Cardiac sodium channel antagonism - Translation of preclinical in vitro assays to clinical QRS prolongation.

INTRODUCTION: Cardiac sodium channel antagonists have historically been used to treat cardiac arrhythmias by preventing the reentry of the electrical impulse that could occur following myocardial damage. However, clinical studies have highlighted a significant increase in mortality associated with such treatment. Cardiac sodium channel antagonist activity is now seen as an off-target pharmacology that should be mitigated during the drug development process. The aim of this study was to examine the correlation between in vitro/ex vivo assays that are routinely used to measure Nav1.5 activity and determine the translatability of the individual assays to QRS prolongation in the clinic. METHODS: A set of clinical compounds with known Nav1.5 activity was profiled in several in vitro/ex vivo assays (binding, membrane potential, patch clamp and the Langendorff isolated heart). Clinical data comprising compound exposure levels and changes in QRS interval were obtained from the literature. Sensitivity/specificity analysis was performed with respect to the clinical outcome. RESULTS: The in vitro assays showed utility in predicting QRS prolongation in the clinic. Optimal thresholds were defined for each assay (binding: IC20; membrane potential: IC10; patch clamp: IC20) and sensitivity (69-88%) and specificity (53-84%) values were shown to be similar between assay formats. DISCUSSION: The data provide clear statistical insight into the translatability of Nav1.5 antagonism data generated in vitro to potential clinical outcomes. These results improve our ability to understand the liability posed by such activity in novel development compounds at an early stage.

L-type calcium channel antagonism - Translation from in vitro to in vivo.

INTRODUCTION: Although therapeutically beneficial in the treatment of certain diseases, L-type calcium channel antagonism can result in unwanted off-target pharmacology leading to adverse drug reactions and to the termination of the development of otherwise promising compounds. In the present study three marketed calcium channel inhibitors, nifedipine, verapamil and diltiazem were profiled in a series of in vitro and ex-vivo assays in an effort to determine the ability of these assays to discriminate, between dihydropyridine versus non-dihydropyridine-like compounds, and how well they can predict the cardiovascular effects observed in a conscious telemetered rat model. METHODS: Standard calcium channel antagonists were profiled in radioligand binding, patch clamp and calcium flux assays. In addition, cardiovascular endpoints related to calcium channel activity were also examined in ex vivo tissue bath preparations, including relaxation of pre-constricted rat aorta and the guinea pig Langendorff isolated heart model. The data generated were correlated with in vivo blood pressure and heart rate data from conscious telemetered rats. RESULTS: Our results show that the binding, FLIPR and aorta assays allow differentiation of the compounds in two distinct classes of L-type calcium channel antagonists, and are good predictors of in vivo outcomes. DISCUSSION: These results suggest that in vitro and ex vivo profiling remains a valuable tool in predicting potential in vivo cardiovascular safety issues, and can aid in the selection of novel development compounds that show inherent inhibitory activity against L-type calcium channels.

Discovery of cyclopropyl chromane-derived pyridopyrazine-1,6-dione γ-secretase modulators with robust central efficacy.

Herein we describe the discovery of a novel series of cyclopropyl chromane-derived pyridopyrazine-1,6-dione γ-secretase modulators for the treatment of Alzheimer's disease (AD). Using ligand-based design tactics such as conformational analysis and molecular modeling, a cyclopropyl chromane unit was identified as a suitable heterocyclic replacement for a naphthyl moiety that was present in the preliminary lead 4. The optimized lead molecule 44 achieved good central exposure resulting in robust and sustained reduction of brain amyloid-ß42 (Aß42) when dosed orally at 10 mg kg-1 in a rat time-course study. Application of the unpaced isolated heart Langendorff model enabled efficient differentiation of compounds with respect to cardiovascular safety, highlighting how minor structural changes can greatly impact the safety profile within a series of compounds.