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What is Sudden Death in Athletes? Definition of Sudden Death in an Athlete Causes of Sudden Death in Athletes Incidence and Prevalence of Sudden Death in Athletes Distribution of Sudden Death Events in Athletes Proposed Mechanisms of Sudden Death in Athletes Definition of Sudden Death in an Athlete Sudden death has been defined as "an abrupt unexpected death of cardiovascular cause, in which the loss of consciousness occurs within 1 to 12 hours of onset of symptoms" (1, 2). The majority of sudden deaths in athletes occur during or immediately after exercise (game, conditioning, training, etc). However, some deaths occur at rest or during sleep. Autopsy is very useful in making a definitive diagnostic determination of the cause of sudden death. Certain conditions (i.e., Long QT Syndrome, Brugada Syndrome) require detailed postmortem biochemical and sometimes genetic studies. In studies of sudden deaths in athletes, individuals that participated in organized competitive sports, and those that exercised regularly and vigorously and had an active lifestyle including sports, and sometimes physically conditioned military personnel were considered "athletes." Individuals that lead a sedentary lifestyle and exercise infrequently have not routinely been included into the definition of “athlete.” Causes of Sudden Death in Athletes The diseases responsible for sudden deaths on the athletic field have now been identified. For the most part, they include a variety of cardiovascular abnormalities as shown in figure 1. The precise disease responsible for the sudden death differs considerably with regards to age. For example, in young athletes, congenital malformations of the heart and/or vascular system cause the majority of deaths. In contrast, in older athletes who died suddenly, there is usually the evidence of atherosclerotic disease of coronary arteries. Hypertrophic cardiomyopathy (HCM) is a genetic disease which manifests itself by the thickening of the ventricular septum and/or other segments of the left ventricle with or without a partial obstruction to the blood flow out of the left side of the heart. HCM has consistently been the single most common cardiovascular cause of sudden death. HCM is relatively common in the general population (1:500 people) (3). HCM is usually diagnosed by an imaging test (echocardiography or magnetic resonance imaging [MRI]). Electrocardiogram (ECG) is often abnormal in patients with HCM. For a schematic representation of ECG and echocardiographic image of a patient with HCM, click here. HCM is a diverse disease with various representations on the echocardiography. For a series of representations, click here. Congenital coronary anomalies, mostly a wrong origin of the left main coronary artery, are the second most frequent cause of athletic field deaths. These anomalies may be more common than previously regarded (4). For a schematic representation of anomalous coronary origins, click here. These anomalies are usually diagnosed by echocardiography, MRI and/or coronary angiogram. A diverse composition of approximately 15 other diseases of the heart account for the remaining athletic field deaths due to cardiovascular disease. These include rupture of the aneurysm of the aorta as a component of Marfan’s syndrome, arrhythmogenic right ventricular dysplasia/cardiomyopathy, rare anomalies of coronary artery development ("bridging" of a coronary artery, congenital absence of one or more coronary artery, etc), degeneration of the structures of mitral valve (mitral valve prolapse), aortic stenosis, dilated cardiomyopathy, myocarditis, and other pathologies. Each of these is responsible for a minor portion of sudden deaths in athletes, and presents a challenge for a physician to diagnose in the absence of symptoms. Occasionally, athletes that die suddenly do not demonstrate any evidence of structural heart disease on autopsy (5). Such deaths may be associated with the disorders of the conduction system of the heart, such as Wolff-Parkinson-White (WPW) syndrome, Long QT Syndrome, Brugada Syndrome, and arrhythmias related to exertion, such as catecholaminergic polymorphic ventricular tachycardia (CPVT) (5). In other instances, exercise-induced coronary spasm, a heart block or asystole with loss of consciousness (6) may be the cause of death. There are a number of other causes of sudden death in athletes that are not related to cardiovascular disease (7, 8). These are: Exercise-induced asthma and respiratory arrest Exercise-induced anaphylaxis Sarcoidosis Malignant hyperthermia