Management of Sialorrhea in Children with Cerebral
Transcription
Management of Sialorrhea in Children with Cerebral
AMERICAN JOURNAL OF CLINICAL NEUROLOGY REVIEW ARTICLE Management of Sialorrhea in Children with Cerebral Palsy Ali Alrefai and Samah K Aburahma Affiliation: Department of Neuroscience, Jordan University of Science and Technology (JUST), Irbid, Jordan A B S T R A C T Drooling, the overflowing of saliva from the mouth, is mainly due to neurological disorder and, less frequently, to hypersalivation. Drooling is prevalent among children with cerebral palsy (CP) and has a negative impact on their social and physical wellbeing. Treatment options include oral medications, chemodenervation, and submandibular duct relocation. Although no treatment option has proven to be ideal, an optimum approach needs to be tailored to the needs of the child. This article provides an overview of the different treatment approaches and significant research findings. Keywords: drooling, cerebral palsy, botulinum toxin Correspondence: Ali Alrefai, Department of Neuroscience, Jordan University of Science and Technology (JUST), PO Box 3030, Irbid, Jordan 22110. Tel: (962)-2720-0600, Ext 40708; Fax: (962)-2720-0621; e-mail: [email protected] sublingual salivary glands produce about 70% of saliva in the resting state, although when stimulated, the parotid glands provide most of the saliva. The submandibular glands produce a high-viscosity fluid, whereas the parotids produce watery saliva. Saliva serves a number of important functions, including: (1) providing a protective effect from tooth decay and the gingival tissues from inflammation; (2) acting as a lubricant for swallowing and a solvent for facilitating taste; (3) providing an antibacterial action in the mouth; and (4) promoting protein and carbohydrate breakdown. INTRODUCTION Sialorrhea (drooling) is the unintentional loss of saliva and other oral contents from the mouth. It is a normal phenomenon of infancy that subsides in early childhood, usually by 15–18 months, as a consequence of physiological maturity of oral motor function [1]. Drooling children frequently have irritated facial skin, foul odor, and in cold weather the dampness from saliva is chilling. Their dehydration experience can be a recurrent problem from chronic fluid loss. They may also damage books, toys, computers, and other communication aids [2]. Salivary secretion is regulated by a reflex arc. The afferent part is mainly activated by stimulation of chemoreceptors located in the taste buds and mechanoreceptors located in the periodontal ligament. The afferent arc is mediated through cranial nerves V, VII, IX, and X, which carry impulses to the salivary nuclei in the medulla oblongata [4]. The efferent part of the reflex is mainly parasympathetic. Cranial nerve VII provides control of the submandibular, sublingual, and minor glands, whereas cranial nerve IX controls the parotid glands [4]. The flow of saliva is enhanced by sympathetic innervation, which promotes contraction of muscle fibers around the salivary ducts [5]. Drooling affects the social and physical wellbeing of children with cerebral palsy (CP), and may represent problems for caregivers. The unsightly nature of drooling, speech spray, and a cough or sneeze can lead to social avoidance [2]. Reported treatment options have included behavioral modification therapy, oral or topical anticholinergic medications, surgical excision of salivary glands or duct relocation, and chemodenervation with botulinum toxin. Despite the abundance of reports on the efficacy and safety profiles of each treatment option, definitive conclusions are difficult to draw, given the heterogeneous nature of the patient populations studied and the different outcome measures used in the various studies. In this review, an analysis of outcome measures commonly used for assessing response to treatment and a study of recent reports on the various therapeutic options available will be presented. ETIOLOGY AND EPIDEMIOLOGY OF DROOLING Hypersalivation, which is excessive saliva production, is not synonymous with drooling. Drooling in children with CP is usually not due to hypersalivation; in fact, in most cases, the volume of saliva produced is normal [6]. It was found that there was no