJ. Surgery for obstructive sleep apnea in adults. Cochrane Database of Systematic Reviews 2005; 4: CD001004. DOI: 10.1002/14651858. CD001004.pub2. 24. Lim J, McKean MC. Adenotonsillectomy for obstructive sleep apnea in children. Cochrane Database of Systematic Reviews 2009; 2: CD003136. DOI: 10.1002/14651858. CD003136.pub2. References 1. Ng A, Gotsopoulos H, Darendeliler AM, Cistulli PA. Oral appliance therapy for obstructive sleep apnea. Treat Respir Med. 2005; 4(6):409-22. 2. Gotsopoulos H, Chen C, Quin J, Cistulli PA, Oral appliance therapy improves symptoms in obstructive sleep apnea. Am J Respir Crit Care Med.2002; 166:743-748. 3. Cote EF. Obstructive sleep apnea- An orthodontic concern. Angle Orthod.1988; 293- 307. 4. Veis RW. Snoring and Obstructive Sleep Apnea from a Dental Perspective J Calif Dental Assoc.1998. August. 5. Guttal SS, Patil NP, Mantur SS. Conservative treatment of obstructive sleep apnea- a case report. NYSDJ. 2008; 70 (5):57 – 59. 6. Young T, Palta M, Dempsey J, Skatrud J, Weber S, Badr S. The occurrence of sleep-disordered breathing among middle-aged adults. N Engl J Med.1993; 328:1230-5. 7. Deegan PC, McNicholas WT. Pathophysiology of obstructive sleep apnea. Eur Respir J.1995; 8: 1161– 1178. 8. Victor LD. Obstructive Sleep Apnea. Am Fam Physician. 1999; 60:2279-86. 9. Eckert DJ and Malhotra A. Pathophysiology of Adult Obstructive Sleep Apnea. Proc Am Thorac Soc. 2008; 5: 144–153. 10. Friedlander AH et al., Diagnosing and Co managing Patients with Obstructive Sleep Apnea Syndrome J Am Dent Assoc. 2000; 131: 1179- 1184. 11. Simmons JH. Diagnostic Sleep Testing in the Evaluation of Snoring and Sleep Apnea. J Calif Dental Assoc.1998. August. 12. Shneerson J, Wright JJ. Lifestyle modification for obstructive sleep apnea. Cochrane Database of Systematic Reviews 2001; 1:CD002875.DOI: 10.1002/14651858.CD002875. 161 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 Journal of Nepal Dental Association (2009), Vol. 10, No. 2, Jul.-Dec., 162-165 Review Article Management of obstructive sleep apnea using oral appliances: A Review (Part II) Kavitha PR1, P Vivek2, Bhat S3 Assistant Professor, Department of Orthodontic and Dentofacial Orthopedics, 3Professor, Vyas Dental College and Hospital, Jodhpur, Rajasthan, 2Assistant Professor, Department of Pedodontics and Preventive Children Dentistry, A.B. Shetty Memorial Institute of Dental Sciences 1 Abstract There are various treatment options for obstructive sleep apnea (OSA) ranging from simple lifestyle modifications to surgical options. Some treatments are cumbersome in nature which makes tolerance and compliance less than optimal. This gives rise to the need for other alternatives that are equally effective and more tolerable. Dentists play a vital role in the treatment of OSA. There is growing interest in the use of oral appliances (OAs) to treat OSA. Wide ranges of appliances are available and are well tolerated by the patients. This second part of our review article focuses on various appliances their mechanism of action and effects on oral cavity. Key words: Oral appliances (OAs), Dental appliances, Mandibular advancement appliances (MADs), Obstructive sleep apnea (OSA) Introduction Dentists have recently begun to play a role in the management of obstructive sleep apnea (OSA) with the use of various oral appliances (OAs) or dental appliances. These appliances can reposition the tissues by lifting up the soft palate, bringing the tongue forward, or lifting the hyoid bone. As they reposition, some appliances also stabilize these tissues, preventing airway collapse. Appliances can also increase muscle tone. Specifically, there is an increase in pharyngeal and genioglossus muscle activity1. Historical aspects of oral appliances George Cattlin was probably the first person who seriously thought that the route of breathing may influence sleep quality and daytime function5. He pointed out that breathing through the nose promotes more restful and better quality sleep, which translates into better daytime function and better general health. However, modern published clinical work began in 1903, when Pierre Robin first described a device, called the “monoblock”, for the treatment of glossoptosis. It took almost another 50 years to start using oral appliances for the treatment of snoring and sleep apnea when Cartwright and Samelson described the tongue retaining device in 1982. This work stimulated further investigations5. These appliances are usually inexpensive, well tolerated by the patients and the side effects if any are thought to be reversible2. There are a large and diverse designs that have been used in clinical practice and research studies. It is important to consider these design features when choosing a device, as they may influence the retention of the oral appliance within the oral cavity during sleep, the degree of advancement of the mandible, and the range of movement of the mandible that is permitted. As a result, variations in design may affect clinical efficacy, adverse effects, and patient compliance3,4. Types of oral appliances There are abundant variety of appliances available and all these oral appliances may be divided into three general groups: soft palate lifters (SPLs), tongue retaining devices (TRDs), and mandibular advancement devices (MADs) also known as mandibular advancement appliances (MAA) or mandibular advancement splints26. Correspondence Dr. Vivek P., Assistant Professor, Department of Paediatric and Preventive Children Dentistry, A.B. Shetty Memorial Institute of Dental Sciences, Mangalore, India, E-mail: [email