The phenomenon of “QT stunning”: The abnormal QT prolongation provoked by standing persists even as the heart rate returns to normal in patients with long QT syndrome

In this work we present a one-dimensional (1D) mathematical model of the coronary circulation and use it to study the effects of arrhythmias on coronary blood flow (CBF). Hydrodynamical models are rarely used to study arrhythmias’ effects on CBF. Our model accounts for action potential duration, which updates the length of systole depending on the heart rate. It also includes dependency of stroke volume on heart rate, which is based on clinical data. We apply the new methodology to the computational evaluation of CBF during interventricular asynchrony due to cardiac pacing and some types of arrhythmias including tachycardia, bradycardia, long QT syndrome and premature ventricular contraction (bigeminy, trigeminy, quadrigeminy). We find that CBF can be significantly affected by arrhythmias. CBF at rest (60 bpm) is 26% lower in LCA and 22% lower in RCA for long QT syndrome. During bigeminy, trigeminy and quadrigeminy, respectively, CBF decreases by 28%, 19% and 14% with respect to a healthy case.

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A SCN5A mutation caused ST elevation, transient QT prolongation and sudden death: An atypical phenotype of Brugada-long QT syndrome?

Heart Rhythm ◽

10.1016/j.hrthm.2005.02.833 ◽

2005 ◽

Vol 2 (5) ◽

pp. S265

Author(s):

Li Zhang ◽

Tiehua Chen ◽

Michael Sheets ◽

Robert L. Lux ◽

Michael S. Schaffer ◽

...

Keyword(s):

Sudden Death ◽

Long Qt Syndrome ◽

Qt Prolongation ◽

Long Qt ◽

St Elevation ◽

Qt Syndrome ◽

Atypical Phenotype ◽

Scn5a Mutation

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Endocrinopathies mimicking gene negative long QT syndrome

Cardiology in the Young ◽

10.1017/s1047951121004388 ◽

2021 ◽

pp. 1-3

Author(s):

Praloy Chakraborty ◽

Jason D. Roberts ◽

Michael H. Gollob

Keyword(s):

Genetic Testing ◽

Long Qt Syndrome ◽

Qt Prolongation ◽

Long Qt ◽

Ventricular Repolarisation ◽

Qt Syndrome ◽

Hormonal Milieu

Abstract Ventricular repolarisation can be influenced by hormonal milieu which may mimic long QT syndrome. We describe a series of patients referred for genetic testing for diagnosed long QT syndrome where a detailed clinical workup demonstrated endocrinopathies as the cause of presumed “gene negative” long QT syndrome and QT prolongation.

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Abstract 4669: Does Long-QT Syndrome Involve the Sinus Node?

Circulation ◽

10.1161/circ.118.suppl_18.s_928-b ◽

2008 ◽

Vol 118 (suppl_18) ◽

Author(s):

Vladimir Shusterman ◽

Jan Nemec ◽

Marie Buncova ◽

Bruce Winter ◽

Win-Kuang Shen ◽

...

Keyword(s):

Heart Rate ◽

Long Qt Syndrome ◽

High Frequency ◽

Cardiac Rhythm ◽

Sinus Node ◽

List Type ◽

High Frequency Power ◽

Long Qt ◽

Qt Syndrome ◽

Frequency Power

Background: The hallmark of Long QT Syndrome (LQTS) is a prolongation of the ventricular electrical action potential caused by mutations involving key cardiac ion channels on the surface membrane of ventricular myocytes. Different mutations are associated with specific modes of arrhythmia initiation and distinct changes in cardiac rhythm prior to these events. We hypothesized that some LQTS-causing mutations might involve the sinus node, leading to aberrations in cardiac rhythm. To test this hypothesis, we examined the features of cardiac rhythm in 23 genotyped patients with LQTS and 14 matched controls (C) using Holter ECG data (6hrs). Methods: QRS-complexes were identified using custom software and verified by an experienced ECG reader; series of sinus beats were extracted and gaps in time series were linearly interpolated. The mean, max, and min heart rate (HR), the time (SD, SDNN, SDANN, RMSSD, pNN50) and frequency-domain (Total (TP), Very low (VLF), Low (LF), High (HF) frequency powers, and LF/HF) indices of heart rate variability (HRV) were calculated in each 5-min interval and over the entire recording. The short-long-short irregularity was examined using the novel multiscale rhythmogenetic analysis (MRA), which quantifies changes in the HRV indices during the transition from one time-scale window to another. Results: The maximum heart rate was slower in LQTS than in C (101±13 and 119±19bpm, p=0.001). The high-frequency power (HF) was lower in LQTS than in C (80±76 and 113±58ms 2 , p<0.05). However, the short-term irregularity (quantified by the difference in RMSSD between the 75ms and 2000ms time scales) was 4 times greater in LQTS compared to C (p=0.003). Inclusion or exclusion of two patents who were on β-blockers did not change the results. Conclusions: LQTS is associated with specific changes in cardiac rhythm, including: diminished acceleration capacity, decreased high-frequency power, and enhanced short-long-short irregularity. This suggests that LQTS involves channel modifications in the sinus node, which might contribute to arrhythmogenesis. Rhythm characterization in genetic sub-types of LQTS might improve arrhythmia risk stratification in this heterogeneous patient population.

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