statistical difference in the rate of salivary flow, the buffering capacity, and the concentration of sodium and potassium between children with CP who drool and unaffected age-matched children [6]. Drooling occurs as a result of central or peripheral etiologies. Of the central BASIC PHYSIOLOGY Healthy subjects secrete variable amounts of saliva, averaging 0.5–1.5 L/day. The parotid and submandibular glands produce about 90% of saliva [3]. The submandibular and AJCN 2010; 000:(000). Month 2010 1 www.slm-americanneurology.com American Journal of Clinical Neurology etiologies, CP is the most common cause in children. The factors that contribute to drooling in children with CP include an inefficient coordination of the oral phase of swallowing and poor lip closure [7]. This has been confirmed by comparing drinking tasks in normal children with children with CP [8]. Drooling children with CP had more trouble initiating swallowing than normal children or children with CP who did not drool. Other factors that might contribute to drooling include muscle hypotonia, macroglossia, dental malocclusion, abnormal posture, and impaired nasal airway patency [7]. observational method; it is defined as the number of times when drool was present or absent measured at 15-s intervals during two 10-min periods separated by a 60-min break. Despite the absence of studies comparing subjective and objective measures of saliva production, subjective measures frequently show an earlier and more significant response to the therapeutic intervention being studied than objective measures, and appear to parallel changes in quality of life assessments [19]. This may be because objective measures assess drooling at a given fixed period of time, whereas most subjective measures assess drooling from observations over a more extended period of time. However, as drooling is variable throughout the day, subjective tools may actually be more reflective of the true nature and burden of the problem for children with drooling, and necessarily complement information obtained from objective tools. Drooling is reported to be a significant problem in 10–37% of patients with CP [9, 10], especially children with quadriplegic CP attending special schools, where drooling was found in up to 54% of the children [11]. ASSESSMENT OF DROOLING A questionnaire was developed to document the social impact and self-esteem of treating drooling [20]. It consists of sets of multiple choice questions and a visual analog scale in which parents evaluate their experiences as well as the personal reactions of the child. A detailed history helps to assess the severity of drooling, its effects on quality of life for the patient and family, and to decide the therapeutic intervention. Both objective and subjective measures need to be utilized in assessing therapeutic intervention. Objective measures are usually aimed at measuring the amount of saliva. The commonly reported and utilized objective measures include calculating the weight of drool using dental bibs [12], weighing dental rolls placed in different areas of the mouth, positioning absorbent cotton rolls at the salivary gland duct orifice [13], and the drool quantification method [14]. The drool quantification method is an effective non-invasive evaluation tool that includes a cup-like collection device, a vacuum pump, plastic tubing, an airtight collection chamber, and a calibrated test tube. The commonly reported subjective tools include the drooling severity and frequency rating scale, Teacher Drooling Scale (TDS), Drooling Quotient (DQ), caregivers’ questionnaires, and a visual analog scale for frequency and severity of drooling [15–18]. Table 1 shows the drooling severity and frequency rating scale. The TDS is a useful tool for outpatient visits, in which the classroom teachers indicate the degree of drooling by means of a fivepoint scale. The DQ is a validated, semiquantitative, direct BEHAVIORAL TREATMENT Various behavioral techniques have been described for the treatment of drooling. Despite their appeal because of their non-invasive nature, there is a paucity of clinical research documenting their efficacy, and most reports are based on anecdotal case descriptions. Proposed techniques include various oral appliances to modify and