The molecular autopsy: an indispensable step following sudden cardiac death in the young?

Annually thousands of sudden deaths involving young individuals (<?35?years of age) remain unexplained following a complete medicolegal investigation that includes an autopsy. In fact, epidemiological studies have estimated that over half of sudden deaths involving previously healthy young individuals have no morphological abnormalities identifiable at autopsy. Cardiac channelopathies associated with structurally normal hearts such as long QT syndrome (LQTS), catecholaminergic polymorphic ventricular tachycardia (CPVT), and Brugada syndrome (BrS), leave no evidence to be found at autopsy, leaving investigators to only speculate that a lethal arrhythmia might lie at the heart of a sudden unexplained death (SUD). In cases of autopsy-negative SUD, continued investigation, through the use of a cardiological and genetic evaluation of first- or second-degree relatives and/or a molecular autopsy, may pinpoint the underlying mechanism attributing to the sudden death and allow for the identification of living family members with the pathogenic substrate that renders them vulnerable to an increased risk for cardiac events, including sudden death.     

Postmortem long QT syndrome genetic testing for sudden unexplained death in the young.

OBJECTIVES: This study sought to determine the spectrum and prevalence of long QT syndrome (LQTS)-associated mutations in a large cohort of autopsy-negative sudden unexplained death (SUD). BACKGROUND: Potentially heritable arrhythmia syndromes may explain a significant proportion of SUD in the young. Here, comprehensive postmortem LQTS genetic testing was performed in a cohort of SUD cases. METHODS: From September 1998 to March 2004, 49 cases of SUD (30 male patients, average age at death 14.2 +/- 10.9 years) were referred by medical examiners/coroners to Mayo Clinic's Sudden Death Genomics Laboratory. Using polymerase chain reaction, denaturing high-performance liquid chromatography, and direct DNA sequencing, open reading frame/splice site mutational analysis was conducted for all 8 genes implicated in the pathogenesis of either LQTS (LQT1 to LQT6) or multisystem disorders involving either QT or QU prolongation. RESULTS: Ten LQTS-associated mutations (4 novel) were discovered in 10 SUD cases (20%, 8 female patients, average age at death 18.0 +/- 11.8 years). The LQTS susceptibility mutations LQT1 (5), LQT2 (3), and LQT3 (2) were far more common among women (8 of 18, 44%) than men (2 of 30, 6.7%, p < 0.008). The activities at the time of SUD included sleep (5), exertion (2), auditory arousal (1), and undetermined (2). Sudden death was the sentinel event in two-thirds of the cases. CONCLUSIONS: In this cardiac channel-focused molecular autopsy investigation of SUD, over one-third of decedents harbored a putative cardiac channel mutation: 7 previously reported to host mutations in the RyR2-encoded calcium release channel and now 10 with LQTS susceptibility mutations. Accordingly, postmortem cardiac channel genetic testing should be pursued in the evaluation of autopsy-negative SUD.     

Sudden infant death syndrome: how significant are the cardiac channelopathies?

Having an apparently healthy, thriving infant fail to reach his/her first birthday is profoundly tragic. This tragedy is compounded when the infant's death is unexpected and unexplained, signed out as sudden infant death syndrome (SIDS). Despite impressive success and welcome reductions in these tragic deaths due in large measure to "Back-to-Sleep" campaigns, the fundamental pathogenic mechanisms precipitating such deaths remain dimly exposed. Here, we review the causal link between SIDS and mutations involving the SCN5A-encoded cardiac sodium channel, provide new findings following extensive postmortem genetic testing of long QT syndrome (LQTS)-associated potassium channel genes in a population-based cohort of SIDS, and summarize the current understanding regarding the spectrum and prevalence of cardiac channelopathies in the pathogenesis of SIDS.     

Genetic testing for risk stratification in hypertrophic cardiomyopathy and long QT syndrome: fact or fiction?

