key: cord-1024691-fiaslrrk authors: Massoullié, Grégoire; Boyer, Baptiste; Sapin, Vincent; Jean, Frédéric; Andronache, Marius; Peoc’h, Michel; Clerfond, Guillaume; Eschalier, Romain title: Sudden cardiac death risk in contact sports increased by myocarditis: a case series date: 2021-03-01 journal: Eur Heart J Case Rep DOI: 10.1093/ehjcr/ytab054 sha: 293b8795f1899b84228dedcab7137deeadb93117 doc_id: 1024691 cord_uid: fiaslrrk BACKGROUND: Myocarditis is a known cause of sudden cardiac death of the athlete. The impact of direct chest trauma in at-risk sports or activities in patients with a history of myocarditis has never been demonstrated or studied. We report herein two cases of life-threatening ventricular arrhythmia secondary to non-penetrating blunt chest trauma while playing contact sports. CASE SUMMARY: The first patient, a 26-year-old man described a brief loss of consciousness after having received blunt impact to the chest (typical intensity) while playing a rugby match. The loss of consciousness was total and proceeded by rapid and regular palpitations. He had a history of viral myocarditis 10 years prior with a fibrotic sequalae in the inferolateral wall on cardiac magnetic resonance imaging (left ventricular ejection fraction 71%). Right apical ventricular pacing induced a sustained monomorphic ventricular tachycardia reproducing the patient’s symptoms. A subcutaneous implantable cardioverter-defibrillator was implanted. The second patient is a 22-year-old professional rugby player with no known notable history. During a match, a direct blow to the chest wall was followed by a cardiac arrest. A ventricular fibrillation was cardioverted to pulseless electrical activity. Patient died despite cardiopulmonary resuscitation. An autopsy identified a myocardial sequela of fibrosis with no acute inflammatory remodelling compatible with a previous myocarditis. DISCUSSION: Myocarditis may increase the risk of life-threatening ventricular arrhythmias caused by blunt impact to the chest, particularly in contact sports. Screening and prevention measures should be considered to reduce this risk. Myocarditis, predominantly in its acute phase but also in its chronic form due to sequelae, is a known cause of sudden cardiac death (SCD) in athletes (5-25%). [1] [2] [3] [4] Symptoms of acute myocarditis are variable: from silent inflammatory response to non-specific viral syndrome, chest pain, dyspnoea, or ventricular arrhythmia and SCD. The condition may be difficult to diagnose; myocarditis can go undiagnosed, in particular, in elite athletes who seem to have an increased risk of viral infection susceptible to viral infections. 5 They cumulate risk factor increasing exposure to pathogen (international events and worldwide travelling) and factors that may impair immune system (sleep deprivation, extreme environment, high intensity exertion, or training). Biological tests (e.g. ultra-sensitive troponin) and cardiac magnetic resonance imaging (MRI) are central to the diagnosis of myocarditis, 5, 6 increasing the number and accuracy of diagnoses, as well as the reliability of a prognosis. However, the long-term risk of life-threatening ventricular arrhythmias (LTVA) is poorly understood. Subsequent events may occur long after the initial episode. 7 Furthermore, the incidence of ventricular arrhythmia during contact sports in patients with a history of myocarditis has not been demonstrated or studied. We report here on two cases of syncope, in one instance followed by SCD, secondary to a non-penetrating blunt chest trauma during sports activity (rugby) in patients with sequelae of myocarditis. Case series Case 1 A 26- year-old man presented brief loss of consciousness while playing a rugby match (semi-professional competitive level). His medical history was marked by a myocarditis 10 years prior based on (i) an elevation of cardiac enzymes along with electrocardiographic changes (diffuse ST-elevation), (ii) presence of coxsackie virus B IgM, and (iii) identification by cardiac MRI (CMR, 1.5 T) of acute myocarditis on a delayed enhancement sequence of epicardial hyperintensity lesions in the inferolateral wall. Following antiinflammatory therapy (aspirin 1000 mg every 8 h for 3 weeks) and during follow-up, the patient reported no symptoms, and an exercise stress test was normal (absence of ischaemia or LTVA). Cardiac MRI performed 11 months after the acute episode revealed a fibrotic scar in the inferolateral wall along with myocardial wall thinning and