Heat stroke Sickle cell trait Gastrointestinal bleeding Rhabdomyolysis Head trauma Spine trauma (in pole vaulting) Non-penetrating neck blow with rupture of cerebral artery (ice hockey) Several deaths of athletes have been related to drug abuse. Although it is not possible to mention all drugs that have been causally linked with sudden death in athletes, the most important (9) of them are: Ephedrine (Ma-Huang or herba ephedra) Cocaine Amphetamines Anabolic steroids (oxymesterone, methandrostenolone, stanozol, etc) Erythropoetin Alcohol Ergotamine derivatives "Energy" drinks There have been reports of sudden cardiac deaths related to vigorous exercise and starvation, semi-starvation and liquid protein diets (9). It is believed that in those cases, severe weight loss results in a decrease of the skeletal and the heart mass. Accompanying inflammation and also deficiencies in magnesium and potassium may make the myocardium more susceptible to arrhythmias. An increase in sudden death and in QT interval was associated with a liquid protein diet in a recent study (10). However, the rates of sudden death did not increase in a medically supervised weight loss program. Commotio Cordis or Innocent Chest Blow A relatively modest and non-penetrating blow to the chest, in the absence of underlying cardiovascular disease or injury to the chest wall itself may result in sudden cardiac death (5,11,12). On the athletic field, such an event, referred to as Commotio Cordis (which means "disturbed or agitated heart motion"), is produced by an object (i.e., ball) or by bodily collision with another athlete. A common scenario is that of a baseball player struck in the chest while batting by a pitched ball thrown at approximately 40 mph from a distance of 40 feet or farther. Catastrophes similar to this have occurred in a variety of sports (baseball, ice hockey, softball, football, karate, lacrosse, boxing, rugby and soccer), including recreational activities at home and on the playing field. The precise mechanism responsible for the sudden death as the outcome of Commotio Cordis is not known with complete certainty, but a recently developed animal model helped answer several key questions (13). The model showed that a low-energy chest blow, when timed appropriately, creates devastating consequences by triggering ventricular fibrillation. A very narrow window of 15-30 ms prior to the peak on the ascending side of the T-wave on the ECG is a vulnerable phase of repolarization, and when the impact occurs in that interval, or ventricular fibrillation develops instantaneously and reproducibly. When the impact occurs on the QRS complex, transient or complete heart block, ventricular tachycardia develops. Commotio Cordis is not uniformly fatal, and approximately 10% of the victims are known to have survived, usually with prompt cardiopulmonary resuscitation and defibrillation. The Minneapolis Heart Institute Foundation together with US Consumer Product Safety Commission (Dr. Susan B. Kyle, Ph.D.) maintains the US Commotio Cordis Registry. If you have a case of Commotio Cordis that you would like to report to The Registry, please click here. If you know of such a case, or know of a survivor of Commotio Cordis, please click here to send an alert. For recent research in Commotio Cordis, click here. Incidence and Prevalence of Sudden Death in Athletes The precise frequency with which sudden death in athletes occurs remains unresolved. In the past, some authors have suggested that the annual incidence of sudden deaths in young athletes is probably as low as 20 per year (14). These low estimates have placed a major obstacle on putting sudden death in athletes in its proper perspective. The most recent survey of collections of newspaper articles for the year 2000 indicates that the occurrence of these catastrophes is at least 7-10 times higher than previously believed. Estimates range from 1 in 15,000 joggers to 1 in 50,000 marathoners, representing 1 death per 50,000 to 375,000 manhours of exercise (15). There are approximately 10 million joggers in the United States. Therefore, the number of deaths related to jogging could potentially be several hundreds per year. In addition, surveying media may grossly underestimate the true prevalence of this phenomenon, since the recognition of these events is not systematic and mostly accounts for elite or well-known athletes and those in high-visibility sports, as well as events that occur at athletic contests and draw the attention of the community. In contrast, deaths of nonelite athletes in many circumstances are probably less likely