Long QT syndrome and associated gene mutation carriers in Japanese children: results from ECG screening examinations

2009 ◽  
Vol 117 (12) ◽  
pp. 415-424 ◽  
Author(s):  
Kenshi Hayashi ◽  
Noboru Fujino ◽  
Katsuharu Uchiyama ◽  
Hidekazu Ino ◽  
Kenji Sakata ◽  
...  
Keyword(s):  
Ion Channel ◽  
Long Qt Syndrome ◽  
High Probability ◽  
Dominant Negative ◽  
Carrier Status ◽  
Japanese Children ◽  
Long Qt ◽  
Mutation Carriers ◽  
Qt Intervals ◽  
Qt Syndrome

LQTS (long QT syndrome) is caused by mutations in cardiac ion channel genes; however, the prevalence of LQTS in the general population is not well known. In the present study, we prospectively estimated the prevalence of LQTS and analysed the associated mutation carriers in Japanese children. ECGs were recorded from 7961 Japanese school children (4044 males; mean age, 9.9±3.0 years). ECGs were examined again for children who had prolonged QTc (corrected QT) intervals in the initial ECGs, and their QT intervals were measured manually. An LQTS score was determined according to Schwartz's criteria, and ion channel genes were analysed. In vitro characterization of the identified mutants was performed by heterologous expression experiments. Three subjects were assigned to a high probability of LQTS (3.5≤ LQTS score), and eight subjects to an intermediate probability (1.0< LQTS score ≤3.0). Genetic analysis of these II subjects identified three KCNH2 mutations (M124T, 547–553 del GGCGGCG and 2311–2332 del/ins TC). In contrast, no mutations were identified in the 15 subjects with a low probability of LQTS. Electrophysiological studies showed that both the M124T and the 547–553 del GGCGGCG KCNH2 did not suppress the wild-type KCNH2 channel in a dominant-negative manner. These results demonstrate that, in a random sample of healthy Japanese children, the prevalence of a high probability of LQTS is 0.038% (three in 7961), and that LQTS mutation carriers can be identified in at least 0.038% (one in 2653). Furthermore, large-scale genetic studies will be needed to clarify the real prevalence of LQTS by gene-carrier status, as it may have been underestimated in the present study.

Abstract 14358: Treadmill Exercise Testing Improves Diagnostic Accuracy in Children With Concealed Congenital Long QT Syndrome

Circulation ◽  
2020 ◽  
Vol 142 (Suppl_3) ◽  
Author(s):  
Trisha Patel ◽  
Stanley Kamande ◽  
Elizabeth Jarosz ◽  
James Bost ◽  
Sridhar hanumanthaiah ◽  
...  
Keyword(s):  
Exercise Testing ◽  
Long Qt Syndrome ◽  
Stress Testing ◽  
Normal Population ◽  
Recovery Phase ◽  
Exercise Stress ◽  
Long Qt ◽  
Qt Intervals ◽  
Prolonged Qt ◽  
Qt Syndrome

Introduction: Resting electrocardiogram (ECG) identification of long QT syndrome (LQTS) has limitations. Uncertainty exists on how to classify patients with borderline prolonged QT intervals. We tested if exercise testing could help serve as a guide for which children with borderline prolonged QT intervals may be gene positive for LQTS. Methods: Pediatric patients (n=139) were divided into three groups: Controls (n=76), gene positive LQTS with borderline QTc (n=21), and gene negative patients with borderline QTc (n=42). Borderline QTc was defined between 440 to 470 (male) and 440 to 480 (female) msec. ECGs were recorded while supine, sitting, and standing. Patients then underwent treadmill stress testing using the Bruce protocol followed by a 9-minute recovery phase. Statistical analysis was completed to compare the QTc intervals amongst all three of the groups using t-test, ANOVA, and the Youden method to calculate sensitivity and specificity cut points. Results: Supine resting QTc, age, and Schwartz score for the three groups were: 1) Gene positive: 446 ± 23 msec, 12.4 ± 3.4 yo, 3.2 ± 1.8; 2) Gene negative: 445 ± 20 msec, 12.1 ± 2.8 yo, 2.0 ± 1.2; and 3) Control: 400 ± 24 msec, 15.0 ± 3 yo. The three groups could be differentiated by their QTc response at two time points: standing and recovery phase at six minutes. Standing QTc ≥ 460 msec differentiated borderline prolonged QTc patients (Gene positive and Gene negative) from controls with a specificity of 90% for gene positive versus control and 83% for gene negative versus control. A late recovery QTc ≥ 480 msec at minute six distinguished Gene positive from Gene negative patients with a specificity of >97%. Conclusions: Exercise stress testing can be useful to identify Gene positive borderline LQTS from a normal population and Gene negative borderline QTc patients, allowing for increased cost effectiveness by selectively gene testing a higher risk group of patients with borderline QTc intervals and intermediate Schwartz scores.

scholarly journals Epinephrine Bolus Test in Detecting Long QT Syndrome Mutation Carriers with Indeterminable Electrocardiographic Phenotype

2011 ◽  
Vol 16 (2) ◽  
pp. 172-179 ◽  
Author(s):  
Anna-Mari Hekkala ◽  
Heikki Swan ◽  
Matti Viitasalo ◽  
Heikki Väänänen ◽  
Lauri Toivonen
Keyword(s):  
Long Qt Syndrome ◽  
Long Qt ◽  
Mutation Carriers ◽  
Qt Syndrome

Denaturing High-Performance Liquid Chromatography Quickly and Reliably Detects Cardiac Ion Channel Mutations in Long QT Syndrome