protected] J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 162 The first category is virtually no longer in use today most likely because of gag, discomfort, and the success of laser and radio frequency soft-palate procedures. The second category is used very seldom, mainly if there are dental reasons precluding the fabrication of MAD. The last category (MAD) is by far the most common type of dental appliance in use today. It protrudes the mandible forward, thus preventing or minimizing upper airway collapse during sleep5,6. Tongue retaining devices (TRDs) is a custom made soft acrylic appliance that has an anterior plastic bulb. It uses negative suction pressure to hold the tongue in forward position inside the bulb. By holding the tongue in forward direction through its attachment to genial tubercle, it stabilizes the mandible and hyoid bone, thus preventing the retrolapse of tongue10. Effects of oral appliances The goals of treatment with oral appliances are to prevent obstructive apneas and hypopneas during sleep, to improve the symptoms of OSA (such as snoring, excessive daytime sleepiness, and neurocognitive impairment), and to decrease the cardiovascular risk associated with OSA3. Design and mechanism of action There are various designs of oral appliances that have been used in clinical practice and research studies. Fabrication of appliance requires dental impressions, bite registration and fabrication by dental laboratory. However, they can be prefabricated too. The mandibular advancers may be made of elastomeric material or hard acrylic, or thermoplastic. Their retention on the teeth can be provided by friction fit of plastic in undercuts, which is most common, or by clasps7. Approximately 65% of patients achieve a 50% or greater reduction in apnea–hypopnea index (AHI) with MAD. Treatment with an MAD also improves oxyhemoglobin saturation. Improvements in sleep architecture and reduction of arousal indices have also been shown. There is significant reduction in the intensity and frequency of snoring. MAD may have a positive impact on cardiovascular disease, with improvement of intermediate end points such as oxidative stress and endothelial function3. Mandibular advancement appliances are either onepiece (monobloc) or twopiece (duobloc) configuration3. The former may be a simple vacuum formed splints with upper and lower fused together or clasped acrylic appliances, for example snore-guard, SNOAR etc. Two piece splints, where upper and lower elements are connected by rigid or plastic lateral connectors, allow some freedom of mandibular movement, for example Silencer, Herbst, Restore4,8. It is clear that not all patients are able to achieve a successful treatment outcome with oral appliances. There are anthropomorphic, physiological, and polysomnographic parameters that have been associated with a better treatment outcome, these parameters include female sex, lower age, lower body mass index, the amount of mandibular protrusion, smaller neck circumference, lower baseline AHI, supinedependent OSA, and primary oropharyngeal collapse of the upper airway during sleep3,6. The primary mechanism of action of MADs is to cause mechanical advancement of the mandible and thereby increase the anteroposterior dimensions of the oropharynx. Mandibular advancement appliances are constructed so that the mandible is positioned 2 to 5 millimeters anteriorly. The amount of forward repositioning and vertical opening varies with the appliance, the clinician and also the comfort on part of the patient. The tongue is also advanced passively because of its attachment to the genial tubercles. These devices simultaneously move the soft palate anteriorly because of its attachment to the tongue via the palatoglossus muscle. These movements enlarge the hypopharyngeal airway and reduce the likelihood that the tongue or soft palate collapse against the posterior pharyngeal wall when the patient inspires during sleep9. The precise reason for this effect on hypopharyngeal patency is unclear. However, soft tissue connections exist between the mandible, tongue, lateral pharyngeal walls, and soft palate, within the palatoglossal and palatopharyngeal arches. It has been proposed that such soft tissue connections may be stretched by mandibular advancement3,5,10. Factors affecting the success of oral appliances (OAs)8,11 1. Retentive factor - OAs must fit accurately, comfortably, and remain in position all night. 2. OAs should be able to variably adjust mandibular position. Appliance should provide lateral movement for the mandible. 3. The appliance must be of low bulk. The absence of bulk makes an appliance more comfortable and therefore more likely to be worn. 4. Appliances that allow the lips to close are more likely to be accepted by patients and are easier to get used to. 5. Appliances that pinch the lips or have protuberances into or beyond the lips and appliances made at excessive vertical opening, the compliance will be poor. 163 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 produce the clinical syndrome of OSA. Different factors will predominate in individual patients, but it is likely that all patients with clinically significant OSA have a multifactorial aetiology, rather than any single causative factor. However, these factors, such as defects in ventilatory control and protective upper airway reflexes, are less easily defined and further research is needed to elucidate their precise role in maintaining upper airway patency during sleep4,7. 6. Appliances should be non-interfering with sleep. Many appliances may cause awakening either owing to its being bulky or as a result of violation of lip seal or tongue space. 