improve oral motor function and aid lip closure [21], oral motor stimulation techniques that emphasize the enhancement of sensorimotor feedback mechanisms [22, 23], and biofeedback and automatic cueing techniques [24, 25]. However, with the complex and demanding nature of these techniques, and their dependency on the cognitive abilities of the patient, they seem to have fallen out of favor. In the authors’ opinion, behavioral techniques may have a role as adjunctive therapy with other treatment modalities; however, this requires further investigation before definitive recommendations can be made. Table 1. Drooling Frequency and Severity Rating Scale SURGICAL TREATMENT Frequency Surgery is indicated when conservative treatment has been tried for at least 6 months without reduction in drooling [19]. It is best deferred until the patient is 6 years old as, by this age, there should be full maturation of oral motor function and coordination. 15 Never drools 25 Occasionally drools (not every day) 35 Frequently drools (part of every day) 45 Constantly drools Various surgical approaches have been reported, such as parotid duct ligation with submandibular gland excision, submandibular gland duct relocation with or without sublingual gland excision, and parasympathetic neurectomy [26–29]. Salivary gland resection is associated with significant morbidity including external scar, xerostomia, and, in the worst cases, facial weakness [26]. Nowadays, the gold standard surgical procedure is submandibular duct relocation. Crysdale and White [27] reported significant reduction Severity 15 Dry (never drools) 25 Mild (only lips wet) 35 Moderate (wet on lips and chin) 45 Severe (drool extends to clothes) 55 Profuse (hands, tray, and objects wet) AJCN 2010; 000:(000). Month 2010 2 www.slm-americanneurology.com Management of sialorrhea in children with CP decrease side-effects. However, this study is limited by small sample size. In another double-blind, placebo-controlled, dose-escalating trial, we reported that bilateral parotid gland injection with BoNT-A significantly reduced the frequency and severity of drooling compared with placebo in the smaller dose, but the reduction was not statistically significant with a higher dose due to a high dropout rate from the placebo group [39]. Another dose-finding trial comparing injections into the submandibular glands alone with injections into the submandibular and parotid glands found more responders with the second approach, but no conclusions were made regarding the ideal dose [17]. In an open-label, randomized controlled trial, Reid and his group [40] reported that injection with BoNT-A into the parotid and submandibular glands in children with CP significantly reduced drooling compared with a control group. This reduction was maximal at 1 month after injection and remained significant for 6 months; nine families were still happy with the results at 1 year. No child was reinjected during this time. This is the first study with long-term follow-up. in drooling in the majority of children who underwent this procedure as the salivary flow is redirected to the back of the mouth, a site more conducive to swallowing than drooling. The absence of an external scar is appealing to both the patient and the surgeon. The disadvantages of this procedure include the need for hospitalization and ranula formation in 8% of patients. The addition of sublingual gland resection to avoid this complication was found to be ineffective and increases the chance of bleeding and pain [28]. Patients with a history of recurrent tonsillitis should have a tonsillectomy 2 or 3 months before the duct relocation. PHARMACOLOGICAL THERAPY Salivation is mediated through the autonomic nervous system, primarily by way of the cholinergic system muscarinic receptor sites. Blockage of these receptors inhibits nervous stimulation to the salivary glands. Anticholinergic drugs used to decrease drooling have widespread effects on all endorgans that are governed by muscarinic stimulation. Several clinical trials have used anticholinergic drugs to decrease drooling, but the response was usually partial and at the price of side-effects [30–32]. A double-blind, placebocontrolled, crossover trial reported that transdermal scopolamine demonstrated ‘‘a