Markers of ventricular repolarization as an additional non-invasive electrocardiography parameters for predicting ventricular tachycardia/fibrillation in patients with Brugada Syndrome – A systematic review and meta-analysis

BackgroundControversies surrounded the management of asymptomatic Brugada syndrome. Prognostication using electrophysiology study (EPS) is disputable. Non-invasive parameters may be a valuable additional tool for risk stratification. We aim to evaluate the use markers of ventricular repolarization including Tpeak-to-Tend (TpTe), Tpe Dispersion, TpTe/QT ratio, and QTc interval as additional non-invasive electrocardiography parameters for predicting ventricular tachycardia/fibrillation in patients with Brugada syndrome.MethodsWe performed a comprehensive search on TpTe, Tpe Dispersion, TpTe/QT ratio, and QTc interval as a predictor for ventricular tachycardia(VT)/fibrillation(VF)/aborted sudden cardiac death/appropriate ICD shock in patients with Brugada syndromes up until October 2018.ResultsWe included ten studies in the qualitative synthesis and eight studies in meta-analysis. There were a total of 2126 subjects from ten studies. We found that TpTe interval (mean difference 11.97 m s [5.02–18.91]; p < 0.001; I² 80% possibly on ≥80–100 m s and maximum QTc interval (mean difference 11.42 m s [5.90–16.93], p < 0.001; I² 28%) were the most potential ECG parameters to predict VT/VF/AT/SCD. Tpe dispersion and TpTe/QT ratio have a high heterogeneity. Upon sensitivity analysis, there is no single study found to markedly affect heterogeneity of Tpe dispersion and TpTe/QT ratio. Removal of a study reduced maximum QTc interval heterogeneity to 0%.ConclusionsMeasurement of TpTe interval, Tp-e dispersion, TpTe/QT ratio, and QTc interval on ECG emerge as a promising prognostication tool which needs further investigations with a more standardized method, outcome, and cut-off points. As for now, only maximum QTc interval has a reliable result with low heterogeneity sufficiently reliable for prognostication.     

A 24-HOUR AMBULATORY ECG MONITORING IN ASSESSMENT OF QT INTERVAL DURATION AND DISPERSION IN ROWERS WITH PHYSIOLOGICAL MYOCARDIAL HYPERTROPHY

Myocardial hypertrophy (MH) due to cardiac pathology is characterized by an increase in QT interval duration and dispersion, while the findings for exercise-induced myocardial hypertrophy are contradictory. The majority of published research findings have not explored this relationship, but there have only been a few conducted studies using 24-hour ECG monitoring. The aim of the study was to determine the QT interval duration and dispersion in short-term and 24-hour ECG in endurance athletes with myocardial hypertrophy and without it. Methods: A total of 26 well-trained rowers underwent a resting 12-lead ECG, 24-hour ECG monitoring and echocardiography. Results: Athletes with MH (n = 7) at rest did not show any increase in QTc interval duration and dispersion, or mean and maximal QTc duration in Holter monitoring compared to athletes without MH (n = 19). Left ventricular mass was not significantly correlated with any QTc characteristics. Furthermore, athletes with MH had significantly longer mean QT (P = 0.01) and maximal QT (P = 0.018) intervals in Holter monitoring and higher 24-hour heart rate variability indexes due to stronger vagal effects. Conclusions: The present study demonstrated that athlete''s heart syndrome with myocardial hypertrophy as a benign phenomenon does not lead to an increase in QT interval duration, or increases in maximal and mean duration in a 24-hour ECG. An increase in QT interval duration in athletes may have an autonomic nature.     

Prolonged ventricular repolarization measured by corrected QT interval (QTc) in subclinical hyperthyroidism.

Overt hyperthyroidism and hypothyroidism exert a major effect on cardiac function and on ECG. The influence of subclinical hyperthyroidism on the circulatory system is still under debate. Few studies examined the effect of thyroid hormones on ventricular repolarization measured by corrected QT interval (QTc). Longer QTc is associated with increased risk of arrhythmia and cardiac mortality. The aim of this study was to examine the influence of subclinical hyperthyroidism on ventricular repolarization measured by corrected QTc in a standard 12-lead electrocardiogram. The examined group consisted of thirty-two patients with subclinical hyperthyroidism; the controls were thirty-nine healthy individuals. In the group with subclinical hyperthyroidism, we observed a significant increase in heart rate (80.3 +/- 10.59 vs. 73.7 +/- 11.37 bpm, p < 0.05). The mean corrected QTc was 0.434 +/- 0.0207 seconds and 0.414 +/- 0.0208 in the examined groups and in controls, respectively (p < 0.001). QTc did not correlate with free thyroxin concentrations (p = 0.5084). Conclusion: Corrected QT intervals were significantly longer in patients with subclinical hyperthyroidism.     