7. Must be economical. Indications and contraindications OAs are indicated for patients with the following11: • Simple snoring problems. • Mild to moderate OSA A better understanding of the interacting factors that lead to the development of clinically significant OSA will, hopefully, lead to the development of simpler modalities of therapy10. OAs are contraindicated for patients with the following11 • Active dental disease • Minimal protrusive range • Children • Acute temporomandibular joint dysfunction (TMJD) symptoms. • TMJ arthritis • Obvious psychological aversion to structures in the oral cavity • Moderately limited dexterity Oral appliances have proved to be vital as a treatment modality for OSA, future studies are needed to evaluate the effect of different appliance designs upon the success rate for reducing the AHI and improving sleep and symptoms6. Standard AHI criteria for success should be established as well as standard protocols for follow-up and documenting adverse effects.7 Future comparisons of OAs to nCPAP therapy may provide different results from studies done several years ago because of improvements in both modalities of therapy. Objective measurements of snoring and treatment adherence should also be obtained.9 Ongoing refinements of appliance design may eventually lead to improved outcomes with fewer complications. Head to head comparisons of different appliances and different design features may provide more information as to the key design elements that are related to treatment efficacy, adherence and complications. The role of these appliances, particularly MAD, in adolescents and children has yet to be evaluated in a comprehensive or systematic way. Studies addressing these issues will advance the field of OAs therapy and improve the care being delivered to patients with OSA8. Disadvantages of oral appliances6,11 The advancement of the mandible or tongue, being the principal mechanism of action of oral appliances, has the potential to cause adverse effects too. Mandibular advancement splints generate reciprocal forces on the teeth and jaw that can result in acute symptoms, as well as long-term dental and skeletal changes. Short-term adverse effects6,11 • Excessive salivation • Mouth dryness • Tooth pain • Gingival and oral mucosal irritation • Headaches • Temporomandibular joint discomfort • Mouth sores • Periodontal complications • Ingestion of broken appliance Conclusion Major advances in the field of oral appliances have provided evidence for the use of oral appliances in the clinical management of OSA. These developments have been reflected in the updated practice parameters which now recommend the use of oral appliances for mild-tomoderate OSA, or for patients with severe OSA who are unable to tolerate nCPAP or refuse treatment with nCPAP. Long-term adverse effects6,11 • Reduction in overjet • Increase in facial height • Increase in degree of mouth opening • Changes in inclination of incisors • Increase in mandibular plane angle • Root resorption As a simpler alternative to nCPAP, oral appliances are often regarded by patients as a more acceptable treatment option for OSA. This has the potential to translate to better treatment adherence and equivalent health benefits, despite the lower efficacy of oral appliances compared to nCPAP. Future research should focus on determining the influence of the design of Discussion Various factors, ranging from upper airway anatomy to central respiratory control mechanisms, interact to J. Nepal Dent. Assoc. (2009), Vol. 10, No.2 164 oral appliances on clinical outcome, the development of a clinically reliable method for identifying those patients who are most likely to achieve a favorable treatment response, and the characterization of factors predisposing to long-term adverse effects of oral appliance treatment. 5. Hoffstein V. Review of oral appliances for treatment of sleep-disordered breathing. Sleep Breath.2007; 11:1–22. 6. Chan ASL, Lee RWW, Cistulli PA. Dental appliance treatment for obstructive sleep apnea. Chest. 2007; 132:693–699. 7. Wolfgang S, Alan L,Laurel W, Rosalind C, Francisco C, Stuart M. Oral appliances for treatment of snoring and obstructive sleep apnea. A review. Sleep. 1995; 18(6): 501- 510. 8. James EE. Comparison of oral devices for snoring. J Calif Dental Assoc. 1998.August. 9. Friedlander AH et al., Diagnosing and Co managing patients with obstructive sleep apnea syndrome. J Am Dent Assoc. 2000; 131:1179- 1184. 10. Padma A, Ramakrishnan. N, Narayanan V. Management of obstructive sleep apnea: A dental perspective. Indian J Dent Res. 2007; 18(4): 201-209. 11. Joshi AS, Steven A, Bielamowicz SA, Alexander AAZ, Truelson M, Roberts DH. Snoring and Obstructive Sleep Apnea- Prosthetic Management. eMedicine Specialties: Jun28,2007. Available from http://emedicine.medscape. com/article/870192-diagnosis. References 1. 2. Veis R.W. Snoring and Obstructive Sleep Apnea from a Dental Perspective. J Calif Dental Assoc.1998.August. Johnston CD, Gleadhill IC, Cinnamond MJ, Peden MW. Oral appliances for the management of severe snoring: A randomized controlled trial. Eur J Ortho.2001:23; 127134. 3. Chan ASL, Lee RWW, Cistulli PA. Non–Positive Airway Pressure Modalities- Mandibular Advancement Devices/ Positional Therapy. Proc Am Thorac Soc.2008; 5: 179– 184 4. Tan YK et al., Mandibular advancement splints and continuous positive airway pressure in patients with obstructive sleep apnea: A randomized crossover trial. Eur J Ortho.2002; 24: 239-249. 165 J. Nepal Dent. Assoc. (2009), Vol. 10, No.2