significant reduction in drooling’’ with low toxicity [30]. However, the patient population was heterogeneous, and the method of measurement of improvement was not sufficiently described. Benztropine in one double-blind trial produced a 65% decrease in drooling, but the trial term was short and had a 30% dropout rate [31]. Glycopyrrolate, a synthetic antimuscarinic agent that does not cross the blood–brain barrier, making it an interesting compound to use, has been investigated in a double-blind, dose-ranging clinical trial, and showed reduction in drooling. However, 20% had adverse effects leading to drug withdrawal [32]. Botulinum toxin type B (BTxB) has been proposed as a treatment for drooling in patients with neurological disorders such as PD and amyotrophic lateral sclerosis (ALS) [41, 42]. In a double-blind, placebo-controlled trial in 20 patients with ALS, 2500 U of BTxB or placebo was injected into the bilateral parotid and submandibular glands under electromyography (EMG) guidance [42]. Patients treated with BTxB reported a global impression of improvement of 82% at 2 weeks compared with 38% of those treated with placebo. At 12 weeks, 50% of patients who received BTxB continued to report improvement compared with 14% of those who received placebo. Based on this study, in a recent practice parameter update, the Quality Standards Subcommittee of the American Academy of Neurology has recommended the use of BTxB for patients with ALS who have medically refractory drooling (level B evidence) [43]. Botulinum toxin (BoNT), a potent exotoxin produced by Clostridium botulinum, the same organism responsible for tetanus, is another medication that may be effective in the treatment of drooling. It blocks the release of acetylcholine at the cholinergic neurosecretory junction of the target organs including the salivary glands. The first published results of BoNT-A injection to treat drooling appeared in 2000 in patients with Parkinson’s disease (PD) [33]. Since then, several case series and unblinded, open-label cohort studies have reported its effect on drooling in children with CP and other neurological disorders [34–37]. The injected salivary glands were the parotid gland alone in one study [34], the submandibular gland alone in two studies [35, 36], and both sets of glands in the third study [37]. Three controlled trials have recently been published [38–40]. A double-blind, placebo-controlled trial studying the effect of unilateral injection of the parotid and bilateral submandibular glands with BoNT-A reported that this approach reduced the drooling frequency and severity scale and drooling quotient at most follow-up periods [38]. The investigators adopted this approach with the intention of keeping at least 50% of resting and post-prandial saliva production in an attempt to www.slm-americanneurology.com In children with CP, Wilken et al [44] randomly assigned children to receive BoNT-A or BTxB into the parotid and submandibular glands on both sides, and found that reduction of drooling was achieved 2 weeks after injection, with a positive effect lasting about 3–4 months, but this reduction was not significant between both types of botulinum toxin. Although most trials have used ultrasound guidance for injection, our group reported that injection using anatomical landmarks was also effective [39]. Trials comparing blind injection based on anatomical landmarks and injection with ultrasound guidance are limited. Side-effects reported with botulinum toxin injection included thicker, more viscous saliva. The parotid glands produce thin, serous secretions unlike the submandibular glands, which produce more viscous saliva. Therefore, this side-effect is believed to be secondary to decreased parotid saliva production. Another reported side-effect is difficulty swallowing, and this is believed to be secondary to local diffusion of botulinum toxin producing weakness of surrounding muscles. Some children might require general 3 AJCN 2010; 000:(000). Month 2010 American Journal of Clinical Neurology anesthesia to administer botulinum toxin, which could increase the cost and risk of complications and side-effects. Other potential effects are hematoma, salivary duct calculi, and local injuries to the carotid arteries or branches of