Adjunctive effect of hyperbaric oxygen treatment patients with acute myocardial infarction
Transcription
Adjunctive effect of hyperbaric oxygen treatment patients with acute myocardial infarction
Adjunctive effect of hyperbaric oxygen treatment after thrombolysis on left ventricular function in patients with acute myocardial infarction Milica Dekleva, MD, PhD,a Aleksandar Neskovic, MD, PhD, FESC,d Alja Vlahovic, MD,d Biljana Putnikovic, MD, PhD,b Branko Beleslin, MD, FESC,c and Miodrag Ostojic, MD, PhD, FESC, FACCc Belgrade, Serbia and Montenegro Background The role of hyperbaric oxygen in patients with acute myocardial infarction is controversial, ranging from not beneficial to having a favorable effect. This randomized study was conducted to further assess the benefit of hyperbaric oxygen treatment after thrombolysis on left ventricular function and remodeling in patients with acute myocardial infarction. Methods Seventy-four consecutive patients with first acute myocardial infarction were randomly assigned to treatment with hyperbaric oxygen treatment combined with streptokinase (HBO⫹) or streptokinase alone (HBO⫺). Results There was a significant decrease of end-systolic volume index from the first day to the third week in HBO⫹ patients compared with HBO⫺ patients (from 30.40 to 28.18 vs from 30.89 to 36.68 mL/m2, P ⬍ .05) accompanied with no changes of end-diastolic volume index in HBO⫹ compared with increased values in HBO⫺ (from 55.68 to 55.10 vs from 55.87 to 63.82 mL/m2, P ⬍ .05). Ejection fraction significantly improved in the HBO⫹ group and decreased in the HBO⫺ group of patients after 3 weeks of acute myocardial infarction (from 46.27% to 50.81% vs from 45.54% to 44.05 %, P ⬍ .05). Conclusions Adjunctive hyperbaric oxygen therapy after thrombolysis in acute myocardial infarction has a favorable effect on left ventricular systolic function and the remodeling process. (Am Heart J 2004;148:e14.) Normobaric therapy has been in use for many years in the treatment of ischemic heart disease.1 When oxygen is breathed in concentrations higher than those found in the atmospheric air, it is considered to be a drug. A limited amount of oxygen is dissolved in blood in normal atmospheric pressure, but under hyperbaric conditions, it is possible to dissolve sufficient oxygen, for example, 6%, in plasma to meet the usual requirements of the body. The oxygen physically dissolved in solution will be utilized more readily than that bound to hemoglobin, and this effect may normalize or increase oxygen tension in ischemic tissue.1 Calvert et al2 reported that hyperbaric oxygen (HBO) could be a treatment for neonatal hypoxia-ischemia in a neonatal rat model and could prevent brain injury. In From aClinical Medical Center “Dr Dradisa Misovic-Dedinje”, bClinical Medical Center “Zemun”, cInstitute for Cardiovascular Diseases Clinical Center of Serbia, and dInstitute for Cardiovascular Diseases, “Dedinje,” Belgrade, Serbia and Montenegro. Reprint requests: Milica Dekleva, MD, PhD, Clinical Medical Center “Dr Dragisa Misovic-Dedinje.” Department of Echocardiography. Milana Tepica 1 St, 11000 Belgrade, Serbia and Montenegro. E-mail: [email protected] 0002-8703/$ - see front matter © 2004, Elsevier Inc. All rights reserved. doi:10.1016/j.ahj.2004.03.031 that study, HBO was administered in a chamber for 1 hour at 3 ATA (absolute pressure of 1 atmosphere), 1 hour after hypoxia exposure. Results suggested that HBO, as a single therapy, is able to attenuate hypoxiaischemia brain insult and offer neuroprotectivity. HBO reduced neuronal injury with much less atrophy and apoptosis of immature neurons, resulting in further improvement of sensorimotor function of neonatal brain. The role of HBO in patients with acute myocardial infarction is controversial, ranging from no beneficial effect3,4 to a favorable effect.5,6 The only controlled trial done by Thurston et al,5 in the prethrombolytic era, revealed a trend but not a statistically significant decrease in mortality rates, especially in high-risk patients. An animal study conducted by Thomas et al6 proved the hypothesis that a combination of thrombolytic