Transient limb ischaemia remotely preconditions through a humoral mechanism acting directly on the myocardium: evidence suggesting cross-species protection.

rIPC (remote ischaemic preconditioning) is a phenomenon whereby short periods of ischaemia and reperfusion of a tissue or organ (e.g. mesentery, kidney) can protect a distant tissue or organ (e.g. heart) against subsequent, potentially lethal, ischaemia. We, and others, have shown that transient limb ischaemia can provide potent myocardial protection experimentally and clinically during cardiac surgery. Nonetheless, our understanding of the signal transduction from remote stimulus to local effect remains incomplete. The aim of the present study was to define the humoral nature of rIPC effector(s) from limb ischaemia and to study their local effects in isolated heart and cardiomyocyte models. Using a Langendorff preparation, we show that infarct size after coronary artery ligation and reperfusion was substantially reduced by rIPC in vivo, this stimulus up-regulating the MAPKs (mitogen-activating protein kinases) p42/p44, and inducing PKCepsilon (protein kinase Cepsilon) subcellular redistribution. Pre-treatment with the plasma and dialysate of plasma (obtained using 15 kDa cut-off dialysis membrane) from donor rabbits subjected to rIPC similarly protected against infarction. The effectiveness of the rIPC dialysate was abrogated by passage through a C18 hydrophobic column, but eluate from this column provided the same level of protection. The dialysate of rIPC plasma from rabbits and humans was also tested in an isolated fresh cardiomyocyte model of simulated ischaemia and reperfusion. Necrosis in cardiomyocytes treated with rIPC dialysate was substantially reduced compared with control, and was similar to cells pre-treated by 'classical' preconditioning. This effect, by rabbit rIPC dialysate, was blocked by pre-treatment with the opiate receptor blocker naloxone. In conclusion, in vivo transient limb ischaemia releases a low-molecular-mass (<15 kDa) hydrophobic circulating factor(s) which induce(s) a potent protection against myocardial ischaemia/reperfusion injury in Langendorff-perfused hearts and isolated cardiomyocytes in the same species. This cardioprotection is transferable across species, independent of local neurogenic activity, and requires opioid receptor activation.

IKr and IKs remodeling differentially affects QT interval prolongation and dynamic adaptation to heart rate acceleration in bradycardic rabbits.

Bradycardic ventricular electrical remodeling predisposes to lethal tachyarrhythmias. We investigated the early temporal sequence and reversibility of electrical remodeling in a rabbit complete heart block model subjected to bradycardic ventricular pacing for either 2 or 8 days, with a third group of animals undergoing 8 days of bradycardic pacing followed by 8 days of physiological-rate pacing. At specified time points after complete heart block induction and pacing initiation, steady-state QT interval measurements and variability as well as dynamic QT interval adaptation to abrupt heart rate acceleration were assessed in the absence and presence of isoproterenol. Rapidly (I(Kr)) and slowly (I(Ks)) activating delayed rectifier repolarizing K(+) tail current densities were evaluated using whole cell patch clamp in isolated right ventricular myocytes. Steady-state QT interval prolongation at both 2 and 8 days was associated with moderate I(Kr) reduction. I(Ks) downregulation was apparent by day 2 but more profound at day 8. Dynamic QT interval adaptation was impaired under baseline conditions at day 8 but only during isoproterenol administration at day 2. Both in vivo and cellular manifestations of remodeling reverted toward control values after 8 days of physiological-rate pacing. In conclusion, in this bradycardic model, I(Ks) downregulation 1) proceeds more gradually but more extensively than that of I(Kr) and 2) is most prominently associated with impaired dynamic QT interval adaptation to heart rate acceleration. Isoproterenol blunts the dynamic QT interval response in animals with partially downregulated I(Ks), consistent with stress-related phenomena in known I(Ks)-impaired states. Relative early sparing of I(Ks) could explain the delay in the onset of lethal tachyarrhythmia predisposition in bradycardic electrical remodeling. Reversibility of remodeling supports the potential utility of preventive pacing intervention soon after bradycardia onset.

Ventricular rate determines early bradycardic electrical remodeling.

OBJECTIVES: The purpose of this study was to isolate chronic ventricular rate as the primary determinant of early bradycardic ventricular electrical remodeling. BACKGROUND: Ventricular repolarization delay predisposing to potentially lethal tachydysrhythmias occurs during chronic bradycardia. Prolonged QT intervals and torsades de pointes are associated with down-regulated ventricular myocyte delayed rectifier potassium (K(+)) currents. METHODS: Transcatheter AV node ablation in rabbits was followed by chronic right ventricular pacing at either 140 bpm (n = 16) or the near-physiologic rate of 280 bpm (n = 9). ECG QT intervals were assessed in vivo at days 0 and 8 of paced AV block. Repolarizing currents in isolated left and right ventricular myocytes were assessed using whole-cell patch clamp technique. RESULTS: Bradycardic rabbits had increased steady-state QT intervals (230 +/- 6 ms vs 206 +/- 7 ms [mean +/- SE], day 8 vs day 0; P < .001). Biventricular myocyte expression of the delayed rectifier K(+) currents I(Kr) and I(Ks) was down-regulated in bradycardic rabbits, with no change in the transient outward current I(to) or inwardly rectifying current I(K1). None of these changes were observed in rabbits paced at 280 bpm. Pause-dependent torsades de pointes was documented in one bradycardic animal on day 8. No heart failure or ventricular hypertrophy was apparent. CONCLUSIONS: Bradycardic ventricular electrical remodeling proceeds independently of structural remodeling, heart failure, or AV synchrony and is prevented by maintenance of near-physiologic ventricular rate.

A novel rabbit model of variably compensated complete heart block.

Complete heart block (CHB) provides a useful substrate for study of bradycardia-dependent ventricular arrhythmias and cardiac function. Existing CHB animal models are limited by surgical recovery time and reliance on intrinsic escape rhythms. We describe a novel closed-chest rabbit model of CHB involving transcatheter radiofrequency (RF) atrioventricular (AV) node ablation and ventricular rate control with chronic transvenous pacing. Permanent CHB was achieved in 34 of 38 attempts overall. Procedural mortality due to cardiac tamponade (n = 2), airway complications (n = 2), and unknown causes (n = 5) occurred in nine animals. Survivors with CHB (n = 28) were maintained for < or = 22 days, during which there were three late deaths related to infection (n = 1) or respiratory distress (n = 2). None of the survivors with CHB showed recovery of AV conduction or pacemaker capture loss during chronic ventricular pacing at about one-half normal sinus rates, and 25 animals surviving to death showed no overt signs of hemodynamic compromise such as lethargy, poor feeding, or respiratory distress. This approach provides a reproducible nonsurgical CHB model with adjustable ventricular rate control.