Maaike Peschar

Relation between the pacing induced sequence of activation and left ventricular pump function in animals.

PRINZEN, F.W., et al.: Relation Between the Pacing Induced Sequence of Activation and Left Ventricu‐lar Pump Function in Animals. The main goal of this article was to review animal experimental work on the effect of asynchronous activation on ventricular pump function. During normal sinus rhythm and atrial pacing, the Purkinje system contributes significantly to the rapid electrical activation of the ventricles. In contrast, during ventricular pacing the impulse is almost exclusively conducted through the normal myocardium. As a consequence, electrical activation of the ventricles becomes asynchronous and has an abnormal sequence. The abnormal impulse conduction causes considerable disturbances to occur in regional systolic fiber shortening, mechanical work, blood flow, and oxygen consumption; low values occurring in early activated regions and values above normal being present in late activated regions. Many animal studies have now shown that the abnormal electrical activation, induced by ventricular pacing, leads to a depression of systolic and diastolic LV function. Pacing at the right ventricular apex (the conventional pacing site) reduces LV function more than pacing at the high ventricular septum or at LV sites. In canine hearts with experimental LBBB, LV pacing significantly improves LV pump function. Differences in LV pump function between (combinations of) pacing sites are poorly correlated with QRS duration. Therefore, the cause of the depression of LV function during abnormal electrical activation appears to be a combination of the asynchrony and the sequence of activation. These experimental findings justify continuing attention for optimizing the site(s) of ventricular pacing in patients with normal and abnormal ventricular impulse conduction.

Left ventricular septal and apex pacing for optimal pump function in canine hearts

OBJECTIVES The goal of this study was to test the hypothesis that left ventricular (LV) pump function is optimal when pacing is performed at the LV near the sites where the impulses exit the Purkinje system. BACKGROUND Pacing at the conventional site, the right ventricular (RV) apex, adversely affects hemodynamics. During normal sinus rhythm (SR), electrical activation of the working myocardium starts at the LV septal endocardium and spreads from apex to base. METHODS Experiments were conducted in anesthetized open-chest dogs with normal ventricular conduction to investigate hemodynamic effects of pacing at various epicardial LV sites, the RV apex, and combinations of these sites (n = 11) and of RV and LV septal pacing (n = 8). The LV septal endocardium was reached via the RV by puncturing through the septum with a barbed electrode. Left ventricular systolic (LVdP/dtpos and stroke work) and diastolic (LVdP/dtneg and Tau) function were assessed using pressure-volume relations (conductance catheter technique). RESULTS Left ventricular systolic and diastolic function were highly dependent on the site of pacing, but not on QRS duration. Left ventricular function was maintained at SR level during LV septal, LV apex, and multisite pacing, was moderately depressed during pacing at epicardial LV free wall sites, and was most severely depressed during RV apex pacing. On average, RV septal pacing did not improve LV function, compared with RV apex pacing, but in each experiment one (variable) RV pacing site was found, which only moderately reduced LV function. CONCLUSIONS During ventricular pacing, LV pump function is maintained best (i.e., at SR level) when pacing at the LV septum or LV apex, potentially because pacing from these sites creates a physiological propagation of electrical conduction.

Intra-ventricular resynchronization for optimal left ventricular function during pacing in experimental left bundle branch block

OBJECTIVES We sought to investigate to what extent intra-ventricular asynchrony (intraVA) and inter-ventricular asynchrony (interVA) determine left ventricular (LV) function in canine hearts with left bundle branch block (LBBB) during ventricular pacing. BACKGROUND Pacing therapy improves LV pump function in patients with heart failure and abnormal ventricular conduction supposedly due to resynchronization. However, the relationship between LV pump function and measures of asynchrony is not well established. METHODS In 15 experiments, LV (various sites) and biventricular (BiV) pacing was performed at atrioventricular (AV) delays of 20 to 140 ms. Measured were the maximum rate of increase (dP/dt(max)) of LV pressure and LV stroke work (SW) (conductance catheter), interVA (time delay between the upslope of LV and RV pressures), and intraVA (from endocardial electrical activation maps). RESULTS Induction of LBBB increased interVA (-6.4 +/- 8.6 to -28.4 +/- 8.5 ms [RV earlier]) and intraVA (4.9 +/- 2.4 to 18.0 +/- 3.3 ms), whereas LV dP/dt(max) and SW decreased (-13 +/- 18% and -39 +/- 24%, respectively). During LBBB, LV and BiV pacing increased LV dP/dt(max) and SW (mean increases 14% to 21% and 11% to 15%, respectively) without changing diastolic function or preload. Optimal improvement in LV function was obtained consistently when intraVA returned to pre-LBBB values, while interVA remained elevated. Normalization of intraVA required AV delays shorter than the baseline PQ time during LV apex and BiV pacing, thus excluding endogenous LV activation, but AV delays virtually equal to the baseline PQ time (difference 4 +/- 9 ms, p = NS) during pacing at (mid)lateral LV sites to obtain fusion between pacing-induced and endogenous activation. CONCLUSIONS In LBBB hearts, optimal restoration of LV systolic function by pacing requires intra-ventricular resynchronization. The optimal AV delay to achieve this depends on both the site of pacing and baseline PQ time.

Comparison of the IKr blockers moxifloxacin, dofetilide and E‐4031 in five screening models of pro‐arrhythmia reveals lack of specificity of isolated cardiomyocytes

Drug development requires the testing of new chemical entities for adverse effects. For cardiac safety screening, improved assays are urgently needed. Isolated adult cardiomyocytes (CM) and human embryonic stem cell‐derived cardiomyocytes (hESC‐CM) could be used to identify pro‐arrhythmic compounds. In the present study, five assays were employed to investigate their sensitivity and specificity for evaluating the pro‐arrhythmic properties of IKr blockers, using moxifloxacin (safe compound) and dofetilide or E‐4031 (unsafe compounds).