therapy and HBO would be more effective in reducing the size of the myocardial infarction than either of these modalities alone. Therefore, a randomized pilot trial conducted by Shandling et al7 demonstrated that adjunctive treatment with HBO appears to be feasible and safe for patients in the acute phase of myocardial infarction. Finally, the Hyperbaric Oxygen and American Heart Journal October 2004 2 Dekleva et al Thrombolysis in Myocardial Infarction (HOT MI) study demonstrated that treatment with HBO in combination with thrombolysis might result in an attenuated creatine phosphokinase rise, more rapid resolution of pain, and improved ejection fraction (EF).8 The following randomized study was designed to further assess the benefit of thrombolysis in combination with HBO on the remodeling process and left ventricular function preservation in patients with acute myocardial infarction. Figure 1 Methods Study population The study population consisted of consecutive patients with first myocardial infarction who met the following criteria: (1) age ⬍70 years, (2) chest pain lasting 30 to 360 minutes, (3) ST-segment elevation ⬎2 mm in ⬎2 contagious electrocardiographic leads, (4) transient creatine phosphokinase and/or MB isoenzyme increase, and (5) first echocardiogram performed within 24 hours of the onset of pain. Exclusion criteria were standard for thrombolysis, including suspected aortic dissection, recent surgery, recent peptic ulcer, and stroke. Exclusion criteria also included patients with malignant arrhythmias and severe hemodynamic instability, with Killip classes III and IV, non–rapidly controlled with intravenous medication, and patients with previous myocardial infarction or bypass surgery. Further exclusions to HBO were the inability to equilibrate pressure in the middle ear space secondary to upper respiratory tract infections, otitis or rhinitis, severe claustrophobia, and chronic obstructive pulmonary disease. From 92 patients with acute myocardial infarction originally considered for the study, 18 were subsequently excluded. Five patients were excluded because of rhythm and hemodynamic instability in the emergency room. Six patients refused coronary angiography, which also represents exclusion criteria in this study. Three patients refused entry into the HBO chamber: two because they felt claustrophobia in the chamber and one because of chronic otitis media. Four patients had chronic obstructive pulmonary disease with marked CO2 retention. In patients who started HBO, there were no complications inside the chamber or after the treatment and no need for urgent decompression. Thus, the final study population consisted of 74 patients (63 men, 11 women; mean age, 55 ⫾ 7 years). Study procedure Streptokinase was administered at the dose of 1.5 mU/L over 30 to 60 minutes, followed by intravenous heparin infusion. With a random number table, patients were randomly assigned to streptokinase therapy alone (HBO⫺ group, 37 patients) or streptokinase with HBO (HBO⫹ group, 37 patients). The patients randomly assigned to streptokinase plus HBO were transferred to the hyperbaric unit in the first 24 hours from the onset of symptoms and after thrombolytic therapy. The time from cessation of thrombolytic therapy to HBO ranged from 45 minutes to 18 hours, with average time of 10 hours (Figure 1). The patients randomly assigned to Time distribution from thrombolysis to HBO. HBO were pressurized during a 20-minute period up to 2 ATA. They remained at this pressure during 60 minutes in the monoplace hyperbaric chamber. Decompression time was 20 minutes with decreasing pressure change 0.2 ATA/ min. A critical care nurse and cardiologist were in attendance at all times. By using electrocardiographic cables with 3 terminals, all patients in the chamber were monitored, including electrocardiograms and respiratory traces. Measuring of noninvasive blood pressure inside the hyperbaric chamber was done in an automatic reading system, which measures the pressure displayed from the oscillometric method at preset intervals. All monitoring devices, drug protocols, and other procedures in the intensive