Comparison and recalculation of the very different QTc interval durations in young healthy women

The aim was to use some simple way for easier comparison, other expression or recalculation of the QTc duration from one formula to another in order to remove the large QTc differences.Methods and Results: The QT interval duration in 138 young healthy women was taken from our archive. The measured QT interval was corrected for heart rate (QTc) according to nine published regression equations (Bazett, Fridericia, Hodges, Sarma, Lecocq, Rautaharju, Sagie=Framingham, Arrowood, Malik) and compared mathematically by the Pearson correlation coefficient R and graphically by linear correlation.Correlation between two different QTc durations can be of three kinds: small (e.g. Bazett's versus Malik's formulas, R=0.0525, p=0.5405, the QTc values are much dispersed in the graph), larger (Malik's versus Sarma's formulas, R=0.939, p<0.01, the values are less dispersed), and identical (the Rautaharju's versus Arrowood's formulas, R=1.000, p<0.01, all QTc points are situated on one line). The linear correlation QTc1 = a+b·QTc2 enables recalculation from one QTc formula into another, if necessary.In conclusion, the QTc interval durations are differently long according to the QTc formula used. The correlations with the large Pearson R coefficient indicate the QTc pairs inappropriate for recalculation, the small R values indicate the appropriate pairs for recalculation.     

QRS、QT、QTc及LVEF预测心源性猝死的价值分析

摘要 目的：探讨QRS时限值（QRS）、QT间期延长（QT）、QTc间期（QTc）及左室射血分数（LVEF）预测心源性猝死的价值分析。方法：选择2018年1月至2019年12月川北医学院附属医院心血管内科治疗的356例心源性猝死患者进行研究,设为病例组,并选择同期体检的健康人200例作为对照组,分析QRS、QT、QTc及LVEF水平变化情况及其预测价值。结果：病例组QRS、QTc水平显著高于对照组,QT、LVEF水平显著低于对照组,差异显著（P＜0.05）;轻度QRS、QTc显著低于中度、重度患者,QT、LVEF水平显著高于中度、重度患者;中度患者QRS、QTc显著低于重度患者,QT、LVEF水平显著高于重度患者,差异显著（P＜0.05）;ROC结果显示,QRS预测心源性猝死的AUC为0.989,灵敏度△为84.59%,特异度为87.68%,截断值为115.59ms;QT预测心源性猝死的AUC为0.944,灵敏度85.12%,特异度为88.45%,截断值为21.69ms;QTc预测心源性猝死的AUC为0.984,灵敏度为86.05%,特异度为88.61%,截断值为416.39ms,LVEF预测心源性猝死的AUC为0.997,灵敏度87.15%,特异度为89.05%,截断值为45.63%,（P＜0.05）。结论：QRS、QT、QTc及LVEF在心源性猝死患者中检查,可显著提高心源性猝死临床诊断效能。     

The Myth of QT Shortening by Weight Loss and Physical Training in Obese Subjects With Coronary Heart Disease

This study aims to describe the changes that a period of low‐calorie diet and physical training determines in heart rate and in corrected QT (QTc) interval in obese patients with coronary heart disease (CHD) and to verify whether it is effective in shortening the QT interval using three different methods for QT correction. Two hundred and seventy obese white patients (162 males—60%) affected with stable CHD and treated with β‐blockers were retrospectively studied in the setting of a program aimed at losing weight through training (aerobic activity + strength exercise) and diet (80% of estimated resting energy expenditure). Age was related to RR interval, QTc was related to left ventricular ejection fraction (EF) while sex exerted no effects. At the end of the study period heart rate decreased by 8.3% and noncorrected QT increased by 3.0%; QT corrected with the Bazett formula decreased by 0.7% (P = 0.007), QT corrected with the Fridericia formula increased by 0.5% (P = 0.023), whereas the modifications were nonsignificant when the Framingham correction was used. In conclusion, contrary to the current views, physical training and diet, which are effective in reducing heart rate, produced no clinically relevant change in the QT interval.     