normal left ventricular ejection fraction (LVEF) (71%). As recommended, 8, 9 sports were contraindicated for 6 months following the acute myocarditis event, after which he was able to resume competitive sports. The patient was followed annually with clinical, electrocardiographic, and trans-thoracic echocardiographic (TTE) assessments. There was no recurrence of myocarditis or cardiac symptoms, and no evidence of arrhythmic events. The patient was not taking any medication. The current syncopal episode occurred after the patient received a tackle with blunt impact (typical intensity) directly on the chest. The loss of consciousness was total and proceeded by rapid and regular palpitations. Return to consciousness was rapid without post-ictal confusion, and no injury was recorded. The patient was evacuated from the field for medical evaluation. He had been describing similar symptoms for several years, exclusively upon direct chest wall impact. Because of this history, the patient was admitted to the hospital emergency unit. Haemodynamics were stable, and the clinical cardiovascular and neurological examination was normal. Laboratory testing revealed moderately elevated troponins Ic at 35 ng/L (high sensitive troponin Ic, normal range 0-14 ng/L) and creatine phosphokinase 381 U/L (normal 20-200 U/L). The 12-lead electrocardiogram revealed a normal QT interval (QTc: 442 ms), a repolarization similar to that previously described (i.e. negative Q waves in the posterior and lateral leads), fragmented QRS in the inferior leads, and left-axis deviation (-70 ) ( Figure 1) . A new CMR (1.5 T) was performed ( Figure 2 ) and found to be superimposable on the previous image, as well as a similar TTE. Prolonged monitoring of the heart rate did not reveal the presence of LTVA, ventricular ectopy, or other arrhythmias. An electrophysiological study was carried out (class IC, level C). 10 Right apical ventricular pacing induced a sustained monomorphic ventricular tachycardia (VT) originating from the left ventricular (LV) lateral wall (212 ms, i.e. 283 b.p.m.) and loss of consciousness, reproducing the patient's on-field symptoms ( Figure 1 ). Return to sinus rhythm was achieved with an antitachycardia pacing burst. This young patient was implanted with a subcutaneous implantable cardioverter-defibrillator (S-ICD) 10 and was treated with betablockers (bisoprolol 2.5 mg o.d.; heart rhythm at discharge: 39 b.p.m.). 6 To reduce the burden of arrhythmic events, a VT ablation with a sub-xyphoidian epicardial approach was performed 1 month later. Critical VT isthmuses were located within the myocardial scar tissue ( Figure 2 ). During follow-up, the patient remained asymptomatic with no VT recurrence recordings in S-ICD follow-up. Considering the rugby practice and the risk of chest blunt trauma, he was dissuaded from competitive-level playing. Due to patient intolerance and the absence of inducible VT after ablation and during stress test, beta-blockers were discontinued. A 21-year-old man, professional rugby player, with no known personal or family history of cardiovascular diseases and LVTA/SCD presenteda cardiac arrest. During a rugby match, he was tackled with a direct blow to the chest wall and lost consciousness temporarily but was able to reach the edge of the field with the help of trainers. In the locker room, the patient suffered several brief losses of consciousness followed by cardiopulmonary arrest. Upon arrival of the medical emergency services, the patient was unconscious and gasping for air. The low-flow period was poorly recognized and deemed to have lasted a few minutes. The electrocardiogram (ECG) recorded by the portable defibrillator ( Figure 3 ) revealed ventricular fibrillation. External cardioversion (one biphasic shock of 300 J) allowed a return to agonal rhythm measured at 35 b.p.m. Haemodynamics remained unstable and despite 47 min of resuscitation, the patient died on site. An autopsy was performed. Histological study of the heart identified epicardial and myocardial sequelae of fibrosis in the anterior interventricular septum extending over the anterior, lateral, and lower aspects of the myocardium with no acute inflammatory remodelling ( Figure 2 ). This lesion was compatible with a sequela of myocarditis, the age of which cannot be determined. There was no coronary lesion or dissection nor valve injury. Left ventricular dimensions and mass were normal for the age and practice of high-level competitive sport. Moreover, in the