care unit continued when patients were discharged inside the chamber. Monoplace chambers exclude possible nurse assistance, so these chambers have an option of emergency decompression within at least 1 minute, depending on the nature of critical situation. All patients were assessed clinically at study entry for the presence or absence of heart failure on the basis of Killip criteria. Creatine phosphokinase samples were obtained on admission, every 4 hours for the first 24 hours, and afterward on daily basis. Coronary angiography was performed after hospital discharge. Perfusion of the infarct-related artery was assessed by using criteria from the Thrombolysis In Myocardial Infarction (TIMI) trial.11 Successful reperfusion was coded as TIMI grade 3. Echocardiography Two-dimensional echocardiography was performed with an Acuson 128 imaging system on day 1 after thrombolysis or immediately after thrombolysis plus HBO treatment, on day 2, and after 3 weeks in all patients. All measurements were performed off-line, calculated from the mean value of 3 best consecutive cardiac cycles. The physician, who assessed left ventricular function, was blinded to the random assignment status of the patient. Left ventricular volumes and EF were determined from apical 2- and 4-chamber views, using the Simpson biplane formula. The left ventricular volumes, end- American Heart Journal Volume 148, Number 4 Dekleva et al 3 Table I. Demographic, clinical, and angiographic characteristics of patients Age (y) Sex (F/M) Hypertension Diabetes mellitus Smoking Killip class ⬎2 Time to STK (h) Anterior MI Peak CK value (U/L) Multivessel CAD TIMI 3 flow Collaterals Cardiac mortality Table II. Medical treatment of patients during in-hospital period HBOⴙ (n ⴝ 37) HBOⴚ (n ⴝ 37) P value 55 ⫾ 7 8/29 14 (38%) 8 (22%) 30 (81%) 2 (5%) 2.4 ⫾ 1.6 14 (38%) 989 ⫾ 643 19 (51%) 22 (59%) 9 (24%) 0 (0%) 54 ⫾ 8 3/34 13 (35%) 2 (5%) 27 (73%) 5 (14%) 3.0 ⫾ 1.5 16 (43%) 1529 ⫾ 1187 20 (54%) 22 (59%) 9 (24%) 1 (3%) NS NS NS ⬍0.05 NS NS NS NS ⬍0.05 NS NS NS NS Heparin Aspirin Oral anticoagulation Nitroglycerin IV Long-acting nitrates Calcium channel blockers -Blockers Digitalis Diuretics ACE inhibitors HBOⴙ (n ⴝ 37) HBOⴚ (n ⴝ 37) P value 37 (100%) 36 (97%) 5 (14%) 7 (19%) 30 (81%) 1 (3%) 26 (70%) 1 (3%) 3 (8%) 8 (22%) 37 (100%) 36 (97%) 8 (22%) 8 (22%) 31 (84%) 1 (3%) 23 (62%) 1 (3%) 5 (14%) 12 (32%) NS NS NS NS NS NS NS NS NS NS Figure 2 CAD, Coronary artery disease; CK, creatine phosphokinase; STK, streptokinase. diastolic and end-systolic, were normalized for body surface area and expressed as indexes (EDVI and ESVI).12 Statistical analysis The unpaired t test and 2 test were used to test the differences between 2 groups of patients. The paired t test was used to compare initial left ventricular volume indexes and EF, with results performed after 3 weeks. Analysis of variance was used for analyzing repeated measures of left ventricular volumes indexes, and EF. Probability values of ⬍.05 were considered statistically significant. Results Demographic, clinical, and angiographic data Patient demographics and clinical and angiographic data are listed in Table I. There was no significant difference between study groups with regard to the age, sex, prevalence of hypertension, and smoking history. According to anamnesis and adjusted analysis for diabetic status at baseline, there were more diabetic patients in the HBO⫹ group, but these distributions have no obvious influence on the final results. The distribution of localization of myocardial infarction was similar in both study groups. Patients in both groups were evenly distributed in either Killip class I or II. With regard to coronary angiography, there were no significant differences between the two groups in infarction artery patency, single or multivessel coronary artery disease, or collateral vessel presence. However, patients receiving thrombolytic therapy alone showed a higher peak creatine phosphokinase activity compared with the HBO⫹ group (989 vs 1529 IU, P ⬍ .05). As shown in Table II, both groups of patients received similar medication before HBO, during their hospital