Validation of using cardioplegic solutions for preserving cardiac function in isolated rabbit heart assays.

INTRODUCTION: Cardioplegic solutions were first developed to preserve heart function during cardiac surgeries and heart transplants but have application in the nonclinical setting. Due to lack of lab space in the vivarium, cardioplegic solution was used to conserve cardiac function for ex-vivo studies performed in a separate building. All studies in this report were conducted with isolated female rabbit hearts (IRHs) via retrograde perfusion using the Langendorff apparatus to investigate if cardioplegia usage affects cardiac function. METHODS: Cardioplegia was achieved with a hyperkalemia (27 mM KCL) solution kept at 4 °C. Cardiac function was assessed by measuring ECG parameters, left ventricular contractility, and coronary flow under constant perfusion pressure. IRHs were cannulated with Krebs Henseleit buffer (KH) either fresh or after cardioplegic solution storage (C-IRH). Three comparisons were performed with and without cardioplegia; (i) direct side-by side studies of cardiac function; (ii) pharmacological responses to typical ion channels blockers, dofetilide, flecainide, and diltiazem; (iii) retrospective evaluation of cardiac functions in a large sample of hearts. RESULTS: In the side-by-side comparisons, cardioplegia-stored IRHs (C-IRH; storage time 90 min) had similar electrocardiographic (ECG) and hemodynamic parameters to fresh-cannulated hearts with KH buffer (KH-IRH). In addition, responses to dofetilide, flecainide, and diltiazem, were similar for C-IRH and KH-IRH hearts. Over the years (2006-2011), baseline data was collected from 79 hearts without cardioplegia and 100 hearts with cardioplegia (C-IRH; storage time 15 min), which showed no meaningful differences in a retrospective analysis. DISCUSSION: Cardiac function was preserved after cardioplegic treatment, however, coronary flow rates were decreased (-19.3%) in C-IRH hearts which indicated an altered coronary vascular tone. In conclusion, storage in cardioplegic solution preserves rabbit cardiac function, a practice that enables heart tissues to be collected at one site (e.g., vivarium) and transported to a laboratory in a separate location.

Comprehensive in vitro pro-arrhythmic assays demonstrate that omecamtiv mecarbil has low pro-arrhythmic risk.

Omecamtiv mecarbil (OM) is a myosin activator (myotrope), developed as a potential therapeutic agent for heart failure with reduced ejection fraction. To characterize the potential pro-arrhythmic risk of this novel sarcomere activator, we evaluated OM in a series of International Conference on Harmonization S7B core and follow-up assays, including an in silico action potential (AP) model. OM was tested in: (i) hERG, Nav1.5 peak, and Cav1.2 channel assays; (ii) in silico computation in a human ventricular AP (hVAP) population model; (iii) AP recordings in canine cardiac Purkinje fibers (PF); and (iv) electrocardiography analysis in isolated rabbit hearts (IRHs). OM had low potency in the hERG (half-maximal inhibitory concentration [IC50 ] = 125.5 µM) and Nav1.5 and Cav1.2 assays (IC50  > 300 µM). These potency values were used as inputs to investigate the occurrence of repolarization abnormalities (biomarkers of pro-arrhythmia) in an hVAP model over a wide range of OM concentrations. The outcome of hVAP analysis indicated low pro-arrhythmia risk at OM concentration up to 30 µM (100-fold the effective free therapeutic plasma concentration). In the isolated canine PF assay, OM shortened AP duration (APD)60 and APD90 significantly from 3 to 30 µM. In perfused IRH, ventricular repolarization (corrected QT and corrected JT intervals) was decreased significantly at greater than or equal to 1 µM OM. In summary, the comprehensive proarrhythmic assessment in human and non-rodent cardiac models provided data indicative that OM did not delay ventricular repolarization at therapeutic relevant concentrations, consistent with clinical findings.

A proprotein convertase subtilisin/kexin type 9 neutralizing antibody reduces serum cholesterol in mice and nonhuman primates.

Proprotein convertase subtilisin/kexin type 9 (PCSK9) regulates serum LDL cholesterol (LDL-C) by interacting with the LDL receptor (LDLR) and is an attractive therapeutic target for LDL-C lowering. We have generated a neutralizing anti-PCSK9 antibody, mAb1, that binds to an epitope on PCSK9 adjacent to the region required for LDLR interaction. In vitro, mAb1 inhibits PCSK9 binding to the LDLR and attenuates PCSK9-mediated reduction in LDLR protein levels, thereby increasing LDL uptake. A combination of mAb1 with a statin increases LDLR levels in HepG2 cells more than either treatment alone. In wild-type mice, mAb1 increases hepatic LDLR protein levels approximately 2-fold and lowers total serum cholesterol by up to 36%: this effect is not observed in LDLR(-/-) mice. In cynomolgus monkeys, a single injection of mAb1 reduces serum LDL-C by 80%, and a significant decrease is maintained for 10 days. We conclude that anti-PCSK9 antibodies may be effective therapeutics for treating hypercholesterolemia.