to achieve public recognition in the mainstream press and are more likely to escape reporting. To approach estimating the prevalence of these events over several years in a systematic way and to better determine the causes of sudden death in athletes, along with other observations relating to these events, the Minneapolis Heart Institute Foundation, with the support of the sponsors has established The US National Registry of Sudden Death in Athletes. For more on The Registry, click here. Distribution of Sudden Death Events in Athletes Observations of distribution of sudden death in athletes are derived from the article by Barry J. Maron, MD; Jamshid Shirani, MD; Liviu C. Poliac, MD; Robert Mathenge, MD; William C. Roberts, MD; Frederick O. Mueller, PhD entitled "Sudden Death in Young Competitive Athletes" published in the Journal of the American Medical Association in 1996 (JAMA 1996;276:199-204). A total of 158 sudden deaths that occurred in young competitive athletes from 1985 to 1995 was analyzed. The athletes were identified from the news media reports, the National Center for Catastrophic Sports Injury Research Registry, the Cardiovascular Pathology Registry of Baylor University Medical Center, and reports from high school and colleges. In this study, only 15% of the athletes were female. This fact may be explained by lower participation rates of females and/or less intensive demands of training, but could also originate from a lesser recognition of HCM in women (16). You can view the occurrence of sudden cardiac death in athletes by the type of sport, hour of day and month of year. The article by Barry J. Maron, MD; Kevin P. Carney, BS; Harry M. Lever, MD; Jannet F. Lewis, MD; Ivan Barac, MD; Susan A. Casey, RN and Mark Sherrid, MD entitled "Relationship of Race to Sudden Death in Competitive Athletes with Hypertrophic Cardiomyopathy" and published in the Journal of the American College of Cardiology (J Amer Coll Cardiol 2003;41:974-80) reported the relationship of race to the prevalence of cardiovascular disease causing sudden death and compared the findings with a representative multi-center hospital-based cohort of patients with HCM. You can view that information by clicking here. Proposed Mechanisms of Sudden Death in Athletes Exercise in general, and regular short-term exercise in particular, produce a significant increase in heart rate, contractility of the heart and increase cardiac output and oxygen consumption. Numerous research studies showed that regular exercise has multiple health benefits that go beyond increase in fitness (i.e., improvements in lipid profile, weight loss, reduction of insulin resistance and the risk of type 2 diabetes, cardiovascular disease in general, including the risk of myocardial infarction, heart failure, and death caused by cardiovascular disease). The National Institute of Health recommends a goal of 30 minutes of moderate activity every day of the week (17). Regular physical activity has been put forward as one of the critical components of the Healthy People 2010 initiative. However, systemic training in endurance (dynamic, aerobic) or isometric sports (static, power) has been known to increase cardiac mass and dimensions, and trigger structural remodeling in many athletes (18-22). This form of hypertrophy is physiologic and is regarded as an adaptation to systematic athletic training, and therefore was termed "athlete’s heart." The changes include enlargement of left and right ventricles and left atrium; however the function of the heart remains preserved. Physiologic increases in cardiac mass vary in magnitude according to sporting discipline. For example, the most extreme cavity dimensions and/or wall thickness have been reported with rowing, cross-country skiing, cycling and swimming. Weight lifting and wrestling have been associated with abnormal increases in left ventricular wall thickness disproportionate to cavity size. Comparative chart guides the diagnosis between HCM and athlete’s heart. Extreme alterations in cardiac dimensions evident in some athletes have unavoidably raised concern of whether such exercise-related adaptations are truly physiologic, especially when present for the long periods of time. For example, approximately 15 percent of trained athletes have striking left ventricular cavity enlargement. A longitudinal echocardiographic study showed incomplete reversal with substantial residual chamber dilatation on 20 percent retired, deconditioned athletes (21). While firm evidence is presently lacking, one cannot exclude with certainty that such extreme ventricular