stay, and at the time of discharge, including Changes of ESVI in acute myocardial infarction in HBO⫹ and HBO⫺ groups of patients. Large box/upper border, 75% percentile; large box/lower border, 25% percentile; line in the middle of the large box, median; small box inside large one, ⫾mean value. *Confidence interval, 1% to 99%. ACE inhibitors, anticoagulants, aspirin, -blockers, longacting nitrates, intravenous nitroglycerin, calcium channel inhibitors, digitalis, and diuretics (P ⫽ not significant). Left ventricular function and remodeling In the current study, using serial echocardiography examinations, we were able to observe the pattern of changes of left ventricular volumes and EF in respect to HBO treatment and to compare the baseline values with subsequent studies up to 3 weeks. The changes in left ventricular volumes and EF are presented in Figure 2, Figure 3, and Figure 4. Initial left ventricular volume indexes and EF were similar in two study groups (P ⫽ not significant). In patients treated with thrombolysis only, there were significant American Heart Journal October 2004 4 Dekleva et al Figure 3 to 50.81%). Thus, 3 weeks after acute myocardial infarction, the HBO⫹ group compared with the HBO⫺ group of patients had lower ESVI (28.18 vs 36.68 mL/ m2, P ⬍ .001) (Figure 2) and EDVI (56.2 vs 63.8 mL/ m2, P ⬍ .001) (Figure 3) and higher EF (44.05% vs 50.,81%, P ⬍ .001) (Figure 4). As shown in the figures, the main effect of HBO was achieved during the very first days of acute myocardial infarction, with significant difference in ESVI and EF on day 2 in favor of the HBO⫹ group. In the subsequent 3-week follow-up period, further changes of left ventricular function indexes were slight and statistically nonsignificant. Discussion Changes of EDVI in acute myocardial infarction in HBO⫹ and HBO⫺ groups of patients. Large box/upper border, 75% percentile; large box/lower border, 25% percentile; line in the middle of the large box, median; small box inside large one, ⫾mean value. *Confidence interval, 1% to 99%. Figure 4 Changes of EF in acute myocardial infarction in HBO⫹ and HBO⫺ groups of patients. Large box/upper border, 75% percentile; large box/lower border, 25% percentile; line in the middle of the large box, median; small box inside large one, ⫾mean value. *Confidence interval, 1% to 99%. increases of ESVI (from 30.89 to 36,68 mL/m2) and EDVI (from 55.87 to 63.82 mL/m2) and decreases of EF (45.8% to 44.2%) during the first 3 weeks. Conversely, in the HBO⫹ group, EDVI did not change significantly (from 55.68 to 56.24 mL/m2), ESVI decreased significantly (from 30.40 to 28.18 mL/m2), and EF improved during the follow-up period (from 46.27% The major original findings of this study relate to the changes of left ventricular volumes in the time course estimated by echocardiography. We have shown that HBO and streptokinase in acute myocardial infarction reduced left ventricular volumes with associated increase in EF during the first 3 weeks after acute myocardial infarction. In contrast, there was progressive left ventricular dilation, with no change in EF in patients treated with thrombolysis only. Comparison with previous studies Left ventricular dilation in the first 3 weeks of myocardial infarction is determined mostly by the expansion process, infarct-related artery patency, and infarct localization.11–13,15 Popovic et al16 have shown that the degree of EDVI increase for the period of 3 weeks after acute myocardial infarction was 6.0% in patients treated with streptokinase only. In our study, a similar increase of EDVI was found in the HBO⫺ group but a lower degree was found in the HBO⫹ group (55.9 to 63.8 mL/m2, 14.1%, vs 55.7 to 56.2 mL/m2, 0.9%) (P ⬍ .001). Similarly, Chareonthaitawee et al14 have shown that the degree of ESVI increase in thrombolytictreated patients was 12% in the acute phase, which correlates well with our results in HBO⫺ patients (30.1 to 36.7 mL/m2, 21.9%). In contrast, the decrease of ESVI during 3 weeks (30.4 vs 28.2 mL/m2, 7%) demonstrated a significant benefit of HBO. Concerning EF, the Intravenous Streptokinase in Acute Myocardial Infarction (ISAM) study