Cellular impedance assays for predictive preclinical drug screening of kinase inhibitor cardiovascular toxicity.

Cardiovascular (CV) toxicity is a leading contributor to drug attrition. Implementing earlier testing has successfully reduced human Ether-à-go-go-Related Gene-related arrhythmias. How- ever, analogous assays targeting functional CV effects remain elusive. Demand to address this gap is particularly acute for kinase inhibitors (KIs) that suffer frequent CV toxicity. The drug class also presents some particularly challenging requirements for assessing functional CV toxicity. Specifically, an assay must sense a downstream response that integrates diverse kinase signaling pathways. In addition, sufficient throughput is essential for handling inherent KI nonselectivity. A new opportunity has emerged with cellular impedance technology, which detects spontaneous beating cardiomyocytes. Impedance assays sense morphology changes downstream of cardiomyocyte contraction. To evaluate cardiomyocyte impedance assays for KI screening, we investigated two distinct KI classes where CV toxicity was discovered late and target risks remain unresolved. Microtubule-associated protein/microtubule affinity regulating kinase (MARK) inhibitors decrease blood pressure in dogs, whereas checkpoint kinase (Chk) inhibitors (AZD7762, SCH900776) exhibit dose-limiting CV toxicities in clinical trials. These in vivo effects manifested in vitro as cardiomyocyte beat cessation. MARK effects were deemed mechanism associated because beat inhibition potencies correlated with kinase inhibition, and gene knockdown and microtubule-targeting agents suppressed beating. MARK inhibitor impedance and kinase potencies aligned with rat blood pressure effects. Chk inhibitor effects were judged off-target because Chk and beat inhibition potencies did not correlate and knockdowns did not alter beating. Taken together, the data demonstrate that cardiomyocyte impedance assays can address three unmet needs-detecting KI functional cardiotoxicity in vitro, determining mechanism of action, and supporting safety structure-activity relationships.

5HT1A receptors inhibit glutamate inputs to cardiac vagal neurons post-hypoxia/hypercapnia.

Synaptic inputs to cardiac vagal neurons (CVNs) regulate parasympathetic activity to the heart. Previous work has shown insults such as hypoxia and hypercapnia (H/H) alter CVN activity by activating post-synaptic serotonergic, purinergic, and glutamatergic receptors in CVNs. This study examines the role of serotonergic 5HT1A receptors in modulating these excitatory neurotransmissions to CVNs during control conditions, H/H and recovery from H/H. Excitatory post-synaptic currents (EPSCs) were recorded from identified CVNs in vitro before, during and post H/H. The 5HT1A receptor antagonist WAY 100635 had no effect on EPSCs in CVNs before, and during H/H. However, during recovery from H/H inspiratory-related excitatory serotonergic and purinergic pathways were recruited to excite CVNs. However, when these serotonergic and purinergic pathways are blocked, the 5HT1A receptor antagonist WAY 100635 restores an excitatory glutamatergic neurotransmission to CVNs. This study indicates endogenous activation of serotonergic 5HT1A receptors diminishes glutamatergic neurotransmission to CVNs following H/H, likely via a presynaptic site of action.

An integrative pharmacological approach to radio telemetry and blood sampling in pharmaceutical drug discovery and safety assessment.

BACKGROUND: A successful integration of the automated blood sampling (ABS) and telemetry (ABST) system is described. The new ABST system facilitates concomitant collection of physiological variables with blood and urine samples for determination of drug concentrations and other biochemical measures in the same rat without handling artifact. METHOD: Integration was achieved by designing a 13 inch circular receiving antenna that operates as a plug-in replacement for the existing pair of DSI's orthogonal antennas which is compatible with the rotating cage and open floor design of the BASi Culex® ABS system. The circular receiving antenna's electrical configuration consists of a pair of electrically orthogonal half-toroids that reinforce reception of a dipole transmitter operating within the coil's interior while reducing both external noise pickup and interference from other adjacent dipole transmitters. RESULTS: For validation, measured baclofen concentration (ABST vs. satellite (µM): 69.6 ± 23.8 vs. 76.6 ± 19.5, p = NS) and mean arterial pressure (ABST vs. traditional DSI telemetry (mm Hg): 150 ± 5 vs.147 ± 4, p = NS) variables were quantitatively and qualitatively similar between rats housed in the ABST system and traditional home cage approaches. CONCLUSION: The ABST system offers unique advantages over traditional between-group study paradigms that include improved data quality and significantly reduced animal use. The superior within-group model facilitates assessment of multiple physiological and biochemical responses to test compounds in the same animal. The ABST also provides opportunities to evaluate temporal relations between parameters and to investigate anomalous outlier events because drug concentrations, physiological and biochemical measures for each animal are available for comparisons.