Issues in QT interval measurement

The QT interval, apart from clinical implications is crucial for safety assessment of new drugs under development. A QTc prolongation of even 10 msec in a study group is a warning signal for a new drug. There are various issues involved in the measurement of the QT interval especially regarding the ending of the T wave and different morphological pattern of T-U complex. The other issue is significant spontaneous variability in the QT interval, resulting in spurious QT prolongation and unnecessary concern.To minimize all these confounding factors, all clinical trials for assessing QT interval prolongation should be randomized and double blinded with appropriate control groups including placebo. ECG measurements should be done by trained readers with electronic calipers at ECG core Lab. ECGs should be compared with multiple baseline values with multiple, time-matched on-treatment values.     

QTc Interval (Cardiac Repolarization): Lengthening After Meals

NAGY, DAVID, RONALD DeMEERSMAN, DYMPNA GALLAGHER, ANGELO PIETROBELLI, ADRIENNE S ZION, DEBORAH DALY, STEVEN B HEYMSFIELD. QTc interval (cardiac repolarization): lengthening after meals. Weight reduction, either by dietary or surgical means, is associated with prolongation of the heart rate corrected QT interval (QTc=QT/R-R^0–5 and, on occasion, sudden death. Screening subjects with obesity before weight loss for prolonged QTc intervals is an accepted practice, although at present, there are no guidelines for whether subjects should be fasting before electrocardiogram (EKG) evaluation. The aim of this study was to test the hypothesis that EKG QTc interval duration is independent of meal ingestion. The hypothesis was tested in 11 healthy subjects who ingested a 500-kcal formula meal. A small decrease in absolute QT interval and a steady decline in R-R interval were observed for up to 60 minutes after formula ingestion. The QTc interval increased above baseline at 15 minutes (p<0. 007) after meal, a change that persisted for the 1-hour postmeal observation period. Spectral analysis of EKG R-R intervals (low-/high-frequency amplitude ratio) indicated a change in cardiac autonomic flow after meal ingestion. The QTc interval did not lengthen and R-R low-/highfrequency amplitude ratio remained unchanged in eight subjects evaluated in a similar manner but in whom isovolumic amounts of water replaced the meal. These observations suggest that (1) cardiac repolarization changes with fasting and feeding, (2) the QTc interval is influenced by meal intake, and (3) the autonomic nervous system may play a role in meal-related QTc changes. These findings have implications for the evaluation of patients with obesity before starting and during weight loss treatment.     

Antipsychotic Dose Mediates the Association between Polypharmacy and Corrected QT Interval

Antipsychotic (AP) drugs have the potential to cause prolongation of the QT interval corrected for heart rate (QTc). As this risk is dose-dependent, it may be associated with the number of AP drugs concurrently prescribed, which is known to be associated with increased cumulative equivalent AP dosage. This study analysed whether AP dose mediates the relationship between polypharmacy and QTc interval. We used data from a cross-sectional survey that investigated the prevalence of QTc lengthening among people with psychiatric illnesses in Italy. AP polypharmacy was tested for evidence of association with AP dose and QTc interval using the Baron and Kenny mediational model. A total of 725 patients were included in this analysis. Of these, 186 (26%) were treated with two or more AP drugs (AP polypharmacy). The mean cumulative AP dose was significantly higher in those receiving AP polypharmacy (prescribed daily dose/defined daily dose = 2.93, standard deviation 1.31) than monotherapy (prescribed daily dose/defined daily dose = 0.82, standard deviation 0.77) (z = −12.62, p < 0.001). Similarly, the mean QTc interval was significantly longer in those receiving AP polypharmacy (mean = 420.86 milliseconds, standard deviation 27.16) than monotherapy (mean = 413.42 milliseconds, standard deviation 31.54) (z = −2.70, p = 0.006). The Baron and Kenny mediational analysis showed that, after adjustment for confounding variables, AP dose mediates the association between polypharmacy and QTc interval. The present study found that AP polypharmacy is associated with QTc interval, and this effect is mediated by AP dose. Given the high prevalence of AP polypharmacy in real-world clinical practice, clinicians should consider not only the myriad risk factors for QTc prolongation in their patients, but also that adding a second AP drug may further increase risk as compared with monotherapy.     

