Original Article

Electrocardiographic Abnormalities and Sudden Death in Myotonic Dystrophy Type 1

William J. Groh, M.D., M.P.H., Miriam R. Groh, M.S., Chandan Saha, Ph.D., John C. Kincaid, M.D., Zachary Simmons, M.D., Emma Ciafaloni, M.D., Rahman Pourmand, M.D., Richard F. Otten, M.D., Deepak Bhakta, M.D., Girish V. Nair, M.D., M.S., Mohammad M. Marashdeh, M.D., Douglas P. Zipes, M.D., and Robert M. Pascuzzi, M.D.

N Engl J Med 2008; 358:2688-2697June 19, 2008

Abstract

Background

Sudden death can occur as a consequence of cardiac-conduction abnormalities in the neuromuscular disease myotonic dystrophy type 1. The determinants of the risk of sudden death remain imprecise.

Full Text of Background...

Methods

We assessed whether the electrocardiogram (ECG) was useful in predicting sudden death in 406 adult patients with genetically confirmed myotonic dystrophy type 1. A patient was characterized as having a severe abnormality if the ECG had at least one of the following features: rhythm other than sinus, PR interval of 240 msec or more, QRS duration of 120 msec or more, or second-degree or third-degree atrioventricular block.

Full Text of Methods...

Results

Patients with severe abnormalities according to the entry ECG were older than patients without severe abnormalities, had more severe skeletal-muscle impairment, and were more likely to have heart failure, left ventricular systolic dysfunction, or atrial tachyarrhythmia. Such patients were more likely to receive a pacemaker or an implantable cardioverter–defibrillator during the follow-up period. During a mean follow-up period of 5.7 years, 81 patients died; there were 27 sudden deaths, 32 deaths from progressive neuromuscular respiratory failure, 5 nonsudden deaths from cardiac causes, and 17 deaths from other causes. Among the 17 patients who died suddenly in whom postcollapse rhythm was evaluated, a ventricular tachyarrhythmia was observed in 9. A severe ECG abnormality (relative risk, 3.30; 95% confidence interval [CI], 1.24 to 8.78) and a clinical diagnosis of atrial tachyarrhythmia (relative risk, 5.18; 95% CI, 2.28 to 11.77) were independent risk factors for sudden death.

Full Text of Results...

Conclusions

Patients with adult myotonic dystrophy type 1 are at high risk for arrhythmias and sudden death. A severe abnormality on the ECG and a diagnosis of an atrial tachyarrhythmia predict sudden death. (ClinicalTrials.gov number, NCT00622453.)

Full Text of Discussion...

Read the Full Article...

Media in This Article

Table 1Characteristics of the Patients at Study Entry and New Events at Follow-up According to the Presence or Absence of a Severe ECG Abnormality at Entry.

Table 2The Relation between the Characteristics of the Patients and Sudden Death, Death from Progressive Neuromuscular Respiratory Failure, and Death from Any Cause.

Article Activity

57 articles have cited this article

Article

Myotonic dystrophy is an autosomal dominant disorder that is the most common muscular dystrophy presenting in adults.1 It is characterized by myotonia (delayed muscle relaxation after contraction), progressive weakness and atrophy of the skeletal muscles, and systemic manifestations, including cardiac involvement.2 Myotonic dystrophy type 1, the more common and typically the more severe of the two major types, is caused by an expanded cytosine–thymine–guanine (CTG) repeat on chromosome 19 in the 3′ untranslated region of a serine–threonine protein kinase gene called DMPK (dystrophia myotonica protein kinase).3-5

Sudden death can occur in patients with myotonic dystrophy type 1 as a consequence of myocardial fibrosis and degeneration of the cardiac-conduction system.6-11 Cardiac involvement initially manifests as asymptomatic electrocardiographic (ECG) abnormalities, commonly prolongation of the PR interval and QRS duration. Arrhythmias can occur, including sinus-node dysfunction; progressive heart block; atrial tachycardia, flutter, or fibrillation; and ventricular tachycardia or fibrillation. Sudden death is believed to result from asystole after atrioventricular block or from a ventricular tachyarrhythmia.9,12 Because of the unpredictable progression of atrioventricular block, pacemakers have been recommended for patients with clinically significant conduction abnormalities.13 Implantable cardioverter–defibrillators have been used in patients with ventricular tachyarrhythmias.12,14,15

Efforts to develop a method to identify patients with myotonic dystrophy type 1 who are at high risk for sudden death have been stymied because studies have failed to enroll and follow a sufficiently large, prospectively characterized population without referral bias. As a result, the optimal clinical approach to the diagnosis and treatment of arrhythmias is unclear, as is the effect of therapeutic interventions on the risk of sudden death.

There is evidence that patients with more severe conduction abnormalities, as quantified on the ECG, are at higher risk for arrhythmias.8,16 The ECG has therefore been recommended as an appropriate screening test, but its usefulness for the prediction of sudden death remains unknown.9,17 We tested the hypothesis that a severe abnormality on the ECG would predict sudden death in a population of patients with myotonic dystrophy type 1.

Methods

Study Organization

The study was conducted at 23 neuromuscular-disease clinics in the United States; it was initiated in April 1997, and follow-up is ongoing. All authors vouch for the completeness and accuracy of the data and its analysis and participated in writing the article. The institutional review boards of Indiana University and of each clinic approved the study.

The study was funded by Medtronic, the Muscular Dystrophy Association, and the National Institutes of Health. The funding entities had no role in the design of the study, the analysis or interpretation of the data, or the decision to publish the results.

Patients

Adult patients (18 years of age or older) with a clinical diagnosis of myotonic dystrophy were invited to participate. Analysis of the CTG repeat sequence was performed on leukocytes (at the Athena Diagnostics Laboratory) with the use of polymerase-chain-reaction assays and analysis of restriction-fragment-length polymorphisms, as well as the Southern blot technique.5,18 Only patients with an abnormal CTG repeat sequence (one or both alleles with ≥38 repeats) confirmatory of myotonic dystrophy type 1 were included.19 All patients provided written informed consent.