the facial nerve. using BoNT in treating drooling in children with CP, showing the differences in the dosages used, outcome measures, and injection sites. Despite the fact that many studies have reported that botulinum toxin is effective in treating drooling in children, there are still unanswered questions. Most studies have used small heterogeneous patient samples and subjective measures to evaluate response. Optimally, future studies should use large homogeneous patient samples and both subjective and objective outcome measures. The optimum dose, the dilution, and the number of injection sites need to be standardized. Table 2 lists some of the recent randomized clinical trials Radiotherapy (RT) to the salivary glands in doses of 10– 20 Gy in a single fraction or two fractions was used to treat drooling in patient with PD and ALS, with variable results [45–47]. The most frequent adverse events reported with RT were xerostomia and loss of taste. Xerostomia is believed to be due to the delivery of RT to the parotid glands. Such adverse events can hopefully be avoided by delivering the RT to the submandibular glands instead of the parotid glands. Another rare, but serious adverse event is the potential risk of RADIATION THERAPY Table 2. Effect of Botulinum Toxin on Drooling in Children with Cerebral Palsy Citation Study group Study type Outcome Results Comments Suskind et al (2002) [17] 22 children (8–21 years) CP Prospective, open-label, doseescalating study: 12 children with only submandibular gland injection 10, 20, 30 units and 10 children with 30 units in submandibular and 20, 30, 40 units in parotid Drooling rating scale, dental roll weight, DQ Drooling rating scale: 33% responders in group 1 and 80% responders in group 2; DQ: eight patients in group 2 have decreased DQ Different outcome measures between groups, no ideal dose Jongerius et al (2004) [18] 45 children (3–18 years) CP Controlled, open-label, clinical trial. Treatment with scopolamine patches, then with BoNT-A into submandibular glands. Total dose: 30 U if ,15 kg; 40 U if 15–25 kg; 50 U if .25 kg Saliva secretion (measured by DQ, TDS, and VAS) DQ: 53% responded to scopolamine and 64% responded to BTX-A at 2 weeks and 49% at 24 weeks. TDS: 61.5% good responders 8 weeks post BTX-A and 36% at 24 weeks 71% patients experienced moderate–severe side-effects with scopolamine. With BTX-A, only nonsevere side-effects Lin et al (2008) [38] 13 children (mean age 14.2¡ 1.8 years) Double-blind, placebocontrolled, randomized clinical trial. Treatment with BoNT-A 2 u/kg into one parotid and the contralateral submandibular gland; control group, 1.5 mL of saline Drooling severity and frequency scale, saliva weight, DQ Significant improvement in all three measures within 14 weeks, except drooling severity and frequency scale and DQ at week 4 of BoNT-A Small sample size with statistical power only 69.5% Alrefai et al (2009) [39] 24 children (21 months– 7 years) CP Double-blind, placebocontrolled, randomized clinical trial. Treatment with BoNT-A 50 U into each parotid; control group, 0.5 mL of saline Drooling severity and frequency scale Significant reduction in median severity and median frequency scale in treatment group High dropout rate in the placebo group with the higher dose (70 U into each parotid) Reid et al (2008) [40] 48 children (6–18 years) 31 with CP Placebo-controlled, randomized clinical trial. Treatment with BoNT-A 25 U into each parotid and submandibular glands; control group, no treatment DrI Significant difference between treatment and control groups in DrI scale at 1 month up to 6 months Measurement bias as the placebo group received no treatment Wilken et al (2008) [42] 30 children (1–18 years) 12 children with CP Randomized, repeated, open-label clinical trial. Treatment with BoNT-A total dose 80 u up to 100 u or serotype B 100 u/kg up to 120 u/kg (parotid and submandibular) TDS 83% of all children responded. No significant difference between serotypes A and B Five children developed viscous saliva; only 50% of children continued treatment DQ, drooling quotient; DrI, Drooling Impact Scale questionnaire; TDS, Teacher Drooling Scale; VAS, visual analog scale. AJCN 2010; 000:(000). Month 2010 4 www.slm-americanneurology.com Management of sialorrhea in children