Quantitative relationship between plasma potassium levels and QT interval in beagle dogs

The aim of the current study was to establish the quantitative relationship between plasma potassium concentrations and the QT interval of the electrocardiogram in dogs. Furosemide, a potent diuretic, was given at increasing doses (5-60 mg/kg) to five male and five female beagle dogs. Electrocardiogram (ECG) was recorded three times each day, simultaneous to blood sampling for measurement of plasma potassium. Furosemide treatment produced a clear hypokalaemia, which was associated with an increase in QT and corrected QT intervals (QTc) duration. On average, the slopes of the negative linear correlation between potassium plasma levels and QT or QTc were steeper in females than in males. These results show that a decrease in potassium plasma level may explain a concomitant increase in QT duration in a toxicity study in dogs, in particular if potassium values are decreased below 3.3 mmol/L. Correction of QT interval for K+ plasma level has, therefore, been established separately for males and females. A global formula correcting QT for K+ and heart rate simultaneously was established. Hypokalaemia was also associated with changes in the morphology of the T wave recorded in CV5RL, in particular, with a flattening and/or a notching of the wave (appearance of a second peak), biphasic aspect or inversion of polarity. These changes are probably related to an increased heterogeneity of repolarization between different populations of cardiomyocytes. In conclusion, hypokalaemia is quantitatively associated with an increase in QT and QTc duration in dogs. The relationship is apparently stronger for females than for males. A formula may be used to correct QT for potassium plasma level.     

The congenital long QT syndrome Type 3: An update

Congenital long QT syndrome type 3 (LQT3) is the third in frequency compared to the 15 forms known currently of congenital long QT syndrome (LQTS). Cardiac events are less frequent in LQT3 when compared with LQT1 and LQT2, but more likely to be lethal; the likelihood of dying during a cardiac event is 20% in families with an LQT3 mutation and 4% with either an LQT1 or an LQT2 mutation. LQT3 is consequence of mutation of gene SCN5A which codes for the Nav1.5 Na⁺ channel α-subunit and electrocardiographically characterized by a tendency to bradycardia related to age, prolonged QT/QTc interval (mean QTc value 478 ± 52 ms), accentuated QT dispersion consequence of prolonged ST segment, late onset of T wave and frequent prominent U wave because of longer repolarization of the M cell across left ventricular wall.     

海葵毒素对心肌钠通道开放模式，动作电位及心电图QT周期的影响

应用膜片箝技术记录游离豚鼠心肌细胞的钠通道电流,细胞内微电极技术记录心室乳头肌的动作电位和心电图机记录豚鼠的心电图,使用与心肌;细胞钠通道有高度亲和力的海葵毒素（sea anemone toxin,ATXⅡ）改变钠通道开放的动力过程,从三个水平来研究钠通道,动作电位,心电图变化的关系,并试图探讨长QT综合征（long QT syndrome,LQTs)的发病机制,结果显示,ATXⅡ使钠通道的开放频率增加,钠通道中“长时间开放模式”的开放时间常数增大,动人电位的持续时间APD50和APD50也分别增加了23％和27％,ATXⅡ使动物心电图QT间期延长18．6％,QTc(校正的QT间期）增大18．9％,这些结果提示,钠通道动力过程的变化对动作电位和心电图QT间期有重要影响,钠通道功能或结构的变异可能是临床上部分长QT综合征产生的原因。     

Prolongation of the QT interval and post-extrasystolic augmentation of the TU-wave during emotional stress

We present a case of a 25-year-old woman with multiple blackouts and no structural heart disease, with abnormal T-U waves and borderline QT interval on her resting electrocardiogram. During emotional stress she developed frequent monomorphic ventricular premature beats, with characteristic changes of the sinus complexes immediately following the premature beats, namely augmentation and greater degree of merging of the T and U waves and QTc interval prolongation. The changes alert about the possibility of congenital long QT syndrome, specifically genotype 2 or 1.     