Evaluation at Study Entry

The clinical characteristics of the patients were ascertained from history and examination. An atrial tachyarrhythmia was diagnosed if the patient had a history of sustained atrial tachycardia, flutter, or fibrillation. A ventricular tachyarrhythmia was diagnosed if the patient had a history of sustained ventricular tachycardia or fibrillation. Cardiac-imaging studies assessing left ventricular function were reviewed, and a patient was considered to have systolic dysfunction if it was reported in the study results or if the ejection fraction was less than 50%. The severity of weakness was scored by a standardized five-point muscular-impairment rating scale, in which a score of 1 indicates no clinical muscular impairment, 2 minimal signs without distal weakness except for digit flexors, 3 distal weakness without proximal weakness except for elbow extensors, 4 moderate proximal weakness, and 5 severe proximal weakness.20 For analysis, patients with no or minimal weakness (muscular-impairment rating of 1 or 2) were grouped.

All patients underwent a 12-lead ECG that was analyzed by one investigator (Dr. Groh). A patient was classified as having a severe abnormality indicative of conduction disease if the ECG had at least one of the following features: rhythm other than sinus, PR interval of 240 msec or more, QRS duration of 120 msec or more, or second-degree or third-degree atrioventricular block.

Causes of Death

Follow-up was performed annually and could include a clinic visit, a newsletter with a reply questionnaire, or telephone contact. The decision to refer patients for cardiac evaluation was made by local care providers. New cardiac diagnoses were confirmed by a review of the records. Annual ECGs were recommended but not required. National death indexes were searched regularly.

Deaths were classified as sudden or nonsudden. Sudden death was defined as death occurring suddenly and unexpectedly in a patient who was stable before the event.21,22 Witnessed deaths were classified as sudden only if death occurred within 1 hour after the onset of new symptoms. Unwitnessed deaths were considered sudden if the patient was seen alive and stable during the previous 24 hours. If the temporal sequence was consistent with sudden death but a specific cause of death other than arrhythmia was confirmed, the death was classified as nonsudden. When available, ECG recordings were used to characterize the initial rhythm. Nonsudden deaths were subclassified into those related to progressive neuromuscular respiratory failure, cardiac deaths, and other deaths. Progressive neuromuscular respiratory failure was defined as death resulting from respiratory dysfunction related to myotonic dystrophy. Cardiac death was defined as death related primarily to a cardiac cause. Causes of death were adjudicated by a committee of study investigators who were unaware of all other patient data.

Statistical Analysis

Characteristics at study entry and non–time-dependent characteristics at follow-up were compared between patients with and those without severe abnormalities on the entry ECG with the use of Student's t-test for continuous variables and the chi-square test or Fisher's exact test for categorical variables.

The times to new events occurring during follow-up were compared between patients with and those without severe ECG abnormalities with the use of Kaplan–Meier analysis and the log-rank test. The relative risks of sudden death, death due to progressive neuromuscular respiratory failure, and death from any cause were estimated for individual covariates with the use of a Cox proportional-hazards model. Variables associated with ECG abnormalities and death were entered into multivariate Cox proportional-hazards models in a stepwise selection procedure based on the likelihood-ratio test to determine the independent effect of patient characteristics on the relative risk of death. The follow-up time was the interval from study entry to the most recent evaluation or death and was censored at death for the determination of time to sudden death or death due to progressive neuromuscular respiratory failure in patients dying of other causes. Characteristics changing during follow-up were incorporated as time-dependent covariates. The sensitivity, specificity, and positive and negative predictive values of a severe abnormality on the ECG and a clinical diagnosis of an atrial tachyarrhythmia for sudden death were determined.

Two-sided P values were calculated for all analyses; values of 0.05 or less were considered to indicate statistical significance. Data were analyzed with SPSS software for Windows, version 14.0, and SAS software, version 9.3.1.

Results

Characteristics of the Patients

Of 443 patients evaluated, 37 did not have an abnormal CTG repeat sequence and were excluded. The remaining 406 patients made up the study population. Of these, 310 did not have a severe ECG abnormality at study entry and 96 did. The characteristics of the patients at entry are shown in Table 1Table 1Characteristics of the Patients at Study Entry and New Events at Follow-up According to the Presence or Absence of a Severe ECG Abnormality at Entry.. Patients with severe ECG abnormalities were older, had more CTG repeats, and had more severe muscular impairment.

Seven of the 406 enrolled patients (1.7%) were lost to follow-up after study entry. None of these patients died during follow-up, according to a review of national death indexes. The mean and median durations of follow-up were 5.7 and 6.5 years, respectively. There was no difference in duration of follow-up between patients with and those without severe ECG abnormalities.

Table 1 also includes events occurring during follow-up according to the presence or absence of a severe ECG abnormality at study entry. There was no difference between the two groups in the rate of progression of muscular impairment during follow-up. Heart failure and left ventricular systolic dysfunction at entry or newly diagnosed during follow-up were more frequent in patients with severe ECG abnormalities at entry. Nineteen of the 23 patients with left ventricular systolic dysfunction had nonischemic cardiomyopathy attributed to myotonic dystrophy.

A diagnosis of atrial tachyarrhythmia was common, especially in those with severe ECG abnormalities at entry (29 of 96 patients). A diagnosis of ventricular tachyarrhythmia was less common. Pacemakers and implantable cardioverter–defibrillators were more frequently used in patients with severe ECG abnormalities. Among the 41 patients with pacemakers, 27 had either no or minimal symptoms and had received their pacemakers because of concern about conduction abnormalities. Nine of the 14 cardioverter–defibrillators were implanted in patients who did not have a diagnosis of spontaneous ventricular tachyarrhythmia.

There were no differences between the two groups in the likelihood of obtaining follow-up ECGs or in the interval between the first and last ECG. The ECGs typically showed concordant prolongation in the PR interval and QRS duration. Patients with severe ECG abnormalities at entry had greater rates of progression of the PR interval and of QRS duration and were more likely to have a new atrial tachyarrhythmia or a paced rhythm on subsequent ECGs. Sixty-nine patients without a severe ECG abnormality at study entry received a diagnosis of a severe abnormality on ECGs that were recorded during follow-up.