with CP malignancy in the irradiated field [46]. However, this risk is minimal, particularly in patients with ALS, as these patients have limited life expectancy. option. In these situations, regional regulations regarding the age of legal capacity and consent procedures must be consulted, and physicians are urged to seek legal advice. RT has been criticized and abandoned from use for the pediatric population because of its long-term hazards of growth retardation and risk of malignancy [48–50]. CONCLUSIONS Drooling can be a significant source of functional and social disability for a child with CP. Treatment of drooling is part of the multidisciplinary care that these patients require, which should consist of a pediatric neurologist, an otolaryngologist, a pediatric dentist, and a speech pathologist. Treatment recommendations are developed through a group decisionmaking process and are based on clinical evaluation of the type and severity of drooling and associated structural or neurodevelopmental problems. The parents and patients are included in developing a stepwise plan of no immediate treatment, intervention with oral motor techniques or equipment, biofeedback, pharmacotherapy, or surgery. There are no clinical trials comparing different treatment options (e.g., pharmacotherapy vs surgery or pharmacotherapy vs behavioral treatment), making treatment guidelines more difficult. ETHICAL CONSIDERATIONS From the above discussion on the treatment options for drooling in children with CP, it is clear that, with the exception of non-invasive behavior modification techniques, adequate explanation of the advantages and disadvantages of each treatment option is required, and treatment can only be offered after appropriate consent is obtained. Obtaining consent before providing care is both a fundamental part of good practice and a legal requirement. The process of obtaining consent will vary from simple situations such as providing behavior modifications or administering oral medications to more complex situations where a considerable amount of information would be needed to support the decision-making process, as is the case with surgical options or botulinum toxin injections. There are unique issues relating to obtaining consent from children under 16 years of age. It is automatically assumed in these cases that obtaining parental consent is sufficient. The authors stress the importance of confirming that the consenting parent is indeed the parent with legal parental responsibility as defined by regional laws and regulations. Once children reach the age of 16 years, they are considered to have reached the age of legal capacity in most countries, and are considered to be able to provide consent to medical interventions. However, physicians are urged to encourage children between the ages of 16 and 18 years to involve their families in decisionmaking, especially when the young person is making the decision to refuse a certain treatment. In addition, in many countries, for treatment decisions that are unlikely to have grave consequences, even a young person under 16 years can legally consent to treatment provided he or she is competent to understand the nature, purpose, and possible consequences of the treatment proposed, as stated in the landmark Gillick case [51]. Consent considerations are more complex for children with CP, as many are not deemed competent to make such decisions. However, a disabled child should never automatically be presumed to be incapable of making decisions regarding care, and many will be able to contribute to the decision-making process if information is presented to them appropriately and they are adequately supported during the decision-making process. Even where children are not able to give consent for themselves, it is very important to involve them as much as possible in decisions about their own health and care. Even very young children will have opinions about their health and care, and methods appropriate to their age and understanding should be used to enable these views to be taken into account. Future long-term studies with a large, homogeneous patient population should provide guidelines for the best treatment approach for this problem. Disclosure: The authors have nothing to disclose. REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. Complex situations arise at times, such as when parental responsibility cannot be verified, or when the competent child and his/her caregivers cannot agree on a certain treatment www.slm-americanneurology.com 14. 