2003 ◽  
Vol 7 (3) ◽  
pp. 249-253 ◽  
Author(s):  
Li Ning ◽  
Arthur Moss ◽  
Woject Zareba ◽  
Jennifer Robinson ◽  
Spencer Rosero ◽  
...  
Keyword(s):  
High Performance Liquid Chromatography ◽  
Liquid Chromatography ◽  
Ion Channel ◽  
Long Qt Syndrome ◽  
High Performance ◽  
Long Qt ◽  
Qt Syndrome

A Candidate Locus Approach Identifies a Long QT Syndrome Gene Mutation

2003 ◽  
Vol 5 (2) ◽  
pp. 97-104 ◽  
Author(s):  
Theresa A. Beery ◽  
Macaira Dyment ◽  
Kerry Shooner ◽  
Timothy K. Knilans ◽  
D. Woodrow Benson
Keyword(s):  
Potassium Channel ◽  
Long Qt Syndrome ◽  
Family Members ◽  
Torsades De Pointes ◽  
Sudden Onset ◽  
Coding Region ◽  
Long Qt ◽  
Candidate Locus ◽  
Qt Intervals ◽  
Qt Syndrome

Long QT syndrome is an inherited disorder that results in lengthened cardiac repolarization. It can lead to sudden onset of torsades de pointes, ventricular fibrillation, and death. The authors obtained a family history, performed electrocardiograms, and drew blood for DNA extraction and genotyping from 15 family members representing 4 generations of an affected family. Seven individuals demonstrated prolonged QT intervals. The authors used polymorphic short tandem repeat markers at known LQTS loci, which indicated linkage to chromosome 11p15.5 where the potassium channel, KCNQ1, is encoded. Polymerase chain reaction was used to amplify the coding region of KCNQ1. During survey of the KCNQ1 coding region, a G-to-A transition (G502A) was identified. DNA from all clinically affected but from none of the clinically unaffected family members carried the G-to-A transition. The candidate locus approach allowed an efficient mechanism to uncover the potassium channel mutation causing LQTS in this family.

Type 1 long QT syndrome and psychological stress in a laboratory setting

2018 ◽  
Vol 25 (9) ◽  
pp. 1213-1221 ◽  
Author(s):  
Ilmari Määttänen ◽  
Niklas Ravaja ◽  
Pentti Henttonen ◽  
Sampsa Puttonen ◽  
Kristian Paavonen ◽  
...  
Keyword(s):  
Stress Responses ◽  
Long Qt Syndrome ◽  
Mental Stress ◽  
Mental Arithmetic ◽  
Physiological Stress ◽  
Long Qt ◽  
Mutation Carriers ◽  
Asymptomatic Patients ◽  
Qt Syndrome

Trait-like sensitivity to stress in long QT syndrome patients has been documented previously. In addition, mental stress has been associated with symptomatic status of long QT syndrome. We examined whether the symptomatic type 1 long QT syndrome patients would be more sensitive to mental stress compared to asymptomatic patients and whether there would be differences in task-related physiological stress reactions between type 1 long QT syndrome patients and healthy individuals. The study population consisted of 21 symptomatic and 23 asymptomatic molecularly defined KCNQ1 mutation carriers, their 32 non-carrier relatives and 46 non-related healthy controls, with mean ages of 37, 39, 35 and 23 years, respectively. Electrocardiography was utilised to calculate inter-beat interval and high frequency and low frequency heart rate variability. Blood pressure was measured and mean arterial pressure and pulse pressure were calculated. Stress was induced using three different tasks: mental arithmetic, reaction time and public speech. Stress responses of symptomatic and asymptomatic type 1 long QT syndrome patients were not statistically different in any of the stress tasks. Short-term physiological stress reactivity of symptomatic type 1 long QT syndrome patients appears to be normal and does not enhance the risk assessment of asymptomatic mutation carriers.

Electrocardiogram screening of deaf children for long QT syndrome: are we following UK national guidelines?

2010 ◽  
Vol 125 (4) ◽  
pp. 354-356 ◽  
Author(s):  
S L Kang ◽  
C Jackson ◽  
W Kelsall
Keyword(s):  
Cochlear Implant ◽  
Long Qt Syndrome ◽  
Qt Interval ◽  
Deaf Children ◽  
National Guidelines ◽  
Long Qt ◽  
Local Practice ◽  
Qt Intervals ◽  
Centre Database ◽  
Qt Syndrome

AbstractIntroduction:Jervell–Lange-Nielsen syndrome is characterised by congenital deafness and a long QT interval on electrocardiography.Aim:(1) To survey UK national practice regarding electrocardiography screening of deaf children referred to cochlear implant centres, performed to evaluate for prolonged QT interval as recommended by national guidelines, and (2) to review local practice.Methods:Data were collected via a questionnaire sent to all UK cochlear implant centres, and via review of the medical records of a local cochlear implant centre database.Results:Eight (42 per cent) of the 19 cochlear implant centres surveyed performed electrocardiographic screening. Thirteen cases of long QT syndrome were reported in seven centres, with two related deaths. In our local cochlear implant centre, 14 (7.1 per cent) of 193 children had abnormal electrocardiograms; one definite long QT syndrome case and 13 borderline cases were identified.Conclusion:Despite clear national guidelines for electrocardiographic screening of deaf children, there is wide variation in practice. Our local practice of performing investigations, including electrocardiography, during magnetic resonance imaging sedation has been very successful. Electrocardiograms should be reviewed by trained clinicians, and corrected QT intervals should be calculated manually.

Sign in / Sign up

Export Citation Format

Share Document