Death

Eighty-one of the 406 patients (20.0%) died during follow-up. The median age at death was 54 years. Twenty-seven (33.3%) of the deaths were sudden; details of events for the patients with sudden death are given in the Supplementary Appendix, available with the full text of this article at www.nejm.org.

Nonsudden deaths were categorized as resulting from progressive neuromuscular respiratory failure in 32 patients (39.5%), cardiac causes in 5 (6.2%), and other causes in 17 (21.0%). Of the five nonsudden cardiac deaths, three were due to progressive heart failure in patients with a cardiomyopathy attributed to myotonic dystrophy and two to coronary artery disease.

The relationship between the characteristics of the patients and the cause of death is reported in Table 2Table 2The Relation between the Characteristics of the Patients and Sudden Death, Death from Progressive Neuromuscular Respiratory Failure, and Death from Any Cause.. A univariate association with sudden death was identified for age, severe proximal muscle weakness, all the cardiac and arrhythmia diagnoses except ventricular tachyarrhythmia, the presence of a pacemaker or cardioverter–defibrillator, and each of the ECG indicators except paced rhythm. A significant univariate association with death due to progressive neuromuscular respiratory failure was identified for age, moderate and severe proximal muscle weakness, heart failure, atrial tachyarrhythmia, the presence of a pacemaker, and each of the ECG indicators except QRS duration. Death from any cause was significantly associated with ventricular tachyarrhythmia and with all the characteristics associated with sudden death and death from progressive neuromuscular respiratory failure.

Multivariate Cox regression models were constructed to determine which characteristics were independently associated with death (Table 3Table 3The Relation between Patient Characteristics and the Risk of Death.). Because a severe ECG abnormality was defined by the rhythm, PR interval, QRS duration, and presence of atrioventricular block, these individual covariates were not included in the multivariate models. All models were adjusted for age, the presence or absence of a pacemaker, and the presence or absence of a severe ECG abnormality, even when these variables were not significant predictors. A diagnosis of atrial tachyarrhythmia and a severe ECG abnormality were independent risk factors associated with sudden death. Other characteristics were not significant independent predictors of sudden death and had minimal effect on the multivariate model if they were included. Age, severe proximal muscle weakness, heart failure, and atrial tachyarrhythmia were independent risk factors for death from progressive neuromuscular respiratory failure. Age, severe proximal muscle weakness, heart failure, atrial tachyarrhythmia, and ventricular tachyarrhythmia were independent risk factors for death from any cause.

The presence of a severe ECG abnormality had a sensitivity of 74.1% for the prediction of sudden death, a specificity of 61.7%, a positive predictive value of 12.1%, and a negative predictive value of 97.1%. The presence of the combined risk factors of a severe ECG abnormality and a clinical diagnosis of an atrial tachyarrhythmia had a sensitivity of 81.5% for the prediction of sudden death, a specificity of 59.4%, a positive predictive value of 12.5%, and a negative predictive value of 97.8%.

Discussion

Our study demonstrated that a severe abnormality on the ECG is an independent predictor, with moderate sensitivity, of sudden death in patients with myotonic dystrophy type 1. In a population of persons with genetically confirmed disease, we defined a severe ECG abnormality with the use of clinically relevant and easily measured parameters. During follow-up, 20% of the patients died, and one third of the deaths were sudden. Each of the indicators we used to define a severe ECG abnormality predicted the risk of sudden death when risk was evaluated on a univariate level; when combined, these indicators predicted the risk of sudden death in multivariate modeling. The presence of a severe ECG abnormality was specific for the prediction of sudden death; it was not an independent risk factor for nonsudden death from progressive neuromuscular respiratory failure or for death from any cause.

The presence of a severe ECG abnormality is indicative of cardiac conduction-system disease that is known to occur in myotonic dystrophy type 1. A prolonged PR interval and QRS duration correlate with the degree of conduction delay between the atria and the bundle of His and between the bundle of His and the ventricles and with the distribution and extent of conduction-system lesions found at autopsy.7,23,24 Conduction-system abnormalities can progress to complete atrioventricular block that can result in asystole and sudden death. In addition, conduction-system abnormalities can be associated with ventricular tachyarrhythmias that can result in sudden death.8,12,16,25 We had access to ECGs for more than half of the patients who died suddenly. A ventricular tachyarrhythmia was most commonly observed. Others have reported ventricular tachyarrhythmias as a cause of sudden death in patients with myotonic dystrophy.9-11,26,27 Whether the initial rhythm recorded after collapse was also the initiating rhythm is unknown. Although our study used an accepted definition of sudden death, appropriate classification remains difficult.22,28 Mechanisms other than arrhythmias could have had a role in some of the sudden deaths.25

Patients with severe abnormalities on the entry ECG were more likely to have or to receive a diagnosis of other factors that adversely affected outcome. These patients were older, had more muscular impairment, and were more likely to have or to receive a diagnosis of heart failure, left ventricular systolic dysfunction, or atrial tachyarrhythmia. Nonetheless, when these characteristics were evaluated in the multivariate model, an abnormal ECG remained a significant predictor of sudden death, with an adjusted relative risk of 3.30.

Despite a substantial burden of sudden death, the major cause of death was respiratory failure associated with progressive muscular weakness attributed to myotonic dystrophy, a finding similar to findings observed in other large registries.10,11 Independent predictors of death from progressive neuromuscular respiratory failure included older age, more severe muscular impairment, and a diagnosis of heart failure or atrial tachyarrhythmia. Because respiratory failure accounted for more deaths than did any other cause, these same characteristics were also independent predictors of death from any cause. The progressive muscular weakness observed in these patients affected their treatment after cardiac arrest and the subsequent outcomes. In three patients with acute unstable arrhythmias, resuscitative measures were aborted after the initial evaluation of rhythm because of advance health care directives. In another patient, resuscitative measures were stopped after defibrillation of a ventricular tachyarrhythmia resulted in asystole. These four patients all had severe proximal muscle weakness, as assessed at the last study follow-up. It is likely that their stable but severe muscular involvement influenced decisions regarding emergency medical care.