PURPOSE OF REVIEW: Hypertrophic cardiomyopathy, affecting 1 in 500 persons, is the most common identifiable cause of sudden cardiac death in the young, whereas congenital long QT syndrome, affecting 1 in 5000 persons, is perhaps one of the most common causes of autopsy negative sudden unexplained death. Since May 2004, genetic testing has been available as a clinical diagnostic test for both hypertrophic cardiomyopathy and long QT syndrome. It is now critical to carefully scrutinize the relationships between genotype and phenotype as they pertain to clinical practice. RECENT FINDINGS: In 1990, the molecular underpinnings of hypertrophic cardiomyopathy were exposed with the identification of a mutation in the MYH7-encoded beta myosin heavy chain. Since then, hundreds of mutations scattered among at least 14 genes confer the pathogenetic substrate for this 'disease of the sarcomere'. In 1995, the discipline of cardiac channelopathies was born with the revelation that mutations in critical cardiac channel genes cause long QT syndrome. Today, hundreds of mutations involving several cardiac channel genes account for approximately 75% of long QT syndrome. Over the past decade, scores of genotype-phenotype correlation studies in both hypertrophic cardiomyopathy and long QT syndrome have been conducted. SUMMARY: Genomic medicine has now entered the clinical practice as it pertains to the evaluation and management of both hypertrophic cardiomyopathy and long QT syndrome. The diagnostic utility of genetic testing for both diseases is clearly evident, as well as current limitations. While treatment decisions are certainly influenced by knowing the underlying genotype in long QT syndrome, there seems to be negligible prognostic value associated with particular hypertrophic cardiomyopathy-causing mutations at this time.     

A review of sudden unexpected death in the young in British Columbia

BACKGROUND:

Since 2008, all pediatric deaths in British Columbia have been reported to the coroner. The cause of death in pediatric sudden unexpected death (SUD) remains undetermined in 10% to 30% of cases. Before 2008, there was no standardized approach for referring relatives of SUD victims for follow-up medical testing to determine whether they were affected by the same condition. In the current era, genetic testing for primary electrical diseases can be used in cases of undetermined SUD when existing diagnostic methods fail.

OBJECTIVE:

To improve the clinical care of surviving relatives of SUD victims, the current practice of assessment of SUD in British Columbia was reviewed. The study also aimed to determine the prevalence of SUD and sudden cardiac death, types of postmortem investigations performed in SUD, and the use of genetic testing for primary electrical diseases in SUD from 2005 to 2007.

METHODS:

Cases involving individuals zero to 35 years of age, with a death due to natural disease or an undetermined cause were compiled from the British Columbia Coroners Service database. Cases were determined to be either sudden death due to a previously diagnosed condition or SUD.

RESULTS:

In individuals zero to 35 years of age, the prevalence of SUD was 9.21 per 100,000 and the prevalence of sudden cardiac death was 5.26 per 100,000. There were 35 cases of SUD in which a cause of death was unidentified after autopsy (autopsy-negative SUD). Specimens were collected, and specialists were consulted in 86% of these cases in the pediatric population and 14% in the adult population. A suggestion was made to relatives to seek medical attention in 26% of the autopsy-negative SUDs, and molecular autopsy was discussed in 9% of cases but performed in none.

CONCLUSION:

Currently, SUD in British Columbia is not managed in a way that optimizes a timely diagnosis for surviving relatives. A standardized protocol for SUD is needed to ensure optimization of diagnosis, genetic testing and referral of surviving relatives.     

Cardiac genetic investigation of young sudden unexplained death and resuscitated out of hospital cardiac arrest

Nearly 30% of young sudden deaths have negative autopsies and these sudden unexplained deaths (SUDs) are presumed to be due to heritable cardiac arrhythmias attributed to cardiac ion channel disorders. Comprehensive cardiac and genetic testing of families of SUD is helpful in the detection of inherited cardiac genetic conditions. It frequently provides a clue to the cause of death in SUD victims and allows early diagnosis and opportunities to prevent SUD in other family members. Out of Hospital Cardiac Arrest (OHCA) victims and their families also require similar assessment, although the role of genetic testing in this group should be reserved to patients where a clinical diagnosis is established. A team approach with multidisciplinary specialised clinics and increased access to genetic analysis is very helpful in achieving these goals.     