Effect of L- Arginine On Electrocardiographic Changes Induced By Hypercholesterolemia And Isoproterenol In Rabbits

Hypercholesterolemia, a well-known cardiovascular risk factor, is associated with prolonged action potential duration, longer QTc intervals (rate controlled QT interval), suggested that Hypercholesterolemia may have a direct effect on ventricular repolarization. Hypercholesterolemia was induced in rabbits and L-arginine was given orally to animals for sixteen weeks. The isoproterenol was injected in all the animals to produce electrocardiographic changes. ECG was recorded in lead II at start of study, after hypercholesterolemic diet and/ or L-arginine supplementation. It is observed that L-arginine significantly reduced the hypercholesterolemia induced QTc prolongation. Isoproterenol induced increase in QTc intervals were decreased only in normolipidemic animals. No significant changes were observed in QRS complex and heart rate. Our study suggests that L-arginine definitely have effect on repolarization processes of myocardium.     

QT interval and QT dispersion before and after diet therapy in patients with simple obesity

To evaluate whether a disordered QT interval and its dispersion in obese patients, if any, may be improved by therapeutic weight reduction, 36 obese patients admitted to our university hospital were examined over a 5-year period from April 1, 1992 to March 31, 1997. Participants included 18 males and 18 females whose mean age +/- SD was 28 +/- 9 and 33 +/- 14 years, respectively, and whose mean body mass index +/- SD was 35 +/- 5 and 38 +/- 6 kg/m2, respectively. Thirty-six control patients were matched in age and gender with the obese patients. All the obese patients were treated with behavioral therapy together with very-low-calorie conventional Japanese diet (VLCD: 370 kcal/day). A standard 12-lead electrocardiogram (ECG) revealed longer maximum (445 +/- 32 msec, mean +/- SD) and minimum (388 +/- 29 msec) heart rate corrected QT intervals (QTc intervals) in the obese group than in the control group (P < 0.0001 for each). QTc dispersion, defined as the difference between maximum and minimum QTc intervals derived from 12-lead ECG, was greater in the obese group (57 +/- 19 msec) than in the control group (32 +/- 13 msec) (P < 0.0001). Both the maximum and minimum QTc intervals in the obese patients were shortened, respectively, to 434 +/- 28 msec and 377 +/- 29 msec (P < 0.05 for each) with no significant change in either QTc dispersion, QRS voltage, or QRS duration following weight reduction. The coefficient value from the linear regression line between QT interval and RR interval in the obese group was less than in the control group. Together, the results show that obesity per se causes both a prolongation of QTc interval and an increase in QTc dispersion, and that weight reduction improves the prolonged QTc interval observed in obese patients.     

海葵毒素对心肌钠通道开放模式、动作电位及心电图QT间期的影响

应用膜片箝技术记录游离豚鼠心肌细胞钠通道电流, 细胞内微电极技术记录心室乳头肌的动作电位和心电图机记录豚鼠的心电图。使用与心肌细胞钠通道有高度亲和力的海葵毒素(sea anemone toxin, ATXⅡ)改变钠通道开放的动力过程, 从三个水平来研究钠通道、动作电位、心电图变化的关系, 并试图探讨长QT综合征(long QT syndrome, LQTs)的发病机制。结果显示: ATXⅡ使钠通道的开放频率增加, 钠通道中“长时间开放模式”的开放时间常数增大, 动作电位的持续时间APD50和APD90也分别增加了23%和27%。 ATXⅡ使动物心电图QT间期延长18.6%, QTc (校正的QT间期)增大18.9%。这些结果提示, 钠通道动力过程的变化对动作电位和心电图QT间期有重要影响, 钠通道功能或结构的变异可能是临床上部分长QT综合征产生的原因。     

High Prevalence of Prolonged QT Interval in Obese Hypogonadal Males

Obese subjects show several electrocardiographic alterations, including prolonged QT interval, a marker for fatal cardiac arrhythmias. Prolonged QT interval has recently been linked to low testosterone levels, a frequent occurrence in male obese patients but no study has yet assessed whether hypoandrogenism contributes to QT interval prolongation in this population. Aim of this study was to evaluate whether prolonged QT interval is linked to hypogonadism in male obese subjects. QT interval corrected for heart rate (QTc) was measured from standard electrocardiogram recordings in 136 obese men (BMI 30 >kg/m², range 30.1–75.4 kg/m²). Obese men were classified as eugonadal or hypogonadal according to serum total testosterone levels (i.e., greater or less than 9.9 nmol/l). Our study showed that QTc measurements corrected by either Bazett (419 ± 3.2 vs. 408 ± 3.4 ms, P < 0.05), Fridericia (406.3 ± 3.39 vs. 396.4 ± 3.03 ms, P < 0.05) or Hodges (407.0 ± 3.12 vs. 397.3 ± 2.84 ms, P < 0.05) were longer in hypogonadal compared with eugonadal obese men; further, prolonged QTc interval (i.e., >440 ms) was more frequent among hypogonadal compared with eugonadal obese men (23% vs. 10%, P < 0.05). The degree of weight excess, diabetes, sleep apnoea and potassium levels were not associated with prolonged QTc. In conclusion, obese hypogonadal men show a greater prevalence of prolonged QT interval compared with their eugonadal counterparts. It appears therefore that low levels of testosterone in obese men may contribute to the arrhythmogenic profile of these patients, a heretofore unknown link which warrants further clinical attention.     