The most common clinical arrhythmia observed was an atrial tachyarrhythmia. A diagnosis of atrial tachyarrhythmia was the only characteristic independently predicting both sudden death and death from progressive neuromuscular respiratory failure. Different mechanisms could be responsible for the association of an atrial tachyarrhythmia with these two causes of death. An atrial tachyarrhythmia could reflect the presence of atrial fibrosis indicative of conduction involvement and an increased risk of sudden death.7 Atrial tachyarrhythmias could also be more common in patients with pulmonary dysfunction who are at higher risk for death due to progressive neuromuscular respiratory failure.29

By the time of the last follow-up visit, 10 of the 96 patients with severe ECG abnormalities at study entry had received a diagnosis of heart failure. The majority of patients with heart failure had a diagnosis of nonischemic cardiomyopathy attributed to myotonic dystrophy.30 A diagnosis of heart failure was associated with death from progressive neuromuscular respiratory failure and death from any cause. Screening patients with myotonic dystrophy type 1 for signs and symptoms of heart failure, especially those with an abnormal ECG, is appropriate.

On the basis of nonrandomized observations, some investigators have recommended pacemakers for patients with myotonic dystrophy and asymptomatic cardiac-conduction abnormalities.25,31 Pacing guidelines have been updated to reflect these recommendations.13 Such recommendations appeared to affect the use of pacemakers in our registry. By the time of the last follow-up visit, 10% of the patients had pacemakers, two thirds of which were prophylactic. However, we did not observe that pacemakers decreased the rates of sudden death or death from any cause. We and others have recognized that patients with myotonic dystrophy continue to die suddenly despite having functioning pacemakers.10,11,25,26

A small number of the patients received implantable cardioverter–defibrillators, most of which were prophylactic. These devices are capable of delivering both pacing and defibrillation and therefore can treat both bradycardia and ventricular tachyarrhythmias. Sudden death occurred in two patients with implantable cardioverter–defibrillators. In one patient, postmortem evaluation of the cardioverter–defibrillator memory was available. The stored ECGs implicated an atrial tachyarrhythmia with recurrent delivery of inappropriate cardioverter–defibrillator therapy, provoking a later ventricular tachyarrhythmia and ultimately asystole not responding to pacing. The predominance of ventricular tachyarrhythmias observed in patients at the initial evaluation of rhythm after collapse lends support to the concept that cardioverter–defibrillators could be beneficial in preventing sudden death. However, the effectiveness of cardioverter–defibrillators in reducing mortality in patients with myotonic dystrophy type 1 remains unknown. Mortality from progressive neuromuscular respiratory failure could limit the overall duration of benefit of implantable cardioverter–defibrillators in patients with myotonic dystrophy type 1.

In conclusion, our study shows that adult patients with myotonic dystrophy type 1 are at high risk for sudden death. The presence of a severe ECG abnormality and a clinical diagnosis of atrial tachyarrhythmia were the only independent predictors of sudden death detected in our analysis.

Supported by grants from Medtronic, the Muscular Dystrophy Association, and the National Institutes of Health (MO1 RR00750-27S1). The authors acknowledge the support of the participating neuromuscular specialty clinics by the Muscular Dystrophy Association.

Dr. Zipes reports receiving grant support and lecture and consulting fees from Medtronic. No other potential conflict of interest relevant to this article was reported.

We thank the following investigators who assisted with patient recruitment or follow-up (listed in order of registry entry, with affiliations at the time of study entry): Indiana University, Indianapolis — R.M. Pascuzzi, J.C. Kincaid, H.A. Horak, R. Pourmand; Methodist Hospital, Indianapolis — W.H. Cooper; Mary Free Bed Clinic, Grand Rapids, MI — J.F. Butzer; Springfield Clinic, Springfield, IL — D.A. Gelber; Duke University, Durham, NC — E.W. Massey, E. Ciafaloni, R.W. Tim; Neurology Associates, Arlington, TX — R.E. McMichael; University of Alabama, Birmingham — S.J. Oh; Emory University, Atlanta — J. Washington, A.S. Zacharias; Health South Tri State Rehabilitation Hospital, Evansville, IN — T.J. Rusche; Neuromuscular Research Center, Phoenix, AZ — K. Sivakumar; Oregon Health Sciences University, Portland — J. Kron, W. Johnston; West Virginia University, Morgantown — L. Gutmann; Carle Clinic, Urbana, IL — R.E. Cranston; Merit Care Medical Group, Fargo, ND — R.C. Bailly; East Virginia Medical School, Norfolk — L.M. Frank; University of Chicago, Chicago — B.C. Soliven, F.F. Eide; Children's Hospital of Michigan, Detroit — M.A. Nigro; University of Massachusetts, Worcester — I.R. Bella; Tampa Neurology Associates, Tampa, FL — S.M. Sergay; Pennsylvania State College of Medicine, Hershey — Z. Simmons; University of Rochester, Rochester, NY — R.T. Moxley; Louisiana State University, Shreveport — R.N. Schwendimann; St. Elizabeth Health Center, Youngstown, OH — D.J. Tamulonis.

Source Information

From the Department of Medicine, Krannert Institute of Cardiology (W.J.G., M.R.G., R.F.O., D.B., G.V.N., M.M.M., D.P.Z.), the Division of Biostatistics (C.S.), and the Department of Neurology (J.C.K., R.M.P.), Indiana University, Indianapolis; the Department of Neurology, Pennsylvania State University, Hershey (Z.S.); the Department of Neurology, University of Rochester, Rochester, NY (E.C.); and the Department of Neurology, State University of New York at Stony Brook, Stony Brook (R.P.).

Address reprint requests to Dr. Groh at the Krannert Institute of Cardiology, Indiana University, 1800 N. Capitol, Rm. E406, Indianapolis, IN 46202, or at wgroh@iupui.edu.