Postmortem molecular screening for cardiac ryanodine receptor type 2 mutations in sudden unexplained death: R420W mutated case with characteristics of status thymico-lymphatics.

BACKGROUND: Mutations of the cardiac ryanodine receptor type 2 (RyR2) gene are known to cause effort-induced polymorphic ventricular arrhythmia, syncope and sudden death. METHODS AND RESULTS: The possible mutations in the RyR2 gene were examined in 18 autopsy cases of sudden unexplained death (SUD). Two cases were found to have the heterozygous missense mutation in exon 14 (nucleotide change C1258T, coding effect R420W). Both cases showed mild fatty infiltration of the right ventricular apex. Interestingly, 1 case showed an enlarged thymus with accompanying hypertrophy of the tonsils and mesenteric lymph nodes. In addition, a narrowing of the aorta was observed in this case. These phenotypic characteristics are consistent with status thymico-lymphaticus, which combines sudden death with an enlargement of lymphoid organs and hypoplasia of the cardiovascular system. The second case also displayed some characteristics of status thymico-lymphaticus. CONCLUSION: The R420W mutation has already been reported in families with juvenile sudden death and may be causative of sudden death in our cases. Postmortem molecular screening of the RyR2 gene could be useful for investigation for cause of death in SUD. The possible association of the RyR2 mutation with status thymico-lymphaticus is discussed.     

Postmortem molecular analysis of KCNQ1 and SCN5A genes in sudden unexplained death in young Australians

The cause of sudden death in young people remains unknown in up to 50% of postmortem cases. Mutations in the ion channel genes are known to cause primary arrhythmogenic disorders such as long QT and Brugada syndromes, which can present with sudden cardiac death and a negative autopsy. In this study, 59 sudden unexplained deaths occurring in Australians aged 相似文献   

Cardiac ion channel mutations in the sudden infant death syndrome

Sudden infant death syndrome (SIDS) is characterized by the sudden death of an infant that occurs during sleep and remains unexplained despite thorough examination. In addition to clinical associations such as prone sleeping and exposure to cigarette smoke, several genetic factors have been identified with regard to SIDS, including autonomic disorders, immunologic polymorphisms and metabolic disorders. In the past decade, postmortem genetic analysis (‘molecular autopsy’) of SIDS cases has revealed a number of cardiac ion channel mutations that are associated with arrhythmia syndromes, including the long QT syndrome, Brugada syndrome and short QT syndrome. Mutations have been found in genes encoding (subunits of) cardiac potassium, sodium and calcium channels, as well as in genes involved in the trafficking or regulation of these channels. Here, we review the literature on cardiac ion channel mutations in relation to SIDS. Combining data from population-based cohort studies, we conclude that at least one out of five SIDS victims carries a mutation in a cardiac ion channel-related gene and that the majority of these mutations are of a known malignant phenotype. Genetic analysis is therefore recommended in cases of sudden infant death. More research is required to further elucidate the pathophysiology of SIDS and to determine whether genetic or electrocardiographic screening of apparently healthy infants should be pursued.     

Postmortem molecular screening in unexplained sudden death

OBJECTIVES: We examined the prevalence of defects in arrhythmia-related candidate genes among patients with unexplained sudden cardiac death (SCD). BACKGROUND: Patients with unexplained sudden death may constitute up to 5% of overall SCD cases. For such patients, systematic postmortem genetic analysis of archived tissue, using a candidate gene approach, may identify etiologies of SCD. METHODS: We performed analysis of KCNQ1 (KVLQT1), KCNH2 (HERG), SCN5A, KCNE1, and KCNE2 defects in a subgroup of 12 adult subjects with unexplained sudden death, derived from a 13-year, 270-patient autopsy series of SCD. Archived, paraffin-embedded myocardial tissue blocks obtained at the original postmortem examination were the source of deoxyribonucleic acid for genetic analysis. RESULTS: Two patients were found to have the same HERG defect, a missense mutation in exon 7 (nucleotide change G1681A, coding effect A561T). The mutation was heterozygous in Patient 1, but Patient 2 appeared to be homozygous for the defect. Patch-clamp recordings showed that the A561T mutant channel expressed in human embryonic kidney cells failed to generate HERG current. Western blot analysis implicated a trafficking defect in the protein, resulting in loss of post-translational processing from the immature to the mature form of HERG. No mutations were detected among the remaining four candidate genes. CONCLUSIONS: In this autopsy series, only 2 of 12 patients with unexplained sudden death were observed to have a defect in HERG among five candidate genes tested. It is likely that elucidation of SCD mechanisms in such patients will await the discovery of multiple, novel arrhythmia-causing gene defects.     