5 Blasco PA, Allaire JH. Drooling in the developmentally disabled: management practices and recommendations. Consortium on drooling. Dev Med Child Neurol. 1992;34:849–862. Finkelstein DM, Crysdale WS. Evaluation and management of the drooling patient. J Otolaryngol. 1992;21:414–418. Becks H, Wainwright W. Human saliva: rate of flow of resting saliva of healthy individuals. Neurogastroenterol Motil. 1943;22:391–396. Garrett JR, Proctor GB. Control of salivation. In: Linden RWA, ed. The Scientific Basis of Eating. Ront Oral Biol. Basel: Karger; 1998:135–155. Hockstein NG, Samadi DS, Gendron K, Handler SD. Sialorrhea: a management challenge. Am Fam Physician. 2004;69:2628–2634. Tahmassebi JF, Curzon ME. The cause of drooling in children with cerebral palsy—hypersalivation or swallowing defect. Int J Paediatr Dent. 2003;13:106–111. Myer CM. Sialorrhea. Pediatr Clin North Am. 1989;36:1495–1500. Sochaniwskyj AE, Koheil RM, Bablich K, Milner M, Kenny DJ. Oral motor functioning, frequency of swallowing and drooling in normal children and in children with cerebral palsy. Arch Phys Med Rehabil. 1986;61:866– 874. Harris SR, Purdy AH. Drooling and its management in cerebral palsy. Dev Med Child Neurol. 1987;29:807–811. Van de Heyning PH, Marquet JF, Creten WL. Drooling in children with cerebral palsy. Acta-Oto-Rhino-Laryngol Belg. 1980;34:691–705. Tahmassebi JF, Curzon MEJ. Prevalence of drooling in children with cerebral palsy attending special schools. Dev Med Child Neurol. 2003;45: 613–617. Osborne JG, Gatling JH, Blakelock J, Peine H, Jenson W. Observation and measurement of drooling by people with mental retardation. Ment Retard. 1994;32:288–298. Dogu O, Apaydin D, Sevim S, Talas DU, Aral M. Ultrasound-guided versus ‘‘blind’’ intraparotid injections of Botulinum toxin-A for the treatment of sialorrhoea in patients with Parkinson’s disease. Clin Neurol Neurosurg. 2004;106:93–96. Sochaniwskyj AE. Drool quantification: non-invasive technique. Arch Phys Med Rehabil. 1982;63:605–607. AJCN 2010; 000:(000). Month 2010 American Journal of Clinical Neurology 40. Reid SM, Johnstone BR, Westbury C, Rawicki B, Reddihough DS. Randomized trial of botulinum toxin injections into the salivary glands to reduce drooling in children with neurological disorders. Dev Med Child Neurol. 2008;50:123–128. 41. Ondo WG, Hunter C, Moore W. A double-blind placebo-controlled trial of botulinum toxin B for sialorrhea in Parkinson’s disease. Neurology. 2004;62:37–40. 42. Jackson CE, Gronseth G, Rosenfeld J, et al. Randomized double-blind study of botulinum toxin type B for sialorrhea in ALS patients. Muscle Nerve. 2009;39:137–143. 43. Miller RG, Jackson CE, Kasarskis EJ, et al. Practice parameter update: the care of the patient with amyotrophic lateral sclerosis: drug, nutritional, and respiratory therapies (an evidence-based review): report of the Quality Standards Subcommittee of the American Academy of Neurology. Neurology. 2009;73:1218–1226. 44. Wilken B, Aslami B, Backes H. Successful treatment of drooling in children with neurological disorders with botulinum toxin A or B. Neuropediatrics. 2008;39:200–204. 45. Postma AG, Heesters M, Van Laar T. Radiotherapy to the salivary glands as treatment of sialorrhea in patients with parkinsonism. Mov Disord. 2007;22:2430–2435. 46. Stalpers LJ, Moser EC. Results of radiotherapy for drooling in amyotrophic lateral sclerosis. Neurology. 2002;58:1308. 47. Neppelberg E, Haugen DF, Thorsen L, Tysnes OB. Radiotherapy reduces sialorrhea in amyotrophic lateral sclerosis. Eur J Neurol. 2007;14:1373– 1377. 48. Vaughn JM. The effects of radiation on bone. In: Bourne CH, ed. The Biochemistry and Physiology of Bone. New York: Academic Press; 1976. 49. Martin H, Strong E, Spiro RH. Radiation-induced skin cancer of the head and neck. Cancer. 1970;25:61–71. 50. Schneider AB, Lubin J, Ron E, et al. Salivary gland tumors after childhood radiation treatment for benign conditions of the head and neck: doseresponse relationships. Radiat Res. 1998;149:625–630. 