References

References

1. 1

   Ashizawa T, Epstein HF. Ethnic distribution of myotonic dystrophy gene. Lancet 1991;338:642-643
   CrossRef | Web of Science | Medline

2. 2

   Harper PS, van Engelen BG, Eymard B, Rogers M, Wilcox D. 99th European Neuromuscular Centre International Workshop: myotonic dystrophy: present management, future therapy. Neuromuscul Disord 2002;12:596-599
   CrossRef | Medline

3. 3

   Buxton J, Shelbourne P, Davies J, et al. Detection of an unstable fragment of DNA specific to individuals with myotonic dystrophy. Nature 1992;355:547-548
   CrossRef | Web of Science | Medline

4. 4

   Aslanidis C, Jansen G, Amemiya C, et al. Cloning of the essential myotonic dystrophy region and mapping of the putative defect. Nature 1992;355:548-551
   CrossRef | Web of Science | Medline

5. 5

   Brook JD, McCurrach ME, Harley HG, et al. Molecular basis of myotonic dystrophy: expansion of a trinucleotide (CTG) repeat at the 3′ end of a transcript encoding a protein kinase family member. Cell 1992;68:799-808
   CrossRef | Web of Science | Medline

6. 6

   Fisch C. The heart in dystrophia myotonica. Am Heart J 1951;41:525-538
   CrossRef | Web of Science | Medline

7. 7

   Nguyen HH, Wolfe JT III, Holmes DR Jr, Edwards WD. Pathology of the cardiac conduction system in myotonic dystrophy: a study of 12 cases. J Am Coll Cardiol 1988;11:662-671
   CrossRef | Web of Science | Medline

8. 8

   Colleran JA, Hawley RJ, Pinnow EE, Kokkinos PF, Fletcher RD. Value of the electrocardiogram in determining cardiac events and mortality in myotonic dystrophy. Am J Cardiol 1997;80:1494-1497
   CrossRef | Web of Science | Medline

9. 9

   Phillips MF, Harper PS. Cardiac disease in myotonic dystrophy. Cardiovasc Res 1997;33:13-22
   CrossRef | Web of Science | Medline

10. 10

    de Die-Smulders CE, Howeler CJ, Thijs C, et al. Age and causes of death in adult-onset myotonic dystrophy. Brain 1998;121:1557-1563
    CrossRef | Web of Science | Medline

11. 11

    Mathieu J, Allard P, Potvin L, Prevost C, Begin P. A 10-year study of mortality in a cohort of patients with myotonic dystrophy. Neurology 1999;52:1658-1662
    Web of Science | Medline

12. 12

    Merino JL, Carmona JR, Fernandez-Lozano I, Peinado R, Basterra N, Sobrino JA. Mechanisms of sustained ventricular tachycardia in myotonic dystrophy: implications for catheter ablation. Circulation 1998;98:541-546
    Web of Science | Medline

13. 13

    Gregoratos G, Abrams J, Epstein AE, et al. ACC/AHA/NASPE 2002 guideline update for implantation of cardiac pacemakers and antiarrhythmia devices: summary article: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines. Circulation 2002;106:2145-2161
    CrossRef | Medline

14. 14

    Hadian D, Lowe MR, Scott LR, Groh WJ. Use of an insertable loop recorder in a myotonic dystrophy patient. J Cardiovasc Electrophysiol 2002;13:72-73
    CrossRef | Web of Science | Medline

15. 15

    Bassez G, Lazarus A, Desguerre I, et al. Severe cardiac arrhythmias in young patients with myotonic dystrophy type 1. Neurology 2004;63:1939-1941
    Web of Science | Medline

16. 16

    Clarke NR, Kelion AD, Nixon J, Hilton-Jones D, Forfar JC. Does cytosine-thymine-guanine (CTG) expansion size predict cardiac events and electrocardiographic progression in myotonic dystrophy? Heart 2001;86:411-416
    CrossRef | Web of Science | Medline

17. 17

    Hawley RJ, Milner MR, Gottdiener JS, Cohen A. Myotonic heart disease: a clinical follow-up. Neurology 1991;41:259-262
    Web of Science | Medline

18. 18

    Fu YH, Pizzuti A, Fenwick RG Jr, et al. An unstable triplet repeat in a gene related to myotonic muscular dystrophy. Science 1992;255:1256-1258
    CrossRef | Web of Science | Medline

19. 19

    International Myotonic Dystrophy Consortium. New nomenclature and DNA testing guidelines for myotonic dystrophy type 1 (DM1). Neurology 2000;54:1218-1221
    Web of Science | Medline

20. 20

    Mathieu J, Boivin H, Meunier D, Gaudreault M, Begin P. Assessment of a disease-specific muscular impairment rating scale in myotonic dystrophy. Neurology 2001;56:336-340
    Web of Science | Medline

21. 21

    The Cardiac Arrhythmia Suppression Trial (CAST) Investigators. Preliminary report: effect of encainide and flecainide on mortality in a randomized trial of arrhythmia suppression after myocardial infarction. N Engl J Med 1989;321:406-412
    Full Text | Web of Science | Medline

22. 22

    Chugh SS, Jui J, Gunson K, et al. Current burden of sudden cardiac death: multiple source surveillance versus retrospective death certificate-based review in a large U.S. community. J Am Coll Cardiol 2004;44:1268-1275
    CrossRef | Web of Science | Medline

23. 23

    Babuty D, Fauchier L, Tena-Carbi D, et al. Is it possible to identify infrahissian cardiac conduction abnormalities in myotonic dystrophy by non-invasive methods? Heart 1999;82:634-637
    Web of Science | Medline

24. 24

    Lazarus A, Varin J, Ounnoughene Z, et al. Relationships among electrophysiological findings and clinical status, heart function, and extent of DNA mutation in myotonic dystrophy. Circulation 1999;99:1041-1046
    Web of Science | Medline

25. 25

    Lazarus A, Varin J, Babuty D, Anselme F, Coste J, Duboc D. Long-term follow-up of arrhythmias in patients with myotonic dystrophy treated by pacing: a multicenter diagnostic pacemaker study. J Am Coll Cardiol 2002;40:1645-1652
    CrossRef | Web of Science | Medline

26. 26

    Grigg LE, Chan W, Mond HG, Vohra JK, Downey WF. Ventricular tachycardia and sudden death in myotonic dystrophy: clinical, electrophysiologic and pathologic features. J Am Coll Cardiol 1985;6:254-256
    CrossRef | Web of Science | Medline