Ankyrins and human disease: what the electrophysiologist should know

The coordinate activity of ion channels and transporters in cardiac muscle is critical for normal excitation-contraction coupling and cardiac rhythm. In the past decade, human gene variants, which alter ion channel biophysical properties, have been linked with fatal cardiac arrhythmias. Ankyrins are a family of "adaptor" proteins, which play critical roles in the proper expression and membrane localization of ion channels and transporters in excitable and nonexcitable cells. Recent findings demonstrate a new paradigm for human cardiac arrhythmia based not on gene mutations that affect channel biophysical properties, but instead on mutations that affect ion channel/transporter localization at excitable membranes in heart. Human ANK2 mutations are associated with "ankyrin-B syndrome" (an atypical arrhythmia syndrome with risk of sudden cardiac death). Human gene mutations, which affect ankyrin-G-based pathways for voltage-gated Na_v channel localization, are associated with Brugada syndrome, a second potentially fatal arrhythmia. Together, these data demonstrate the importance of the molecular events involved in the cellular organization of membrane domains in excitable cells. Moreover, these data define an exciting new field of cardiac "channelopathies" due to defects in proper channel targeting/localization.     

Arrhythmogenic hereditary syndromes: Brugada Syndrome, long QT syndrome, short QT syndrome and CPVT

In approximately 10-20% of all sudden deaths no structural cardiac abnormalities can be identified. Important potential causes of sudden cardiac deaths in the absence of heart disease are primary electrical diseases such as Brugada syndrome, long QT syndrome (LQTS), short QT syndrome and catecholaminergic polymorphic ventricular tachyarrhythmias. Each of these cardiac channelopathies is charaterized by unique genetic and clinical features. The resting ECG and the ECG under exercise are pivotal for the diagnosis of ion channel diseases. Molecular genetic screening can reveal underlying mutations in a variable degree among the cardiac ion channel diseases in up to 70% (LQTS) and may identify individuals with incomplete penetration of the disease. In patients with primary electrical diseases specific clinical triggers for arrhythmic events such as syncope or sudden cardiac death have been identified including exercise, strenuous activity, auditory stimuli or increased vagal tone. The significance of programmed ventricular stimulation is at present unclear concerning risk stratification in patients with Brugada syndrome and short QT syndrome and of no significance in long QT syndrome and catecholaminergic polymorphic ventricular tachycardias. The success of medical therapy remains modest for prevention of sudden cardiac death and may necessitate the insertion of an implantable cardioverter. However, side effects with inappropriate therapies in this patient group with often young and active individuals have to be encountered. More insights into the arrhythmogenesis is critical for future development of effective medical treatment strategies.     

The implications of genetic mutations in the sodium channel gene (SCN5A).

Mutations in sodium channel alpha-subunit gene (SCN5A) result in multiple arrhythmic syndromes, including long QT3 (LQT3), Brugada syndrome (BS), an inherited cardiac conduction defect, sudden unexpected nocturnal death syndrome (SUNDS) and sudden infant death syndrome (SIDS), constituting a spectrum of disease entities termed Na+ channelopathies. These diseases are allelic disorders, if not the same disease with variable penetrance and variable modifiers worldwide. Interestingly, death occurs during sleep in all of these disorders, suggesting a common mechanism. To date, mutational analyses have revealed about 103 distinct mutations in SCN5A, of which at least more than 30 mutations are associated with LQT3, whereas the rest of the mutations are affiliated with the remaining sodium channel disorders. The majority of these mutations are missense. However, other types such as deletions, insertions, frameshifts, nonsense and splice-donor errors have also been reported.     