demonstrated significant improvement of EF (5.3%) in patients treated with streptokinase compared with the control group.17 This difference was also seen in the study by White et al13 (10%), the GISSI-2 study18 (2% to 3%), the European Cooperative study Grupo Trial19 (4%), and the Western Washington Trial20 (5%). In our study, the difference in EF was not observed in the HBO⫺ group, but in the HBO⫹ group, EF significantly increased for 9.8% (46.3% to 50.8%). A favorable effect of the combination of thrombolysis and HBO on left ventricular EF has been demonstrated in the HOT MI study by Sta- American Heart Journal Volume 148, Number 4 vitsky et al.8 This multicenter study demonstrated higher values of left ventricular EF at discharge time in patients treated with adjunctive HBO compared with control subjects treated with thrombolysis only (48.4% vs 51.7%).8 Both of these studies reported a benefit of HBO as a single adjuvant therapy, without repeated exposure, but Wada et al9,10 showed a protective effect of repetitive HBO against ischemia in a brain experimental model. According to these results, the best tolerance against neuronal damage of the hippocampus of Mongolian gerbils was induced with pretreatment in 5 sessions of HBO, every other day, compared with single HBO pretreatment or with ischemic control group. Regarding prognostic importance of left ventricular volumes, White et al13 have shown that left ventricular volumes were clearly associated with death; that is, ESVI was the most powerful predictor of survival, and the inclusion of EDVI or EF in a multivariate model added no further prognostic power. Myocardial enzymes Standard reflow with thrombolysis is followed with significant creatine phosphokinase enzyme leakage or washout effect, evidenced as an increased total activity in blood after thrombolysis. In our study, peak creatine phosphokinase level was 35.3% lower in the HBO⫹ group of patients than in the HBO⫺ group. Very similar data were reported in a randomized pilot trial by Shandling et al,7 demonstrating that mean creatine phosphokinase level at 12 and 24 hours was reduced in patients given HBO by approximately 35% (P ⫽ .03). An attenuated rise in creatine phosphokinase (7.5%) in patients treated with thrombolysis and HBO is one of the main remarks of the HOT MI study by Stavitsky et al.8 Also, in an animal study conducted by Thomas et al,6 HBO combined with thrombolysis restored 95% of normal oxidative enzyme activity and decreased the release of creatine phosphokinase into blood, thus better preserving myocardial fiber integrity. Mechanism of improvement in left ventricular function In the presence of a critical coronary artery stenosis, the oxygen demand changes. In these circumstances, increased dissolved oxygen fraction under hyperbaric conditions could be enough to meet resting cellular requirements without any contribution from oxygen bound to hemoglobin from increased blood flow.1 The quantity of oxygen carried in the plasma and tissue fluid under hyperbaric conditions in this study is increased 10-fold compared with breathing room air. The net effect, with an HBO treatment at 2 ATA absolute pressure, is an approximately 25% enhanced oxygen blood content and consumption and increased Dekleva et al 5 tissue oxygen diffusion distance by a factor 3 or 4. Therefore, high oxygen tension and an increased amount of available tissue oxygen, pressure difference between ischemic and nonischemic tissue, consequently improved penetration of oxygen into hypoxic tissues.6 Reduction in heart rate during compression time that was based on decrease of sympathetic activity could be part of the mechanism of left ventricular function improvement.5 Tissue oxygen tension remained elevated for some hours after cessation of HBO treatment.21 Thus, the tissue remains oxygenated after completion of the HBO treatment. According to our results, the most powerful effect was on left ventricular remodeling and left ventricular function at the first days of acute myocardial infarction. The “late effect” could result in sustained beneficial effects even after decompression, allowing