27. 27

    Florek RC, Triffon DW, Mann DE, Ringel SP, Reiter MJ. Electrocardiographic abnormalities in patients with myotonic dystrophy. West J Med 1990;153:24-27
    Medline

28. 28

    Pratt CM, Greenway PS, Schoenfeld MH, Hibben ML, Reiffel JA. Exploration of the precision of classifying sudden cardiac death: implications for the interpretation of clinical trials. Circulation 1996;93:519-524
    Web of Science | Medline

29. 29

    Benjamin EJ, Levy D, Vaziri SM, D'Agostino RB, Belanger AJ, Wolf PA. Independent risk factors for atrial fibrillation in a population-based cohort: the Framingham Heart Study. JAMA 1994;271:840-844
    CrossRef | Web of Science | Medline

30. 30

    Bhakta D, Lowe MR, Groh WJ. The prevalence of structural heart abnormalities in myotonic dystrophy type 1. Am Heart J 2004;147:224-227
    CrossRef | Web of Science | Medline

31. 31

    Pelargonio G, Dello Russo A, Sanna T, De Martino G, Bellocci F. Myotonic dystrophy and the heart. Heart 2002;88:665-670
    CrossRef | Web of Science | Medline

Citing Articles (57)

Citing Articles

1. 1

   ANNE B. CURTIS, KINAN DALAL. (2011) The Role of Implantable Cardiac Electrical Devices in Patients with Myotonic Dystrophy. Journal of Cardiovascular Electrophysiology 22:12, 1376-1377
   CrossRef

2. 2

   DEEPAK BHAKTA, CHANGYU SHEN, JACK KRON, ANDREW E. EPSTEIN, ROBERT M. PASCUZZI, WILLIAM J. GROH. (2011) Pacemaker and Implantable Cardioverter-Defibrillator Use in a US Myotonic Dystrophy Type 1 Population. Journal of Cardiovascular Electrophysiology 22:12, 1369-1375
   CrossRef

3. 3

   Manoj P Menezes, Kathryn N North. (2011) Inherited neuromuscular disorders: Pathway to diagnosis. Journal of Paediatrics and Child Healthno-no
   CrossRef

4. 4

   Claudia Stöllberger, Christina Steger, Paul Gabriel, Josef Finsterer. (2011) Implantable loop recorders in myotonic dystrophy 1. International Journal of Cardiology 152:2, 249-251
   CrossRef

5. 5

   Nicholas Johnson, Chad R. Heatwole. 2011. Myotonic Dystrophies. , 80-86.
   CrossRef

6. 6

   Bela Juhasz, Balazs Varga, Attila Czompa, Istvan Bak, Istvan Lekli, Rudolf Gesztelyi, Judit Zsuga, Adam Kemeny-Beke, Miklos Antal, Levente Szendrei, Arpad Tosaki. (2011) Postischemic cardiac recovery in heme oxygenase-1 transgenic ischemic/reperfused mouse myocardium. Journal of Cellular and Molecular Medicine 15:9, 1973-1982
   CrossRef

7. 7

   Helle Petri, John Vissing, Nanna Witting, Henning Bundgaard, Lars Køber. (2011) Cardiac manifestations of myotonic dystrophy type 1. International Journal of Cardiology
   CrossRef

8. 8

   A. Fayssoil, O. Nardi. (2011) Cœur et myotonie de Steinert. Annales de Cardiologie et d'Angéiologie 60:4, 225-229
   CrossRef

9. 9

   Dominique Babuty, Bénédicte Lallemand, Valérie Laurent, Nicolas Clémenty, Bertrand Pierre, Laurent Fauchier, Martine Raynaud, Sybille Pellieux. (2011) Quand implanter un stimulateur cardiaque dans la maladie de Steinert ?. La Presse Médicale 40:7-8, 748-753
   CrossRef

10. 10

    Pierre Kaminsky, Mathias Poussel, Lelia Pruna, Joëlle Deibener, Bruno Chenuel, Béatrice Brembilla-Perrot. (2011) Organ Dysfunction and Muscular Disability in Myotonic Dystrophy Type 1. Medicine 90:4, 262-268
    CrossRef

11. 11

    Valérie Laurent, Sybille Pellieux, Philippe Corcia, Pascal Magro, Bertrand Pierre, Laurent Fauchier, Martine Raynaud, Dominique Babuty. (2011) Mortality in myotonic dystrophy patients in the area of prophylactic pacing devices. International Journal of Cardiology 150:1, 54-58
    CrossRef

12. 12

    Frédérique Rau, Fernande Freyermuth, Charlotte Fugier, Jean-Philippe Villemin, Marie-Christine Fischer, Bernard Jost, Doulaye Dembele, Geneviève Gourdon, Annie Nicole, Denis Duboc, Karim Wahbi, John W Day, Harutoshi Fujimura, Masanori P Takahashi, Didier Auboeuf, Natacha Dreumont, Denis Furling, Nicolas Charlet-Berguerand. (2011) Misregulation of miR-1 processing is associated with heart defects in myotonic dystrophy. Nature Structural & Molecular Biology 18:7, 840-845
    CrossRef

13. 13

    Pierre Kaminsky, Béatrice Brembilla-Perrot, Lelia Pruna, Mathias Poussel, Bruno Chenuel. (2011) Age, conduction defects and restrictive lung disease independently predict cardiac events and death in myotonic dystrophy. International Journal of Cardiology
    CrossRef

14. 14

    Claudia Stöllberger, Hans Keller, Christina Steger, Josef Finsterer. (2011) Implantable loop-recorders in myopathic and non-myopathic patients with left ventricular hypertrabeculation/noncompaction. International Journal of Cardiology
    CrossRef

15. 15

    William J. Groh, Miriam R. Groh, Changyu Shen, Darren G. Monckton, Cynthia L. Bodkin, Robert M. Pascuzzi. (2011) Survival and CTG repeat expansion in adults with myotonic dystrophy type 1. Muscle & Nerve 43:5, 648-651
    CrossRef

