Ohad Ziv

Mechanisms of cardiac arrhythmias and sudden death in transgenic rabbits with long QT syndrome

Long QT syndrome (LQTS) is a heritable disease associated with ECG QT interval prolongation, ventricular tachycardia, and sudden cardiac death in young patients. Among genotyped individuals, mutations in genes encoding repolarizing K+ channels (LQT1:KCNQ1; LQT2:KCNH2) are present in approximately 90% of affected individuals. Expression of pore mutants of the human genes KCNQ1 (KvLQT1-Y315S) and KCNH2 (HERG-G628S) in the rabbit heart produced transgenic rabbits with a long QT phenotype. Prolongations of QT intervals and action potential durations were due to the elimination of IKs and IKr currents in cardiomyocytes. LQT2 rabbits showed a high incidence of spontaneous sudden cardiac death (>50% at 1 year) due to polymorphic ventricular tachycardia. Optical mapping revealed increased spatial dispersion of repolarization underlying the arrhythmias. Both transgenes caused downregulation of the remaining complementary IKr and IKs without affecting the steady state levels of the native polypeptides. Thus, the elimination of 1 repolarizing current was associated with downregulation of the reciprocal repolarizing current rather than with the compensatory upregulation observed previously in LQTS mouse models. This suggests that mutant KvLQT1 and HERG interacted with the reciprocal wild-type alpha subunits of rabbit ERG and KvLQT1, respectively. These results have implications for understanding the nature and heterogeneity of cardiac arrhythmias and sudden cardiac death.

Estradiol promotes sudden cardiac death in transgenic long QT type 2 rabbits while progesterone is protective

BACKGROUND Postpubertal women with inherited long QT syndrome type 2 (LQT2) are at increased risk for polymorphic ventricular tachycardia (pVT) and sudden cardiac death (SCD), particularly during the postpartum period. OBJECTIVE To investigate whether sex hormones directly modulate the arrhythmogenic risk in LQTS. METHODS Prepubertal ovariectomized transgenic LQT2 rabbits were treated with estradiol (EST), progesterone (PROG), dihydrotestosterone (DHT), or placebo (OVX). RESULTS During 8 weeks of treatment, major cardiac events-spontaneous pVT or SCD-occurred in 5 of the 7 EST rabbits and in 2 of the 9 OVX rabbits (P <.05); in contrast, no events occurred in 9 PROG rabbits and 6 DHT rabbits (P <.01 vs PROG; P <.05 vs DHT). Moreover, EST increased the incidence of pVT (P <.05 vs OVX), while PROG reduced premature ventricular contractions, bigeminy, couplets, triplets, and pVT (P <.01 vs OVX; P <.001 vs EST). In vivo electrocardiographic monitoring, in vivo electrophysiological studies, and ex vivo optical mapping studies revealed that EST promoted SCD by steepening the QT/RR slope (P <.05), by prolonging cardiac refractoriness (P <.05), and by altering the spatial pattern of action potential duration dispersion. Isoproterenol-induced Ca(2+) oscillations resulted in early afterdepolarizations in EST-treated hearts (4 of 4), while PROG prevented SCD by eliminating this early afterdepolarization formation in 4 of the 7 hearts (P = .058 vs EST; P <.05 vs OVX). Analyses of ion currents demonstrated that EST increased the density of I(Ca,L) as compared with OVX (P <.05) while PROG decreased it (P <.05). CONCLUSION This study reveals the proarrhythmic effect of EST and the antiarrhythmic effect of PROG in LQT2 in vivo, outlining a new potential antiarrhythmic therapy for LQTS.

Differential conditions for early after‐depolarizations and triggered activity in cardiomyocytes derived from transgenic LQT1 and LQT2 rabbits

Non‐technical summary  Long QT syndrome (LQTS) is a genetic disorder characterized by recurrent syncope and sudden cardiac death (SCD). Type 1 (LQT1) and Type 2 (LQT2) LQTS account for 90% of the genotyped mutations in patients with this disorder. These syndromes have been associated with different sympathetic modes for initiation of cardiac arrest. Using isolated cardiomyocytes and Langendorff‐perfused hearts from transgenic rabbit models of LQT1 and LQT2, we have identified differential conditions and cellular mechanisms for the generation of early afterdepolarizations (EADs), abnormal depolarizations during the plateau and repolarization phase of action potentials and the hallmark of the arrhythmias in LQTS. These differences explain why different types of increased autonomic nervous system activity, i.e. sympathetic surge vs. high sympathetic tone, are associated with the initiation of polymorphic ventricular tachycardia in LQTS patients with different genetic background.