Fever-triggered ventricular arrhythmias in Brugada syndrome and type 2 long-QT syndrome

The risk for lethal ventricular arrhythmias is increased in individuals who carry mutations in genes that encode cardiac ion channels. Loss-of-function mutations in SCN5A, the gene encoding the cardiac sodium channel, are linked to Brugada syndrome (BrS). Arrhythmias in BrS are often preceded by coved-type ST-segment elevation in the right-precordial leads V1 and V2. Loss-of-function mutations in KCNH2, the gene encoding the cardiac ion channel that is responsible for the rapidly activating delayed rectifying potassium current, are linked to long-QT syndrome type 2 (LQT-2). LQT-2 is characterised by delayed cardiac repolarisation and rate-corrected QT interval (QTc) prolongation. Here, we report that the risk for ventricular arrhythmias in BrS and LQT-2 is further increased during fever. Moreover, we demonstrate that fever may aggravate coved-type ST-segment elevation in BrS, and cause QTc lengthening in LQT-2. Finally, we describe molecular mechanisms that may underlie the proarrhythmic effects of fever in BrS and LQT-2. (Neth Heart J 2010;18:165-9.)     

Effect Of Different Doses Of Noradrenaline Against Ischemia-induced Ventricular Arrhythmias In Rat Heart In Vivo

Background

The present study was designed to evaluate the preconditioning effect of different doses of noradrenaline on ischemia-induced ventricular arrhythmias in open chest anesthetized rats.

Methods

The anaesthetized rats were subjected to 25 min of regional ischemia by left descending coronary artery (LAD) occlusion. In sham group, surgical procedures were done but ischemia was not applied. In control rats, saline was injected prior to ischemia. In noradrenaline groups, rats pretreated with three different doses of noradrenaline (respectively, 0.5, 1 and 2 μg/kg, IV).

Results

In control rats, induction of ischemia shortened the QTc (corrected QT) interval (ms) and led to occurrence of ventricular arrhythmias. Administration of low-dose of noradrenaline prevented shortening of the QTc interval during ischemia but could not significantly attenuate severity and incidences of arrhythmias. Injection of mid-dose of noradrenaline stabilized the QTc during ischemia and reduced severity of arrhythmias. Pretreatment with high-dose of noradrenaline significantly prolonged the QTc interval and declined severity and incidence of arrhythmias.

Conclusions

Noradrenaline dose-dependently attenuated ischemia-induced ventricular arrhythmias.     

Buprenorphine as a safe alternative to methadone in a patient with acquired long QT syndrome: a case report

A 52-year-old man with a medical history of intravenous drug abuse was admitted to our hospital with syncope due to torsades de pointes (TdP). Two days earlier, he had used methadone. The electrocardiogram showed a prolonged corrected QT interval (QTc) of 600 ms. Continuous telemetry observation showed multiple episodes of TdP. The patient was diagnosed with bradyarrhythmia-induced TdP with acquired long QT syndrome resulting from methadone use. The QTc normalised within 2 weeks after discontinuation of the methadone. In this case of a patient with opioid dependency, there is a reasonable risk of repeated methadone use. Therefore, implantable cardioverter defibrillator or pacemaker implantation is justified but risky because of possible infections when using intravenous drugs. Given the high mortality rates seen in untreated illicit opioid users, this patient needs an alternative pharmacological treatment. Buprenorphine is an opiate-receptor agonist associated with less QTc prolongation. The patient was referred to a rehab clinic and treated with an oral combination of buprenorphine and naloxone (Suboxone). During this therapy, his QTc remained normal.