remodeling due to intense conditioning may have adverse consequences over long time periods (20, 23). In hypertrophic cardiomyopathy, intense training and the strain of competition, which increase physiologic demands on the heart, produce alterations in electrolytes, blood volume and levels of hydration and together increase sympathetic tone and withdrawal of parasympathetic tone. Multiple interactions of those factors with the hypertrophied myocardium and the disarray of myocardial fibers act as triggers for potentially lethal ventricular arrhythmias (24). Also, increased myocardial mass and insufficient regional perfusion during high-intensity exercise cause myocardial ischemia, and over time, replacement fibrosis, both of which may act as independent triggers of arrhythmias. In fact, patients with HCM that survived a sudden death had a very high incidence of inducible ischemia on thallium stress-testing (25). In addition, lack of appropriate blood pressure and heart rate response to exercise may act as the initial event cascading into a hemodynamic collapse with loss of consciousness. Finally, partial obstruction present at rest may increase twice as high with intense physical exercise compared to levels at baseline (26), which can potentially result in myocardial ischemia, hemodynamic compromise and arrhythmias. Autopsy, histological and microscopic studies, and sometimes biochemical tests establish a post-mortem diagnosis of HCM. To see a representational sample of a gross heart specimen and histological studies, click here. In congenital anomalies, each variation of normal anatomy may have its specific mechanism of induction of hemodynamic compromise and/or lethal arrhythmias. There are several common mechanisms. For example, in coronary anomalies, either the expansion of the aorta or pulmonary arteries from the increased stroke volume changes the take-off angle of the artery and, as a consequence, the artery may become compressed (2,22,27). The compression of the arterial lumen may only be present at vigorous exercise. Anatomic variance known as “bridging” has largely similar mechanics, except the exact location is more distal in the vessel but not at the origin. The events in the myocardium responsible for sudden death in these pathologies are rather complex. However, myocardial ischemia, especially if it occurs repeatedly, is believed to play a major role (2,22,27). Absence of a coronary artery results in decreased perfusion of the myocardium and prolonged episodes of acute ischemia, which are sufficient enough to trigger ventricular fibrillation. Sudden death in Marfan’s syndrome most commonly arises as a result of complications of the disease, such as rupture of the ascending aorta. In arrhythmogenic right ventricular cardiomyopathy, CPVT and selective cases of MVP, although heterogeneous from the standpoint of molecular pathophysiology, electrical instability of the myocardium at peak exercise may induce ventricular fibrillation and then sudden death. WPW, Brugada and Long QT syndromes may be responsible for sudden death with or without exercise. For example, in WPW syndrome, the most frequent complication is rapid atrial fibrillation with a rapid ventricular response, which may lead to cardiac arrest. Ventricular tachycardia and fibrillation may be easily inducible in individuals with Brugada syndrome, especially under the influence of elevated body temperature, cocaine and some other illicit drugs (28). Long QT syndromes resulted in sudden death, which related to exercise, although forms that were linked to emotional stress, and also unrelated to either have been reported (29). Myocarditis is associated with inflammatory infiltration of the myocardium, and sometimes with systemic inflammation. Illicit drug use is sometimes associated with myocarditis. Dilated cardiomyopathy with reduced cardiac function can result from myocarditis. With either myocarditis or dilated cardiomyopathy, small vessel ischemia resulting from decreased regional perfusion may be an excellent substrate for ventricular arrhythmias which can cause sudden death. Exercise can induce coronary vasospasm, which can cause acute coronary syndrome with subsequent arrhythmias leading to hemodynamic collapse and sudden death, all unfolding in a matter of minutes. As the artery dilates with exercise, some segments that have atherosclerotic plaque rupture under high sheer stress and coronary occlusion develops secondary to platelet aggregation. In some individuals exhibiting a particularly augmented blood pressure response to exercise, platelets may hyper-aggregate in