Origin of complex behaviour of spatially discordant alternans in a transgenic rabbit model of type 2 long QT syndrome

Enhanced dispersion of repolarization has been proposed as an important mechanism in long QT related arrhythmias. Dispersion can be dynamic and can be augmented with the occurrence of spatially out‐of‐phase action potential duration (APD) alternans (discordant alternans; DA). We investigated the role of tissue heterogeneity in generating DA using a novel transgenic rabbit model of type 2 long QT syndrome (LQT2). Littermate control (LMC) and LQT2 rabbit hearts (n= 5 for each) were retrogradely perfused and action potentials were mapped from the epicardial surface using di‐4‐ANEPPS and a high speed CMOS camera. Spatial dispersion (ΔAPD and Δslope of APD restitution) were both increased in LQT2 compared to LMC (ΔAPD: 34 ± 7 ms vs. 23 ± 6 ms; Δslope:1.14 ± 0.23 vs. 0.59 ± 0.19). Onset of DA under a ramp stimulation protocol was seen at longer pacing cycle length (CL) in LQT2 compared to LMC hearts (206 ± 24 ms vs. 156 ± 5 ms). Nodal lines between regions with APD alternans out of phase from each other were correlated with conduction velocity (CV) alternation in LMC but not in LQT2 hearts. In LQT2 hearts, larger APD dispersion was associated with onset of DA at longer pacing CL. At shorter CLs, closer to ventricular fibrillation induction (VF), nodal lines in LQT2 (n= 2 out of 5) showed persistent complex beat‐to‐beat changes in nodal line formation of DA associated with competing contribution from CV restitution and tissue spatial heterogeneity, increasing vulnerability to conduction block. In conclusion, tissue heterogeneity plays a significant role in providing substrate for ventricular arrhythmia in LQT2 rabbits by facilitating DA onset and contributing to unstable nodal lines prone to reentry formation.

Impact of Voltage Mapping to Guide Whether to Perform Ablation of the Posterior Wall in Patients With Persistent Atrial Fibrillation.

Fibrosis as a substrate for atrial fibrillation (AF) has been shown in numerous preclinical models. Voltage mapping enables in vivo assessment of scar in the left atrium (LA), which can be targeted with catheter ablation.

Electrophysiological studies of transgenic long QT type 1 and type 2 rabbits reveal genotype-specific differences in ventricular refractoriness and His conduction.

We have generated transgenic rabbits lacking cardiac slow delayed-rectifier K(+) current [I(Ks); long QT syndrome type 1 (LQT1)] or rapidly activating delayed-rectifier K(+) current [I(Kr); long QT syndrome type 2 (LQT2)]. Rabbits with either genotype have prolonged action potential duration and QT intervals; however, only LQT2 rabbits develop atrioventricular (AV) blocks and polymorphic ventricular tachycardia. We therefore sought to characterize the genotype-specific differences in AV conduction and ventricular refractoriness in LQT1 and LQT2 rabbits. We carried out in vivo electrophysiological studies in LQT1, LQT2, and littermate control (LMC) rabbits at baseline, during isoproterenol infusion, and after a bolus of dofetilide and ex vivo optical mapping studies of the AV node/His-region at baseline and during dofetilide perfusion. Under isoflurane anesthesia, LQT2 rabbits developed infra-His blocks, decremental His conduction, and prolongation of the Wenckebach cycle length. In LQT1 rabbits, dofetilide altered the His morphology and slowed His conduction, resulting in intra-His block, and additionally prolonged the ventricular refractoriness, leading to pseudo-AV block. The ventricular effective refractory period (VERP) in right ventricular apex and base was significantly longer in LQT2 than LQT1 (P < 0.05) or LMC (P < 0.01), with a greater VERP dispersion in LQT2 than LQT1 rabbits. Isoproterenol reduced the VERP dispersion in LQT2 rabbits by shortening the VERP in the base more than in the apex but had no effect on VERP in LQT1. EPS and optical mapping experiments demonstrated genotype-specific differences in AV conduction and ventricular refractoriness. The occurrence of infra-His blocks in LQT2 rabbits under isoflurane and intra-His block in LQT1 rabbits after dofetilide suggest differential regional sensitivities of the rabbit His-Purkinje system to drugs blocking I(Kr) and I(Ks).

Complex excitation dynamics underlie polymorphic ventricular tachycardia in a transgenic rabbit model of long QT syndrome type 1

BACKGROUND Long QT syndrome type 1 (LQT1) is a congenital disease arising from a loss of function in the slowly activating delayed potassium current IKs, which causes early afterdepolarizations (EADs) and polymorphic ventricular tachycardia (pVT). OBJECTIVE The purpose of this study was to investigate the mechanisms underlying pVT using a transgenic rabbit model of LQT1. METHODS Hearts were perfused retrogradely, and action potentials were recorded using a voltage-sensitive dye and CMOS cameras. RESULTS Bolus injection of isoproterenol (140 nM) induced pVT initiated by focal excitations from the right ventricle (RV; n = 16 of 18 pVTs). After the pVT was initiated, complex focal excitations occurred in both the RV and the left ventricle, which caused oscillations of the QRS complexes on ECG, consistent with the recent proposal of multiple shifting foci caused by EAD chaos. Moreover, the action potential upstroke in pVT showed a bimodal distribution, demonstrating the coexistence of 2 types of excitation that interacted to produce complex pVT: Na(+) current (INa)-mediated fast conduction and L-type Ca(2+) current (ICa)-mediated slow conduction coexist, manifesting as pVT. Addition of 2 μM tetrodotoxin to reduce INa converted pVT into monomorphic VT. Reducing late INa in computer simulation converted pVT into a single dominant reentry, agreeing with experimental results. CONCLUSION Our study demonstrates that pVT in LQT1 rabbits is initiated by focal excitations from the RV and is maintained by multiple shifting foci in both ventricles. Moreover, wave conduction in pVT exhibits bi-excitability, that is, fast wavefronts driven by INa and slow wavefronts driven by ICa co-exist during pVT.