Combining radio telemetry and automated blood sampling: a novel approach for integrative pharmacology and toxicology studies.

INTRODUCTION: A novel automated blood sampling and telemetry (ABST) system was developed to integrate pharmacokinetic (PK), pharmacodynamic (PD) and toxicology studies. The goals of this investigation were to determine: 1) optimal feeding conditions and minimal acclimation times for recording PD parameters (blood pressure, heart rate, and temperature) after animals arrived on-site; 2) stress hormone levels in ABST-housed rats; 3) the feasibility of simultaneously recording cardiovascular parameters with electroencephalogram (EEG); 4) the equivalence of renal endpoints from ABST-housed rats with those in the metabolic cage, and 5) the cardiovascular responses to baclofen. METHODS: Body weight, blood pressure, temperature, stress biomarkers, urine chemistries, renal biomarkers and responses to vehicle or baclofen (10mg/kg) were compared in awake and freely moving rats housed in the ABST system, home cage (HC) or metabolic cage. RESULTS: Fasted rats lost 5+/-1% and 7+/-1% body weight when housed in ABST and metabolic cages, respectively. Weight loss was reversed by supplementing regular diet with hydration and nutritional supplements. Based on PD parameters, the minimum acclimation time required for both ABST and HC rats was 3days. The feasibility of simultaneously measuring multiple parameters, such as EEG with cardiovascular parameters in ABST was demonstrated. Renal function and biomarkers in rats continuously housed in the ABST and metabolic cages were equivalent (p>0.05) on days 1, 3, and 7. Baclofen-induced quantitatively and qualitatively similar (p>0.05) PK, mean arterial pressure, heart rate and temperature in ABST- and HC-housed rats. DISCUSSION: These studies demonstrate for the first time that drug-induced PD responses can be recorded simultaneously with time-matched pharmacokinetic, biochemical and metabolic parameters in the same animal. The ABST system has the added advantage of blood sampling without the need for satellite PK animals. ABST is a useful and novel tool for establishing efficacy and safety margins using an in vivo integrative pharmacology approach.

Reactive oxygen species mediate central cardiorespiratory network responses to acute intermittent hypoxia.

Although oxidative stress and reactive oxygen species generation is typically associated with localized neuronal injury, reactive oxygen species have also recently been shown to act as a physiological signal in neuronal plasticity. Here we define an essential role for reactive oxygen species as a critical stimulus for cardiorespiratory reflex responses to acute episodic hypoxia in the brain stem. To examine central cardiorespiratory responses to episodic hypoxia, we used an in vitro medullary slice that allows simultaneous examination of rhythmic respiratory-related activity and synaptic neurotransmission to cardioinhibitory vagal neurons. We show that whereas continuous hypoxia does not stimulate excitatory neurotransmission to cardioinhibitory vagal neurons, acute intermittent hypoxia of equivalent duration incrementally recruits an inspiratory-evoked excitatory neurotransmission to cardioinhibitory vagal neurons during intermittent hypoxia. This recruitment was dependent on the generation of reactive oxygen species. Further, we demonstrate that reactive oxygen species are incrementally generated in glutamatergic neurons in the ventrolateral medulla during intermittent hypoxia. These results suggest a neurochemical basis for the pronounced bradycardia that protects the heart against injury during intermittent hypoxia and demonstrates a novel role of reactive oxygen species in the brain stem.