response to increased circulating norepinephrine. The result of a coronary occlusion is acute myocardial ischemia, which then may serve as a substrate for a lethal arrhythmia. Sudden deaths in athletes that are linked to acute coronary syndrome in presence of coronary artery disease occur mostly in older (over the age of 35) athletes and rarely happen in individuals younger than 30 years of age. The scenario of a sudden death related to coronary artery disease and/or coronary spasm is especially real in men over 45 years of age with concomitant hypertension and obesity that subject themselves to episodic high-intensity exercise and do not participate in regular, medically supervised exercise programs. However, recent associations of cocaine use and acute coronary syndrome (30) steer towards recognition of coronary complications of illicit drugs in younger individuals. Abnormalities of the conduction system, which include fibrosis and fatty infiltration within very small regions of the myocardium or reside in the pericardium may be responsible for various heart blocks and bradyarrhythmias, which occasionally may result in cardiac arrest, collapse, loss of consciousness and death. Changes that trigger sudden death related to drug abuse are in most cases specific to the class of drugs involved. However, most commonly, increase in heart rate, blood pressure, contractility and oxygen demand, together with induced prolongation of the QT interval and interference with repolarization, have the ability to trigger ventricular tachycardia or Torsades de Pointes transforming into ventricular fibrillation. Such a scenario holds true for abuse of ephedrine, cocaine, amphetamine- and cannabinoid- derivatives and “energy” drinks. Acute coronary syndrome (see above) has also been associated with cocaine and anabolic steroid use, although the former is more predominant than the latter. Anabolic steroids have been reported to increase myocardial mass and induce hypertension, probably secondary to mineralocorticoid effect. In addition, hyperaggregation of platelets and subsequent thrombosis were described (31-33). The mechanisms associated with dieting combined with prolonged exertion resulting in sudden death are not completely understood at the present time. Deficiency of magnesium, potassium and copper that occur with weight loss may result in the electrical instability of the myocardium (34). In addition, rapid weight loss may cause a loss of ATPase and development of insulin resistance (35), which could make the myocardium more sensitive to norepinephrine. This information may be important for the athletes that are engaging in weight loss combined with prolonged physical training and consumption of performance-enhancing supplements. New research is now underway that is addressing distinct molecular mechanisms of sudden death in HCM, arrhythmogenic right ventricular cardiomyopathy, CPVT and heart failure with preliminary data showing that in each distinct pathology there may be a separate mutation or the cluster of cellular abnormalities that may be responsible for the eventual sudden death (36,37,38). References: 1. Myerburg RJ, Castellanos A. Cardiac arrest and sudden cardiac death. In: Braunwald E, Ed: Heart Disease: A Textbook of Cardiovascular Medicine, 4th edition. Philadelphia, PA, WB Saunders Co; 1992:756-789. 2. Maron BJ, Roberts WC, McAllister HA, et al. Sudden death in young athletes. Circulation 1980;62:218-229. 3. Maron BJ. Hypertrophic cardiomyopathy: a systematic review. JAMA 2002;287;1308-1320. 4. Davis JA, Cecchi F, Jones TK, Portman MA. Major coronary artery anomalies in a pediatric population: incidence and clinical importance. J Am Coll Cardiol 2001;37:593-597. 5. Maron BJ. Sudden cardiac death in young athletes: epidemiology, screening and prevention. In: Aliot E, Clemety J, Prystowsky EN, eds. Fighting Sudden Cardiac Death: A Worldwide Challenge. Futura, Armonk, NY, 2000;211-237. 6. Hirata T, Yano K, Okui T, et al. Asystole with syncope following strenuous exercise in a man without organic heart disease. Ann Intern Med 1987;106:280-283. 7. Maron BJ, Shirani J, Poliac LC, et al. Sudden death in young competitive athletes: clinical, demographic and pathological profiles. JAMA 1996;276:199-204. 8. Katcher MS, Salem DN, Wang PJ, Estes III NAM. Mechanisms of sudden cardiac death in the athlete. In: Estes III NAM, Salem DN, Wang PJ, eds. Sudden Cardiac Death in the Athlete. Futura, Armonk, NY, 1998;3-24. 9. Kloner RA. Illicit drug use in the athlete as a contributor to cardiac events. In: Estes III NAM, Salem DN, Wang PJ, eds. Sudden Cardiac Death in the Athlete. Futura, Armonk, NY, 1998; 441-452. 