Heart-brain interactions in cardiac arrhythmia

This review examines current knowledge of the effects of higher brain centres and autonomic control loops on the heart with particular relevance to arrhythmogenesis. There is now substantial evidence that higher brain function (cortex), the brain stem and autonomic nerves affect cardiac electrophysiology and arrhythmia, and that these may function as an interactive system. The roles of mental stress and emotion in arrhythmogenesis and sudden cardiac death are no longer confined to the realms of anecdote. Advances in molecular cardiology have identified cardiac cellular ion channel mutations conferring vulnerability to arrhythmic death at the myocardial level. Indeed, specific channelopathies such as long QT syndrome and Brugada syndrome are selectively sensitive to either sympathetic or vagal stimulation. There is increasing evidence that afferent feedback from the heart to the higher centres may affect efferent input to the heart and modulate the cardiac electrophysiology. The new era of functional neuroimaging has identified the central neural circuitry in this brain-heart axis. Since precipitants of sudden fatal arrhythmia are frequently environmental and behavioural, central pathways translating stress into autonomic effects on the heart might be considered as therapeutic targets. These brain-heart interactions help explain the apparent randomness of sudden cardiac events and provide new insights into future novel therapies to prevent sudden death.     

Multi-phase post-mortem CT-angiography: a pathologic correlation study on cardiovascular sudden death

Multi-phase post-mortem CT-angiography (MPMCTA) has the great potential to increase the quality of the post-mortem investigation, especially in the area of sudden death; however, its role as routine complement to the pathology toolbox is still questioned as it needs to be further standardized. The aim of this study is to investigate the contribution of MPMCTA in cases of sudden unexplained death in adults and in particular in sudden cardiovascular death. Sixty-eight sudden unexpected deaths of adults were investigated at our institution between 2012 and 2013. Ten cases underwent MPMCTA and autopsy and were included in the study. Before the angiographic step by complete filling of the vascular system, prior to any manipulation of the body, a non-contrast CT-scan was carried out. Image reconstructions were performed on a CT workstation (Vitrea) and two radiologists experienced with post mortem imaging interpreted the MPMCTA findings. In all 10 cases, we could state a good correlation between combination of post-mortem CT and MPMCTA and autopsy procedures, confirming a high diagnostic sensitivity. With this case series we want to illustrate the advantages offered by performing MPMCTA when facing a sudden death, regardless of specific suspicion for acute coronary syndrome or other vascular or ischemic disease.     

Sudden death in the young

BACKGROUND: Sudden death is rare in young people, but it has a disproportionate impact on the community. OBJECTIVES: The purpose of this study was to determine the causes of sudden, natural death in persons aged 5-35 years. METHODS: All autopsies conducted at a forensic medicine facility in the years 1995-2004 (inclusive) were reviewed. This facility serves more than 2.5 million people in the eastern part of Sydney, Australia. Data collected included subject age, height, weight, gender, circumstances of death, and pathologic findings at autopsy. Deaths caused by trauma, accidental causes, drowning, and drug toxicity were excluded from analysis. RESULTS: There were 427 nontraumatic, sudden deaths in the 10-year period (70.7% male). Cardiac causes accounted for 56.4%, noncardiac causes 39.3%, and undetermined cause 4.3%. The most common cardiac cause of sudden death was presumed arrhythmia in those with no or minimal structural heart disease (29.0%). Other cardiac causes were acute myocardial infarction (24.5%), myocarditis (11.6%), hypertrophic cardiomyopathy (5.8%), aortic dissection (5.4%), and dilated cardiomyopathy (5.4%). More than two thirds of deaths caused by acute myocardial infarction occurred in the age group from 30-35 years. Sudden cardiac death occurred during physical activity in 10.8% of cases. Sudden cardiac death was reported in a first-degree relative in 4.5% of decedents. The most common noncardiac causes of sudden death were epilepsy (23.8%), intracerebral hemorrhage (23.8%), asthma (16.1%), and pulmonary embolism (12.5%). CONCLUSION: Presumed cardiac arrhythmia is the most common cause of sudden, natural death in the young. There was no reported history of sudden death among the relatives of most decedents.     