51. Gillick v West Norfolk and Wisbech AHA [1986]. AC 112 and 113. 15. Stonell TN, Greenberg J. Three treatment approaches and clinical factors in the reduction of drooling. Dysphagia. 1988;3:73–78. 16. Reddihough D, Johnson H, Ferguson E. The role of a saliva control clinic in the management of drooling. J Paediatr Child Health. 1992;28:395–397. 17. Suskind DL, Tilton A. Clinical study of botulinum—a toxin in the treatment of sialorrhea in children with cerebral palsy. Laryngoscope. 2002; 112:73–81. 18. Jongerius PH, Van den Hoogen FJ, Limbeek JV, Gabree¨ls FJ, Van Hulst K, Rotteveel JJ. Effect of botulinum toxin in the treatment of drooling: a controlled clinical trial. Pediatrics. 2004;114:620–627. 19. Crysdale WS. Management options for the drooling patient. Ear Nose Throat J. 1989;68:820, 825–826, 829–830. 20. Van der Burg JJ, Jongerius PH, van Limbeek J, van Hulst K, Rotteveel JJ. Social interaction and self-esteem of children with cerebral palsy after treatment for severe drooling. Eur J Pediatr. 2006;165:37–41. 21. Johnson HM, Reid SM, Hazard CJ, Lucas JO, Desai M, Reddihough DS. Effectiveness of the Innsbruck Sensorimotor Activator and Regulator in improving saliva control in children with cerebral palsy. Dev Med Child Neurol. 2004;46:39–45. 22. McCracken, A. Drool control and tongue thrust therapy for the mentally retarded. Am J Occup Ther. 1978;32:79–85. 23. Domaracki LS, Sisson LA. Decreased drooling with oral motor stimulation in children with multiple disabilities. Am J Occup Ther. 1990; 44:680–684. 24. Koheil R, Sochaniwskyj AE, Bablich K, Kenny DJ, Milner M. Biofeedback techniques and behaviour modification in the conservative remediation of drooling by children with cerebral palsy. Dev Med Child Neurol. 1987;29: 19–26. 25. Lancioni GE, Brouwer JA, Coninx F. Automatic cueing to reduce drooling: a long-term follow-up with two mentally handicapped persons. J Behav Ther Exp Psychiatry. 1994;25:149–152. 26. Burton MJ. The surgical management of drooling. Dev Med Child Neurol. 1991;33:1110–1116. 27. Crysdale WS, White A. Submandibular duct relocation for drooling: a 10year experience with 194 patients. Otolaryngol Head Neck Surg. 1989;101:87– 92. 28. Glynn F, Dwyer TP. Does the addition of sublingual gland excision to submandibular duct relocation give better overall results in drooling control? Clin Otolaryngol. 2007;32:103–107. 29. Michel RG, Johnson KA, Patterson CN. Parasympathetic nerve section for control of sialorrhea. Arch Otolaryngol. 1977;103:94–97. 30. Lewis DW, Fontana C, Mehallick L, Everett Y. Transdermal scopolamine for reduction of drooling in developmentally delayed children. Dev Med Child Neurol. 1994;36:484–486. 31. Camp-Bruno JA, Winsberg BG, Green-Parsons AR, Abrams JP. Efficacy of benztropine therapy for drooling. Dev Med Child Neurol. 1989;31:309–319. 32. Mier RJ, Bachrach SJ, Lakin RC, Barker T, Childs J, Moran M. Treatment of sialorrhea with glycopyrrolate: a double-blind, dose-ranging study. Arch Pediatr Adolesc Med. 2000;154:1214–1218. 33. Pal PK, Calne DB, Calne S, Tsui JKC. Botulinum toxin A as treatment for drooling saliva in PD. Neurology. 2000;54:244–247. 34. Bothwell JE, Clarke K, Dooley JM, et al. Botulinum toxin a as a treatment for excessive drooling in children. Pediatr Neurol. 2002;27:18–22. 35. Jongerius PH, Hulst KV, van den Hoogen FJA, Rotteveel JJ. The treatment of posterior drooling by botulinum toxin in a child with cerebral palsy. J Pediatr Gastroenterol Nutr. 2005;41:351–353. 36. Jongerius PH, Rotteveel JJ, Van den Hoogen F, Joosten F, Van Hulst K, Gabree¨ls FJ. Botulinum toxin A: a new option for treatment of drooling in children with cerebral palsy. Presentation of case series. Eur J Pediatr. 2001;160:509–512. 37. Banerjee KJ, Glasson C, O’Flaherty SJ. Parotid and submandibular botulinum toxin A injections for sialorrhoea in children with cerebral palsy. Dev Med Child Neurol. 2006;48:883–887. 38. Lin Y, Shieh J, Cheng M, Yang P. Botulinum toxin type A for control of drooling in Asian patients with cerebral palsy. Neurology. 2008;70:316– 318. 39. Alrefai AH, Aburahma SK, Khader YS. Treatment of sialorrhea in children with cerebral palsy: a double-blind placebo controlled trial. Clin Neurol Neurosurg. 2009;111:79–82. AJCN 2010; 000:(000). Month 2010 6 www.slm-americanneurology.com