patient's personal history obtained from his family and general practitioner, no indication of prior myocarditis could be identified. Ten months earlier, a cardiological assessment (ECG and TTE) had not found any signs contraindicating the practice of competitive rugby. This report describes the case of two high-performance athletes suffering a non-penetrating blunt chest trauma associated with the occurrence of LTVA due to a chronic sequela of myocarditis. In contrast to the classically described commotio cordis, these two episodes of ventricular arrhythmias were associated with underlying myocardial scarring. Commotio cordis is a rare phenomenon defined by the occurrence of an LTVA induced by a non-penetrating chest trauma. 11 At sufficient intensity, the shock wave is capable of producing a depolarization of the myocardial cells primarily via the activation of potassium ATP channels. 12 Occurring at the peak of the T wave, i.e. an electrically vulnerable period of cardiac repolarization, this depolarization can induce a sustained ventricular arrhythmia, often difficult to control and recurrent. 13 The phenomenon can be immediate with a rapid and complete loss of consciousness, although $20% of patients are able to continue their activity for a few seconds 13,14 (cf. Case 2). Although very rare, commotio cordis has been described in sports with chest blows (baseball, lacrosse, etc.). 15 Reported cases and series indicate that the phenomenon affects mostly young athletes. The prevalence of commotio cordis appears to be higher in the USA than in Europe (21.6Â higher) due to the more common practice of competitive contact sports among North American youth and also to the absence of a dedicated registry in Europe. 14, 16 A recent review of the literature found only 215 reported cases (160 autopsies performed) of commotio cordis with an estimated incidence of 3-6% of SCD occurring during sporting activity. 17, 18 However, underreporting is a possibility, considering the poor survival rates, the circumstances of occurrence, and the definitions used. The diagnosis is above all one of exclusion, Myocarditis is a cardiac condition most commonly of viral origin. Due to the diversity of its clinical manifestations, it is difficult to assess the incidence in the general population. The occurrence of cardiac arrest appears to increase with exertion and in high-performance athletes. 19 Current consensus dictates that sports activity is contraindicated for the ensuing 3-6 months following an episode of myocarditis. 1, 9 The resumption of training and competitions is authorized on condition of normal LVEF, negative serum biomarker, and absence of arrhythmias on exertion and at rest. Demonstration of persistent abnormal cardiac fibrosis on CMR may be considered as an additional SCD risk factor without justifying additional restrictions. 9 A review of the literature identified a similar case of a soccer player who suffered a cardiac arrest secondary to a direct chest wall trauma and the presence of a sequela of myocarditis. 20 This and the present two cases share similar mechanisms and aetiology. However, the soccer player exhibited mild-biventricular dysfunction and was thus at increased risk of ventricular arrhythmias. To date, myocardial scarring has not been associated with an increased risk of arrhythmia in the event of commotio cordis. The factors associated with arrhythmias include type of mechanical stimulus, stimulus intensity, site of impact, and the timing of the impact in the cardiac cycle (peak of the T wave). Prevention is based on chestprotection equipment and changes in rules of play of at-risk sports without a complete elimination of the risk of blunt chest trauma. Professional athletes may be more exposed than amateurs through repeated training and the intensity of the contacts. However, given the nature of the sport, the occurrence is also frequent in nonprofessional rugby. 21 In both cases presented, chest blows are part of the game and the intensities were not unusual for experienced players. The presence of myocarditis may have promoted both the onset and sustained nature of a ventricular arrhythmia (see Case 2) . Currently, an ECG is required for participation in high-level competitive sports. We believe that certain sports with chest wall impact should require a thorough and systematic cardiological assessment. In the USA as in France, the eligibility assessment for the practice of a high-level sport is not compulsory and depends on each federation. 