improved myocardial salvage in that group of patients who have late reperfusion. Other mechanisms may be responsible for improved regional wall motion. Through favorable changes in myocardial oxygen supply and demand, HBO improved contraction of hibernating myocardium after myocardial infarction that is indicated in the study conducted by Swift et al.21 In our study, the increase of global left ventricular function is followed by improvement of global systolic function in HBO⫹ patients compared with the HBO⫺ group. During left ventricular remodeling, there are structural changes in coronary microcirculation followed by decreased capillary density, with enlarged diffusion distances for oxygen and disturbed perfusion of the capillary bed.22 Microvascular obstruction after reperfusion may be the consequence of low or no reflow phenomena. These obstructive myocardial zones have a great influence on the left ventricular remodeling process and left ventricular function.23,24 Favorable effects of HBO in decreasing leukocyte endothelial adherence and improvement of angiogenesis is also a contributory mechanism.23,25 There was initially concern that an increase in free oxygen radicals, occurring by the high oxygen tension state of HBO treatment, would emphasize tissue reperfusion injury.1,25 However, the results from our study do not suggest that this mechanism occurs to any noticeable clinical sign in patients treated with 2 ATA HBO protocol. Recent and present investigators have shown that HBO lessens or may inhibit reperfusion injury by protection of oxidative metabolism in reperfusion-stunned myocardium.23,25,26 Results of the studies conducted by Wada et al showed an HBO effect on immunoreactivity to apoptosis-regulating protein (Bc1-2, Bax) and manganese superoxide dismutase (Mn SOD), a radical scavenging system. This protective mechanism of repeated HBO pretreatment induced tolerance against ischemic neuronal damage in gerbil 6 Dekleva et al hippocampus. Protection against mitochondrial alterations after ischemia through Mn SOD and/or Bc1-2 expression may be related to induction of ischemic tolerance by HBO.10,27 Study limitations The data apply to the patients treated only with streptokinase, and the results may be different for the patients treated with other lytic agents or combination therapies. Because HBO treatment requires additional logistic support, we excluded from the study high-risk patients with severe heart failure as well as patients with significant electrical complications, who may actually have the greatest benefit from combined HBO and thrombolysis therapy. In the current study, the time from streptokinase to HBO treatment was prolonged because of the distance between hyperbaric unit and the coronary care unit. A larger group of patients treated with HBO after thrombolysis may demonstrate event-free survival benefits, as compared with those treated with thrombolysis alone. Clinical implications Our data indicate the adjunctive effect of HBO after thrombolysis, resulting in attenuated creatine phosphokinase rise and improvement of left ventricular function in the acute phase of myocardial infarction. Repeated HBO sessions during the acute phase of myocardial infarction could be of great importance by inducing ischemic tolerance and attenuating left ventricular remodeling. Further multicenter clinical trials are needed to evaluate possible improvement of event-free survival and mortality rates. References 1. Jain KK. Hyperbaric oxygen therapy in cardiovascular diseases. In: Jain KK, editor. Textbook of Hyperbaric Medicine. Seattle: Hogrefe and Huber; 1990. pp. 283–307. 2. Calvert JW, Yin W, Patel M, et al. Hyperbaric oxygenation prevented brain injury induced by hypoxia-ischemia in a neonatal rat model. Brain Res 2002;27:951:1– 8. 3. Cameron AJV, Hutton I, Kenmure ACF, et al. Hemodynamic and metabolic effects of hyperbaric oxygen in myocardial infarction. Lancet 1966:833–7. 4. Ashfield R, Gavey CJ. Severe acute myocardial infarction treated with hyperbaric oxygen: report on forty patients. Postgrad Med 1969;45:648 –54. 