J wave syndromes: What's new?

Among the inherited ion channelopathies associated with potentially life-threatening ventricular arrhythmia syndromes in nominally structurally normal hearts are the J wave syndromes, which include the Brugada (BrS) and early repolarization (ERS) syndromes. These ion channelopathies are responsible for sudden cardiac death (SCD), most often in young adults in the third and fourth decade of life. Our principal goal in this review is to briefly outline the clinical characteristics, as well as the molecular, ionic, cellular, and genetic mechanisms underlying these primary electrical diseases that have challenged the cardiology community over the past two decades. In addition, we discuss our recently developed whole-heart experimental model of BrS, providing compelling evidence in support of the repolarization hypothesis for the BrS phenotype as well as novel findings demonstrating that voltage-gated sodium and transient outward current channels can modulate each other's function via trafficking and gating mechanisms with implications for improved understanding of the genetics of both cardiac and neuronal syndromes.     

De novo mutations in childhood cases of sudden unexplained death that disrupt intracellular Ca2+ regulation

Sudden unexplained death in childhood (SUDC) is an understudied problem. Whole-exome sequence data from 124 “trios” (decedent child, living parents) was used to test for excessive de novo mutations (DNMs) in genes involved in cardiac arrhythmias, epilepsy, and other disorders. Among decedents, nonsynonymous DNMs were enriched in genes associated with cardiac and seizure disorders relative to controls (odds ratio = 9.76, P = 2.15 × 10⁻⁴). We also found evidence for overtransmission of loss-of-function (LoF) or previously reported pathogenic variants in these same genes from heterozygous carrier parents (11 of 14 transmitted, P = 0.03). We identified a total of 11 SUDC proband genotypes (7 de novo, 1 transmitted parental mosaic, 2 transmitted parental heterozygous, and 1 compound heterozygous) as pathogenic and likely contributory to death, a genetic finding in 8.9% of our cohort. Two genes had recurrent missense DNMs, RYR2 and CACNA1C. Both RYR2 mutations are pathogenic (P = 1.7 × 10⁻⁷) and were previously studied in mouse models. Both CACNA1C mutations lie within a 104-nt exon (P = 1.0 × 10⁻⁷) and result in slowed L-type calcium channel inactivation and lower current density. In total, six pathogenic DNMs can alter calcium-related regulation of cardiomyocyte and neuronal excitability at a submembrane junction, suggesting a pathway conferring susceptibility to sudden death. There was a trend for excess LoF mutations in LoF intolerant genes, where ≥1 nonhealthy sample in denovo-db has a similar variant (odds ratio = 6.73, P = 0.02); additional uncharacterized genetic causes of sudden death in children might be discovered with larger cohorts.