22 Such evaluation is advisable and encompasses a cardiological assessment with at the very least a clinical examination, an ECG, and a TTE in the event of an abnormality during the previous examinations. Cardiac MRI is not systematic although it would seem advisable to broaden the indication. With regard to amateur athletes practicing a sport with risk of chest blows, the presence of an abnormality on ECG/TTE 9 or a prior cardiovascular history should always lead to a myocardial CMR. For professional athletes practicing such sports, cardiac CMR should be systematically performed. The risk of nonischaemic myocardial injury, such as myocarditis has increased with the COVID-19 pandemic, 23-25 with 7-40% of patients hospitalized or admitted to intensive care unit presenting with virus-related acute myocarditis. 23, 26 The underlying mechanism of injury has not yet been identified and high-quality data are not available. Due to the suspected high prevalence of COVID-19 cardiac injury, a specific screening (serologic test and CMR) should strongly be considered before the start of the 2020/2021 season. The history of our two patients suggests that chest contact sports may share a higher risk of rhythmic complications in cases of myocardial scarring. Using CMR late gadolinium enhancement mapping (LGE), asymptomatic focal myocardial LGE has been identified in up to 30% of athletes and non-athletes. 27 An association with ventricular arrhythmia has not been documented, but subepicardial LV LGE has been associated with ventricular arrhythmias and appears not to be a benign condition. 28 These lesions are typical of postmyocardial scarring but may also be associated with non-ischaemic cardiomyopathies (arrhythmogenic dysplasia). These few data are insufficient to support a recommendation to discontinue competitive sport based on the mere existence of cardiac fibrosis. However, practitioners should be alert to the presence of a ventricular LGE and examine such patients further to determine the aetiology of cardiac lesions and the arrhythmic risk from scars, which will guide recommendations on sports activities. Beyond the somatic assessment, there remains the question of the risk of death or serious trauma in high-level sports. The recent modification to harmful high-tackle rules in World Rugby encouraging a systematic sanction of the referees is aimed at reducing the incidence of whiplash and concussion. 29 It may be insufficient to only penalize 'high tackle' (head and neck) since no impact on the risk of LVTA secondary to chest trauma will be observed. Some federations are currently testing limiting tackles to below the hips in non-professional leagues. The present case descriptions may motivate a reflection on further player protection measures that should not be limited to rugby. In particular, during the current COVID-19 pandemic, more studies in larger populations of professional and amateur athletes should be performed to evaluate the potentially higher risk of LVTA associated with sequelae of myocarditis. Such data would be necessary to guide modifications of the minimal examination tests and athletics rules. The occurrence of chest wall trauma during sports activities is frequent and, under very specific conditions, can be associated with severe ventricular arrhythmia. A sequela of myocarditis increases the risk of lethal ventricular arrhythmias following blunt chest trauma. Further studies and systematic CMR assessments should be performed to evaluate the potentially higher risk of LVTA and the benefit of and an adaptation of the rules, in terms of health and medicoeconomic aspects. Grégoire Massoullié is a electrophysiologist at Clermont-Ferrand University Hospital. He completed his residency in Clermont-Ferrand and his fellowship in arrhythmia management at Bordeaux University Hospital (IHU LIRYC, Pr Haïssaguerre). Supplementary material is available at European Heart Journal -Case Reports online. 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World Rugby Laws-World Rugby's Law Education Web Site We thank Mr Pierre Pothier for the editing of the manuscript.Slide sets: A fully edited slide set detailing this case and suitable for local presentation is available online as Supplementary data. The authors confirm that written consent for submission and publication of this case report including images and associated text has been obtained from the patients or next of kin in line with COPE guidance. Funding: None declared.