5. Thurston JGB, Greenwood TW. Results of a controlled trial of hyperbaric oxygen in acute myocardial infarction. Q J Med 1973; 168:752–70. 6. Thomas MP, Brown LA, Sponseller DR, et al. Myocardial infarction size reduction by synergistic effect of hyperbaric oxygen and recombinant tissue plasminogen activator. Am Heart J 1990;120: 791– 800. American Heart Journal October 2004 7. Shandling AH, Ellestad MH, Hart GB, et al. Hyperbaric Oxygen and Thrombolysis in Myocardial Infarction: the “HOT MI” pilot study. Am Heart J 1997;134:544 –50. 8. Stavitsky Y, Shanding AH, Ellestad MH, et al. Hyperbaric Oxygen and Thrombolysis in Myocardial Infarction: the “HOT MI” Randomized Multicenter Study. Cardiology 1998;90:131– 6. 9. Wada K, Ito M, Miyazama T, et al. Repeated hyperbaric oxygen induces ischemic tolerance in gerbil hippocampus. Brain Res 1996;18:15–20. 10. Wada K, Miyzama T, Nomura N, et al. Preferential conditions for and possible mechanism of induction of ischemic tolerance by repeated hyperbaric oxygenation in gerbil hippocampus. Neurosurgery 2001;49:160 –7. 11. TIMI Study Group. The Thrombolysis In Myocardial Infarction (TIMI) trial: phase I findings. N Engl J Med 1985;312:932– 6. 12. Shiller N, Shah PM, Crawford M, et al. Recommendations for quantitation of the left ventricle by two-dimensional echocardiography. J Am Soc Echocardiogr 1989;2:358 – 68. 13. White HD, Noris RM, Brown MA, et al. Left ventricular end-systolic volume as the major determinant of survival after recovery from myocardial infarction. Circulation 1987;76:44 –51. 14. Chareonthaitawee P, Christian TF, Hirose K, et al. Relation of initial infarct size to left ventricular remodeling in the year after acute myocardial infarction. J Am Coll Cardiol 1995;25:567–73. 15. Anversa P, Olivetti G, Capasso M, et al. Cellular basis of ventricular remodeling after myocardial infarction. Am J Cardiol 1991;68: 7D–16D. 16. Popovic AD, Neskovic AN, Babic R, et al. Independent impact of thrombolytic therapy and vessel patency on the left ventricular dilatation after myocardial infarction: serial echocardiographic follow-up. Circulation 1994;90:800 –7. 17. ISAM Study Group. Prospective trial of intravenous streptokinase in acute myocardial infarction (ISAM). N Engl J Med 1986;314: 1465–71. 18. GISSI-2: A fractional randomized trial of alteplase versus streptokinase and heparin versus no heparin among 12,490 patients with acute myocardial infarction. Lancet 1990;336:65–71. 19. Van de Werf F, Arnold AER. Intravenous tissue plasminogen activator and size of infarct, left ventricular function and survival in acute myocardial infarction. Br Med J 1988;297:1374 –9. 20. Ritchie JL, Cerqueira M, Maynard C, et al. Ventricular function and infarct size: the Western Washington Intravenous Streptokinase in Myocardial Infarction Trial. J Am Coll Cardiol 1988;11: 689 –97. 21. Swift PC, Turner JH, Oxer HF, et al. Myocardial hibernation identified by hyperbaric oxygen treatment and echocardiography in postinfarction patients: comparison with exercise thallium scintigraphy. Am Heart J 1992;124:1151–7. 22. Rochitte CE, Lima AC, Bluemke DA, et al. Microvascular obstruction and tissue injury after acute MI. Circulation 1998;98:1006 – 15. 23. Wu KC, Kim RJ, Bluemke DA, et al. Quantification and time course of microvascular obstruction by contrast enhanced echocardiography and magnetic resonance imaging following acute myocardial infarction and reperfusion. J Am Coll Cardiol 1998;32: 1756 – 64. 24. Wu KC, Zerhouni EA, Judd RM, et al. The prognostic significance of microvascular obstruction by magnetic resonance imaging in patients with acute myocardial infarction. Circulation 1998;97: 765–72. American Heart Journal Volume 148, Number 4 25. Zamboni WA, Roth AC, Russell CR, et al. Morphological analysis of the microcirculation during reperfusion of ischemic skeletal muscle and the effect of hyperbaric oxygen. Plast Reconstr Surg 1993;91:110–23. 26. Davies MJ. Reactive oxygen species: metalloproteinase and plaque Dekleva et al 7 stability. Circulation 1998;97:2382–3. 27. Wada K, Miyazama T, Nomura N, et al. Mn-SOD and Bc1-2 expression after repeated hyperbaric oxygenation. Acta Neurochir Suppl 2000;76:285–90.