10. Surawics B, Waller BF. The enigma of sudden cardiac death related to dieting. Can J Cardiol 1995;11:228-231. 11. Maron BJ, Poliac L, Kaplan JA, et al. Blunt impact to the chest leading to sudden death from cardiac arrest during sports activities. N Engl J Med 1995;333:337-342. 12. Maron BJ, Link MS, Wang PJ, et al. Clinical profile of commotio cordis: an underappreciated cause of sudden death in the young during sports and other activities. J Cardiovasc Electrophysiol 1999;10:114-120. 13. Link MS, Wang PJ, VanderBrink BA, et al. Selective activation of tke K-ATP is a mechanism by which sudden death is produced by low energy chest wall impact (commotio cordis). Circulation 1999;100:413-418. 14. Van Camp SP, Bloor CM, Mueller FO, et al. Nontraumatic sports deaths in high school and college athletes. Med Sci Sports Exerc 1995;27:641-647. 15. Willich SN, Maclure M, Mittleman M, et al. Sudden cardiac death: support for a role of triggering in causation. Circulation. 1993;87:1442-1450. 16. Maron BJ, Bonow RO, Cannon RO III, Leon MB, Epstein SE. Hypertrophic cardiomyopathy: interrelations of clinical manifestations, pathophysiology, and therapy. N Engl J Med 1987;316:780789, 844-852. 17. NIH consensus development panel on physical activity and cardiovascular health. Physical activity and cardiovascular health. JAMA 1996;276:241-246. 18. Pelliccia A, Maron BJ, Spataro A, et al. The upper limit of physiologic cardiac hypertrophy in highly trained elite athletes. N Engl J Med 1991;324:295-301. 19. Sharhag J, Schneider G, Urhausen A, et al. Athlete’s heart: Right and left ventricular mass and function in male endurance athletes and untrained individuals determined by magnetic resonance imaging. J Am Coll Cardiol 2002;40:1856-63. 20. Pelliccia A, Maron BJ, de Luca R, et al. Remodeling of left ventricular hypertrophy in elite athletes after long-term deconditioning. Circulation 2002;105:944-49. 21. Pelliccia A, Maron BJ, Culaso F, et al. Clinical significance of abnormal electrocardiographic patterns in trained athletes. Circulation 2000;102:278-84. 22. Maron BJ. Sudden death in young athletes. N Engl J Med 2003 (?). 23. Estes III NAM, Link MS, Cannom D, et al. Report of the NASPE Policy Conference on Arrhythmias and the Athlete. J Cardiovasc Electrophysiol 2001;12:1208-19. 24. Maron BJ. Hypertrophic cardiomyopathy as a cause of sudden death in the young competitive athlete. In: Estes III NAM, Salem DN, Wang PJ, eds. Sudden Cardiac Death in the Athlete. Futura, Armonk, NY, 1998;301-317. 25. Dilsizian V, Bonow RO, Epstein SE, et al. Myocardial ischemia detected by thallium scintigraphy is frequently related to cardiac arrest and syncope in young patients with hypertrophic cardiomyopathy, J Am Coll Cardiol 1993;22:796-804. 26. Schwammenthal E, Schwartzkopff B, Block M, et al. Doppler echocardiographic assessment of the pressure gradient during bicycle ergometry in hypertrophic cardiomyopathy. Am J Cardiol 1992;62:1623-28. 27. Maron BJ, Epstein SE, Roberts WC. Causes of sudden death in competitive athletes. J Am Coll Cardiol 1986;7:204-214. 28. Antzelevitch C, Brugada P, Brugada J, et al. Brugada syndrome: 1992-2002. J Am Coll Cardiol 2003;41:1665-71. 29. Meyer JS, Mehdirad A, Salem BI, et al. Sudden arrhythmia death syndrome: importance of the long QT syndrome. Am Fam Physician. 2003;68:483-8. 30. Lange RA. Cocaine and myocardial infarctions. Adv Stud Med 2003;3:448-54. 31. Huie MJ. An acute myocardial infarction occurring in an anabolic steroid user. Med Sci Sports Exerc 1994;26:408-13. 32. Dickerman RD, Schaller F, Prather I, et al. Sudden cardiac death in a 20-year old bodybuilder using anabolic steroids. Cardiology 1995;86:172-73. 33. Ferenchick G, Hirokawa S, Mammen EF, et al. Anabolic-androgenic steroid abuse and platelet aggregation in weight-lifters: evidence for activation of the hemostatis system. Am J Hematol 1995;49:282-88. 34. Drott C, Lundholm K. Cardiac effects of caloric restriction-mechanisms and potential hazards. Int J Obes Relat Metan Disord 1992;16:481-86. 35. Fisler JS. Cardiac effects of starvation and semi-starvation diets: safety and mechanisms of action. Lakartidningen 1995;9:3411. 36. Allen PD. Not all sudden death is the same. Circ Res 2003;93:484-486. 37. George CH, Higgs GV, Lai AF. Ryanodine receptor mutations associated with stress-induced ventricular tachycardia mediate increased calcium release in stimulated cardiomyocytes. Circ Res 203;93:531-40. 38. Seidman C. Genetic causes of inherited cardiac hypertrophy. Robert L Frye Lecture. Mayo Clin Proc 2002;77:1315-19.