Spatially Discordant Alternans and Arrhythmias in Tachypacing-Induced Cardiac Myopathy in Transgenic LQT1 Rabbits: The Importance of IKs and Ca2+ Cycling

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A novel, minimally invasive, segmental myocardial infarction with a clear healed infarct borderzone in rabbits

Ventricular arrhythmias in the setting of a healed myocardial infarction have been studied to a much lesser degree than acute and subacute infarction, due to the pericardial scarring, which results from the traditional open-chest techniques used for myocardial infarction (MI) induction. We sought to develop a segmental MI with low perioperative mortality in the rabbit that allows optimal visualization and therefore improved study of the infarction borderzone. Rabbits underwent MI using endovascular coil occlusion of the first obtuse marginal artery. Three weeks postprocedure, we evaluated our model by echocardiography and electrophysiology studies, optical mapping of isolated hearts, and histological studies. Seventeen rabbits underwent the protocol (12 MI and 5 sham) with a 92% survival to completion of the study (11 MI and 5 sham). MI rabbits demonstrated wall motion abnormalities on echocardiography while shams did not. At electrophysiological study, two MI rabbits had inducible ventricular tachycardia and one had inducible ventricular fibrillation. Isolated hearts demonstrated no pericardial scarring with a smooth, easily identifiable infarct borderzone. Optical mapping of the borderzone region showed successful mapping of peri-infarct reentry formation, with ventricular fibrillation inducible in 11 of 11 MI hearts and 1 of 5 sham hearts. We demonstrate successful high resolution mapping in the borderzone, showing delayed conduction in this region corresponding to late deflections in the QRS on ECG. We report the successful development of a minimally invasive MI via targeted coil delivery to the obtuse marginal artery with an exceptionally high rate of procedural survival and an arrhythmogenic phenotype. This model mimics human post-MI on echocardiography, gross pathology, histology, and electrophysiology.

The presence of left atrial posterior wall fibrillation despite restoration of sinus rhythm after posterior box ablation

A 74-year-old woman was referred to the outpatientdepartment with a history of symptomatic persistent AFdespite receiving a maximal dose of dofetilide. Her othermedication included warfarin, lisinopril, and atorvastatin.There was no history of hypertension, coronary arterydisease, or obstructive sleep apnea. A previous trans-thoracic echocardiogram had been reported as demonstrat-ing a mildly dilated left atrium (LA) at 4.2 cm with normalleft ventricle (LV) systolic function (ejection fraction70%). A preoperative transesophageal echocardiogramshowed no evidence of clot in the left atrial appendagewith 4 PVs draining into the LA. Thesefindings wereconfirmed by a preoperative multislice computedtomography scan. The patient elected to have radiofre-quencycatheterablationforAF.Dofetilidewasheld5daysprior to the procedure.The patient presented to the laboratory in AF. A doubletransseptalpuncturewasperformedandheparinwasgivenasa bolus and infused targeting activated coagulation times of300–400 seconds. A 3-dimensional electroanatomic map-ping technique was employed (CARTO 3 NavigationSystem, Biosense Webster, Diamond Bar, CA). A 6F Lassovariable circular catheter (Biosense Webster) and anirrigated-tip mapping/ablationcatheter(FcurveThermoCoolIrrigated Tip Catheter SF, Biosense Webster) were intro-duced into the LA.Wide antral isolation of the left and right PVs wasperformed initially. Powers of 35–43W were usedanteriorlyand 25–30 W posteriorly in the LA. The patient remained inAF after all 4 PVs demonstrated isolation. The patient wassuccessfully cardioverted to sinus rhythm, following a singlesynchronized direct current shock of 150 J. All PVsremained isolated. However, AF recurred shortly aftercardioversion. Posterior wall isolation was therefore tar-getedwitharooflineandfloorlinetocompletea“posteriorbox.” After further ablation, including that at the cavo-tricuspid isthmus and LA septal roof, the patient convertedto sinus rhythm during radiofrequency delivery on the LAroof. During sinus rhythm, the Lasso catheter was placedback onto the posterior wall to check for electricalisolation. At this time, the posterior wall appeared to havecontinuous irregular electrical signal during sinus rhythm,suggesting AF existing on the now isolated posteriorwall during sinus rhythm in the remainder of the atria(Figure 1).The post-procedure course was uncomplicated. Thepatient was restarted on dofetilide and was discharged homethe next day. Dofetilide was discontinued 2 months postablation. Now,7 months post ablation and off antiarrhythmicdrugs, she has remained asymptomatic and in sinus rhythm.A 1-month Event monitor at 3 months post ablation and a2-week Holter monitor at 6 months post ablation did notreveal any atrial arrhythmias.