16. 16

    Dianna Quan. (2011) Muscular Dystrophies and Neurologic Diseases that Present as Myopathy. Rheumatic Disease Clinics of North America 37:2, 233-244
    CrossRef

17. 17

    Larry B. Goldstein, Nada El Husseini. (2011) Neurología y cardiología: puntos de contacto. Revista Española de Cardiología 64:4, 319-327
    CrossRef

18. 18

    Larry B. Goldstein, Nada El Husseini. (2011) Neurology and Cardiology: Points of Contact. Revista Española de Cardiología (English Edition)
    CrossRef

19. 19

    Dany Patoine, Ibrahim Hasibu, Sylvie Pilote, Jean Champagne, Benoit Drolet, Chantale Simard. (2011) A Novel KCNQ1 Variant (L203P) Associated with Torsades de Pointes–Related Syncope in a Steinert Syndrome Patient. Canadian Journal of Cardiology 27:2, 263.e5-263.e12
    CrossRef

20. 20

    SAMAN NAZARIAN, KATHRYN R. WAGNER, BRIAN S. CAFFO, GORDON F. TOMASELLI. (2011) Clinical Predictors of Conduction Disease Progression in Type I Myotonic Muscular Dystrophy. Pacing and Clinical Electrophysiology 34:2, 171-176
    CrossRef

21. 21

    B. Brembilla-Perrot, J. D. Luporsi, S. Louis, P. Kaminsky. (2011) Long-term follow-up of patients with myotonic dystrophy: an electrocardiogram every year is not necessary. Europace 13:2, 251-257
    CrossRef

22. 22

    Christopher F. Spurney. 2011. Cardiac Complications of Neuromuscular Disorders. , 33-50.
    CrossRef

23. 23

    William C. Warner. 2011. Orthopedic Surgery in Neuromuscular Disorders. , 137-153.
    CrossRef

24. 24

    S. Rudnik-Schöneborn, M. Schaupp, A. Lindner, W. Kress, E. Schulze-Bahr, S. Zumhagen, M. Elbracht, K. Zerres. (2011) Brugada-like cardiac disease in myotonic dystrophy type 2: report of two unrelated patients. European Journal of Neurology 18:1, 191-194
    CrossRef

25. 25

    Bruce S. Stambler, Kenneth A. Ellenbogen. 2011. Pacing for Atrioventricular Conduction System Disease. , 323-360.
    CrossRef

26. 26

    Linda L. Bachinski, Mario Sirito, Maria Böhme, Keith A. Baggerly, Bjarne Udd, Ralf Krahe. (2010) Altered MEF2 isoforms in myotonic dystrophy and other neuromuscular disorders. Muscle & Nerve 42:6, 856-863
    CrossRef

27. 27

    Deepak Bhakta, Miriam R. Groh, Changyu Shen, Robert M. Pascuzzi, William J. Groh. (2010) Increased mortality with left ventricular systolic dysfunction and heart failure in adults with myotonic dystrophy type 1. American Heart Journal 160:6, 1137-1141.e1
    CrossRef

28. 28

    William J. Groh. (2010) The electrocardiogram: A useful screening test for cardiac involvement in some but not all of the muscular dystrophies. Heart Rhythm 7:10, 1489-1490
    CrossRef

29. 29

    Anjan M. Shah, John L. Jefferies, Joseph W. Rossano, Jamie A. Decker, Bryan C. Cannon, Jeffrey J. Kim. (2010) Electrocardiographic abnormalities and arrhythmias are strongly associated with the development of cardiomyopathy in muscular dystrophy. Heart Rhythm 7:10, 1484-1488
    CrossRef

30. 30

    A. J. Ward, M. Rimer, J. M. Killian, J. J. Dowling, T. A. Cooper. (2010) CUGBP1 overexpression in mouse skeletal muscle reproduces features of myotonic dystrophy type 1. Human Molecular Genetics 19:18, 3614-3622
    CrossRef

31. 31

    R. Spataro, M. Lo Re, T. Piccoli, F. Piccoli, V. La Bella. (2010) Causes and place of death in Italian patients with amyotrophic lateral sclerosis. Acta Neurologica Scandinavica 122:3, 217-223
    CrossRef

32. 32

    P. Lindqvist, S. Mörner, B.O. Olofsson, C. Backman, D. Lundblad, H. Forsberg, M.Y. Henein. (2010) Ventricular dysfunction in type 1 myotonic dystrophy: Electrical, mechanical, or both?. International Journal of Cardiology 143:3, 378-384
    CrossRef

33. 33

    M.C.E. Hermans, Y.M. Pinto, I.S.J. Merkies, C.E.M. de Die-Smulders, H.J.G.M. Crijns, C.G. Faber. (2010) Hereditary muscular dystrophies and the heart. Neuromuscular Disorders 20:8, 479-492
    CrossRef

34. 34

    John B. Williamson, Greg Lewis, Angela J. Grippo, Damon Lamb, Emily Harden, Mika Handleman, Jocelyn Lebow, C. Sue Carter, Stephen W. Porges. (2010) Autonomic predictors of recovery following surgery: A comparative study. Autonomic Neuroscience 156:1-2, 60-66
    CrossRef

35. 35

    Saman Nazarian, David A. Bluemke, Kathryn R. Wagner, Menekhem M. Zviman, Evrim Turkbey, Brian S. Caffo, Monda Shehata, David Edwards, Barbara Butcher, Hugh Calkins, Ronald D. Berger, Henry R. Halperin, Gordon F. Tomaselli. (2010) QRS prolongation in myotonic muscular dystrophy and diffuse fibrosis on cardiac magnetic resonance. Magnetic Resonance in Medicine 64:1, 107-114
    CrossRef

36. 36

    M. Koshelev, S. Sarma, R. E. Price, X. H.T. Wehrens, T. A. Cooper. (2010) Heart-specific overexpression of CUGBP1 reproduces functional and molecular abnormalities of myotonic dystrophy type 1. Human Molecular Genetics 19:6, 1066-1075
    CrossRef

37. 37

    S. Mörner, P. Lindqvist, C. Mellberg, B.-O. Olofsson, C. Backman, M. Henein, D. Lundblad, H. Forsberg. (2010) Profound cardiac conduction delay predicts mortality in myotonic dystrophy type 1. Journal of Internal Medicine
    CrossRef