Absence of reverse electrical remodeling during regression of volume overload hypertrophy in canine ventricles.

OBJECTIVE Ventricular hypertrophy predisposes for cardiac arrhythmias, presumably due to prolongation of repolarization (electrical remodeling). The temporal relation between the development of hypertrophy and electrical remodeling, as well as their reversibility upon restoration of normal load, however, are poorly understood. This was investigated in the present study using volume overload hypertrophy induced by atrio-ventricular (AV) block and normalization of load by pacing. METHODS Dogs were subjected to either 16 weeks of AV-block (CAVB group, n=9) or 8 weeks of AV-block followed by 8 weeks of right ventricular (RV) pacing at physiological heart rate (CAVB+PACE group, n=9). RESULTS Left ventricular (LV) mass (2D-echocardiography) increased after 8 weeks of AV-block to approximately 30% above baseline and returned to 10+/-14% after 8 weeks of pacing. QT-time (surface ECG) also increased after AV-block. However, 8 weeks of pacing did not decrease QT and QTc-time (c=corrected for heart rate), neither during physiological pacing nor during temporary pacing at 100 beats/min. Lack of reverse electrical remodeling was confirmed by the absence of changes in LV and RV action potential duration (monophasic action potentials) at week 8 and 16. CONCLUSIONS In volume overload hypertrophy due to AV-block, structural and electrical remodeling develop in parallel but restoration of physiological heart rate causes dissociation between reverse structural remodeling and reverse electrical remodeling.

Efficient and specific cardiac IK1 inhibition by a new pentamidine analogue

AIMS In excitable cells, KIR2.x ion-channel-carried inward rectifier current (IK₁) is thought to set the negative and stable resting membrane potential, and contributes to action potential repolarization. Loss- or gain-of-function mutations correlate with cardiac arrhythmias and pathological remodelling affects normal KIR2.x protein levels. No specific IK1 inhibitor is currently available for in vivo use, which severely hampers studies on the precise role of IK1 in normal cardiac physiology and pathophysiology. The diamine antiprotozoal drug pentamidine (P) acutely inhibits IK₁ by plugging the cytoplasmic pore region of the channel. We aim to develop more efficient and specific IK₁ inhibitors based on the P structure. METHODS AND RESULTS We analysed seven pentamidine analogues (PA-1 to PA-7) for IK₁ blocking potency at 200 nM using inside-out patches from KIR2.1 expressing HEK-293 cells. PA-6 showed the highest potency and was tested further. PA-6 blocked KIR2.x currents of human and mouse with low IC₅₀ values (12-15 nM). Modelling indicated that PA-6 had less electrostatic but more lipophilic interactions with the cytoplasmic channel pore than P, resulting in a higher channel affinity for PA-6 (ΔG -44.1 kJ/Mol) than for P (ΔG -31.7 kJ/Mol). The involvement of acidic amino acid residues E224 and E299 in drug-channel interaction was confirmed experimentally. PA-6 did not affect INav1.5, ICa-L, IKv4.3, IKv11.1, and IKv7.1/minK currents at 200 nM. PA-6 inhibited the inward (50 nM 40%; 100 nM 59%; 200 nM 77%) and outward (50 nM 40%; 100 nM 76%; 200 nM 100%) components of IK₁ in isolated canine adult-ventricular cardiomyocytes (CMs). PA-6 prolonged action potential duration of CMs by 8 (n = 9), 26 (n = 5), and 34% (n = 11) at 50, 100, and 200 nM, respectively. Unlike P, PA-6 had no effect on KIR2.1 channel expression at concentrations from 0.1 to 3 μM. However, PA-6 at 10 μM increased KIR2.1 expression levels. Also, PA-6 did not affect the maturation of hERG, except when applied at 10 μM. CONCLUSION PA-6 has higher efficiency and specificity to KIR2.x-mediated current than P, lengthens action potential duration, and does not affect channel trafficking at concentrations relevant for complete IK₁ block.

High-resolution functional imaging with ultrasound contrast agents based on RF processing in an in vivo kidney experiment

Knowledge of the relative tissue perfusion distribution is valuable in the diagnosis of numerous diseases. Techniques for the assessment of the relative perfusion distribution, based on ultrasound (US) contrast agents, have several advantages compared to established nuclear techniques. These are, among others, a better spatial and temporal resolution, the lack of exposure of the patient to ionizing radiation and the relatively low cost. In the present study, US radiofrequency (RF) image sequences are acquired, containing the signal intensity changes associated with the transit of a bolus contrast agent through the microvasculature of a dog kidney. The primary objective is to explore the feasibility of calculating functional images with high spatial resolution. The functional images characterize the transit of the contrast agent bolus and represent distributions of peak time, peak value, transit time, peak area, wash-in rate and wash-out decay constant. For the evaluation of the method, dog experiments were performed under optimized conditions where motion artefacts were minimized and an IA injection of the contrast agent Levovist was employed. It was demonstrated that processing of RF signals obtained with a 3.5-MHz echo system can provide functional images with a high spatial resolution of 2 mm in axial resolution, 2 to 5 mm in lateral resolution and a slice thickness of 2 mm. The functional images expose several known aspects of kidney perfusion, like perfusion heterogeneity of the kidney cortex and a different peripheral cortical perfusion compared to the inner cortex. Based on the findings of the present study, and given the results of complimentary studies, it is likely that the functional images reflect the relative perfusion distribution of the kidney.