Sudden unexplained death affects all ages and socioeconomic groups. Prevention focuses on reducing environmental causes (e.g., unsafe sleep environment in infants), treating medical conditions (e.g., sleep apnea) and identifying high-risk individuals (e.g., young athletes with exertional syncope). When medical record review, death scene investigation, autopsy, and toxicology provide no definite cause of death, decedent DNA sequencing may identify pathogenic variants that confer susceptibility for lethal ventricular arrhythmias (1, 2). Sudden cardiac death series in children and young adults with unrevealing autopsies found pathogenic cardiac gene variants in 25% of cases (1, 3). By contrast, among children ages 1 to 10 y who died in sleep—most sudden unexplained deaths in childhood (SUDC)—pathogenic cardiac gene variants occurred in only 4.2% of cases (3).Most SUDC cases affect 1- to 4-y-olds, for whom “undetermined/unexplained” is the fifth leading category of death (4, 5). These cases challenge the medico-legal death investigation systems, which often lack standardized methods and resources (6). These limitations and the perceived need to identify a cause of death (6, 7) lead to some unexplained pediatric deaths being misclassified as “explained” (e.g., mild respiratory illness) (8), which likely underestimates the true incidence of unexplained childhood deaths. Although sudden death studies focus on cardiac genes (9), seizures likely cause some SUDC since febrile seizures occur in 29 to 32% of decedents, ∼10-fold greater than the general population (10–12). This suggests a contributory mechanism similar to sudden unexpected death in epilepsy (SUDEP) (7).In comparison to the 1,400 annual United States cases of sudden infant death syndrome (SIDS), there are 400 SUDC cases. However, SIDS has received >$500 million for research and public health education in the United States (13), with >12,000 articles in PubMed, while SUDC has received no targeted research funding and <45 articles in PubMed. Thus, there has been a 300:1 disparity in funding and publications for two lethal childhood disorders with a 4:1 incidence. Despite the wealth of SIDS research, a recent review of genetic findings identified only four pathogenic de novo mutations (DNMs), which are present in the proband and absent in both parents. A major hindrance is that molecular autopsies typically lack parental data, limiting identification of DNMs.To identify potential pathogenic de novo or inherited coding single nucleotide variants and indels in SUDC, we studied genetic data from 124 decedent/parental trios, the largest trio dataset of any sudden pediatric death cohort. We sought to identify de novo and inherited pathogenic variants, focusing initially on cardiac and epilepsy genes given prior epidemiological and genetic studies (14, 15). We also functionally characterized pathogenic variants involving overlapping pathways to assess the role of impaired cardiac/neuronal Ca²⁺ signaling and excitability as a common pathogenic mechanism. All cases were obtained from the SUDC Registry and Research Collaborative (SUDCRRC), a registry approved by the New York University Institutional Review board (#S14-01061), that supports the epidemiology of sudden death in children after age 1 y as occurring primarily in toddlers (5).     

The Long QT Syndrome

The long QT syndrome (LQTS) is a genetically transmitted cardiac arrhythmia due to ion channel protein abnormalities, which affects the transport of potassium and sodium ions across the cell membrane. Patients with LQTS may present with syncope, seizures or aborted cardiac arrest. LQTS is also an important cause of unexplained sudden cardiac death in the young. The diagnosis of LQTS is generally made on an ECG showing the prolonged QT interval. The establishment of LQTS registry and the discovery of genetic mutations causing LQTS have contributed greatly to the understanding of this condition and have also provided an impetus in understanding of other inherited cardiac arrhythmias. Genotype-phenotype correlation studies have allowed risk stratification of LQTS patients. Life style modification to avoid triggers for malignant cardiac arrhythmias, and the use of beta-blockers, pacemakers and implantable defibrillators, help to treat symptoms and reduce mortality in these patients.     

The autopsy study of 553 cases of sudden cardiac death in Chinese adults

Despite a recent epidemiological study reporting a lower incidence of sudden cardiac death (SCD) in China as compared with that in Western countries, the exact causes of SCD are still unknown. Using a uniform review protocol and diagnostic criteria, a retrospective autopsy study identified 553 cases of SCD in 14,487 consecutive autopsies from eight regions in China representing different geographic and population features. Their ages ranged from 18 to 80 years (median 43.0 years) with a ratio of 4.3/1.0 for male/female. Out-of-hospital deaths and unwitnessed cases accounted for 74.3 and 22.6 %, respectively. The main causes of death were coronary atherosclerotic disease (CAD 50.3 %), myocarditis (14.8 %), and hypertrophic cardiomyopathy (4.5 %), with unexplained sudden death accounting for 12.1 % of the cases. CAD had a proportion of 10.4 % in victims <35 years, lower as compared with 59.0 and 83.0 % in victims aged 35–54 and in victims ≥55 years. On the other hand, myocarditis and unexplained sudden death were major causes and accounted for 34.7 and 22.5 % in victims <35 years. In order to differentiate the degree of the cause–effect relationship between autopsy findings and sudden death, a grading method was used in this series and characterized 24.3 % of findings as certain, 52.9 % as highly probable, and 22.8 % as uncertain. Our data indicated that there most likely are less CAD but more myocarditis and unexplained sudden death in Chinese youth with SCD than in populations from Western countries. Molecular genetic testing should be conducted in those cases with uncertain findings and unexplained sudden death in routine autopsy.