38. 38

    Toby N. Weingarten, Ryan E. Hofer, Margherita Milone, Juraj Sprung. (2010) Anesthesia and myotonic dystrophy type 2: a case series. Canadian Journal of Anesthesia/Journal canadien d'anesthésie 57:3, 248-255
    CrossRef

39. 39

    Allison Conravey, Lenay Santana-Gould. (2010) Myotonia Congenita and Myotonic Dystrophy: Surveillance and Management. Current Treatment Options in Neurology 12:1, 16-28
    CrossRef

40. 40

    Ignasi Anguera, Joan Nicolàs, Xavier Sabaté, Enric Esplugas. (2010) Taquicardia ventricular sincopal como primera manifestación de la enfermedad de Steinert. Revista Española de Cardiología 63:1, 112-114
    CrossRef

41. 41

    Guey-Shin Wang, Muge N. Kuyumcu-Martinez, Satyam Sarma, Nitin Mathur, Xander H.T. Wehrens, Thomas A. Cooper. (2009) PKC inhibition ameliorates the cardiac phenotype in a mouse model of myotonic dystrophy type 1. Journal of Clinical Investigation 119:12, 3797-3806
    CrossRef

42. 42

    JORDAN M. PRUTKIN, KRISTEN K. PATTON. (2009) Ventricular Tachycardia in a Patient with Inclusion-Body Myositis. Pacing and Clinical Electrophysiology 32:12, e36-e39
    CrossRef

43. 43

    Rachel Thompson, Benedikt Schoser, Darren G. Monckton, Karla Blonsky, Hanns Lochmüller. (2009) Patient Registries and Trial Readiness in Myotonic Dystrophy – TREAT-NMD/Marigold International Workshop Report. Neuromuscular Disorders 19:12, 860-866
    CrossRef

44. 44

    Richard F. Otten, John A. Scherschel, John C. Lopshire, Deepak Bhakta, Robert M. Pascuzzi, William J. Groh. (2009) Arrhythmia exacerbation after sodium channel blockade in myotonic dystrophy type 1. Muscle & Nerve 40:5, 901-902
    CrossRef

45. 45

    V. A. Sansone, G. De Ambroggi, A. Zanolini, M. Panzeri, F. Sardanelli, R. Cappato, G. Meola, L. De Ambroggi. (2009) Long-term follow-up free of ventricular fibrillation recurrence after resuscitated cardiac arrest in a myotonic dystrophy type 1 patient. Europace 11:9, 1243-1244
    CrossRef

46. 46

    B. Schoser, T. Grimm. (2009) Myotone Dystrophien – und ihre Differenzialdiagnosen. medizinische genetik 21:3, 381-392
    CrossRef

47. 47

    Neil E. I. Langlois. (2009) Sudden adult death. Forensic Science, Medicine, and Pathology 5:3, 210-232
    CrossRef

48. 48

    M. Tada, A. Kakita, Y. Toyoshima, O. Onodera, T. Ozawa, T. Morita, M. Nishizawa, H. Takahashi. (2009) Depletion of medullary serotonergic neurons in patients with multiple system atrophy who succumbed to sudden death. Brain 132:7, 1810-1819
    CrossRef

49. 49

    M.I. Miladi, H. Charfeddine, I. Feki, E. Turki, N. Elleuch, I. Trabelsi, S. Krichène, S. Kammoun, C. Mhiri. (2009) Les anomalies cardiaques au cours de la dystrophie myotonique de Steinert. La Revue de Médecine Interne 30:7, 573-577
    CrossRef

50. 50

    Gerard Piñol-Ripoll, Alexey Shatunov, Ana Cabello, Pilar Larrodé, Iris de la Puerta, Juana Pelegrín, Feliciano J. Ramos, Montse Olivé, Lev G. Goldfarb. (2009) Severe infantile-onset cardiomyopathy associated with a homozygous deletion in desmin. Neuromuscular Disorders 19:6, 418-422
    CrossRef

51. 51

    Federico Canavese, Michael D. Sussman. (2009) Orthopaedic Manifestations of Congenital Myotonic Dystrophy During Childhood and Adolescence. Journal of Pediatric Orthopaedics 29:2, 208-213
    CrossRef

52. 52

    Albert C Ludolph. (2009) Neuromuscular diseases: new hopes for alleviation and elimination. The Lancet Neurology 8:1, 16-17
    CrossRef

53. 53

    Antonio Dello Russo, Fortunato Mangiola, Paolo Della Bella, Giovanni Nigro, Paola Melacini, Maria Grazia Bongiorni, Claudio Tondo, Leonardo Calò, Loredana Messano, Manuela Pace, Gemma Pelargonio, Michela Casella, Tommaso Sanna, Gabriella Silvestri, Anna Modoni, Elisabetta Zachara, Massimo Moltrasio, Lucia Morandi, Gerardo Nigro, Luisa Politano, Alberto Palladino, Fulvio Bellocci. (2009) Risk of Arrhythmias in MYotonic Dystrophy: trial design of the RAMYD study. Journal of Cardiovascular Medicine 10:1, 51-58
    CrossRef

54. 54

    Hyun Kyung Park, Won Hyeong Park, Dae-Geun Song, Tae Gyoon Kim, Bo Young Min, Keun Lee, Joong-Il Park. (2009) Non-Ischemic Cardiomyopathy Attributed to Adult Myotonic Dystrophy. Korean Circulation Journal 39:8, 340
    CrossRef

55. 55

    Zachary Simmons. (2008) Whatʼs in the Literature?. Journal of Clinical Neuromuscular Disease 10:2, 70-75
    CrossRef

56. 56

    (2008) Sudden Death in Myotonic Dystrophy. New England Journal of Medicine 359:15, 1626-1629
    Full Text

57. 57

    KURT SAMSON. (2008) CARDIAC ARRHYTHMIAS BLAMED FOR MOST SUDDEN DEATHS IN MYOTONIC DYSTROPHY PATIENTS. Neurology Today 8:15, 1,5-7
    CrossRef

Letters