Your search keyword '"David W, Whalley"' showing total 4 results

1. Targeting Cardiac Myocyte Na

Author

Natasha A S, Fry, Chia-Chi, Liu, Alvaro, Garcia, Elisha J, Hamilton, Keyvan, Karimi Galougahi, Yeon Jae, Kim, David W, Whalley, Henning, Bundgaard, and Helge H, Rasmussen

Subjects

Heart Failure, Disease Models, Animal, Animals, Myocytes, Cardiac, Rabbits, Adrenergic beta-Agonists, Sodium-Potassium-Exchanging ATPase, Ligation

Abstract

Abnormally high cytosolic NaIndices for HF were lung-, heart-, and liver: body weight ratios and ascites after circumflex coronary artery ligation in rabbits. NaCoronary ligation caused ascites in most rabbits, significantly increased lung-, heart-, and liver: body weight ratios, and decreased IParallel β3 AR agonists-induced reversal of Na

Published

2020

2. Basic Concepts in Cellular Cardiac Electrophysiology: Part II: Block of Ion Channels by Antiarrhythmic Drugs

Author

Augustus O. Grant, David W. Whalley, and D. J. Wendt

Subjects

Potassium Channels, Action Potentials, Pharmacology, Ion Channels, Sodium Channels, Toxicology, Drug treatment, Potassium Channel Blockers, Humans, Medicine, Available drugs, Ion channel, Block (data storage), business.industry, Cardiac electrophysiology, Blocking (radio), Heart, General Medicine, Calcium Channel Blockers, Electrophysiology, Clinical trial, Drug development, Drug Design, Controlled Clinical Trials as Topic, Cardiology and Cardiovascular Medicine, business, Anti-Arrhythmia Agents, Sodium Channel Blockers

Abstract

Summary Antiarrhythmic drugs have relative specificity for blocking each of the major classes of ion channels that control the action potential. The kinetics of block is determined by the state of the channel. Those channel states occupied at depolarized potentials generally have greater affinity for the blocking drugs. The kinetics of the drug-channel interaction is important in determining the blocking profile observed clinically. The increased mortality resulting from drug treatment in CAST and several atrial fibrillation trials has resulted in a shift in antiarrhythmic drug development from the Na+ channel blocking (Class I) drugs to the K+ channel blocking (Class III) drugs. While both Classes of drugs have a proarrhythmic potential, this may be less for the Class III agents. Their lack of negative inotropy also make them more attractive. It is important that the potential advantages of these agents be evaluated in controlled clinical trials. In several laboratories, the techniques of molecular biology and biophysics are being combined to determine the block site of available drugs. This information will aid in the future development of agents with greater specificity, and hopefully greater efficacy and safety than those currently in clinical use.

Published

1995

3. Basic concepts in cellular cardiac electrophysiology: Part I: Ion channels, membrane currents, and the action potential

Author

Augustus O. Grant, D. J. Wendt, and David W. Whalley

Subjects

Voltage-gated ion channel, business.industry, Cardiac electrophysiology, Myocardium, Action Potentials, Heart, General Medicine, Gating, Ion Channels, Membrane Potentials, Electrophysiology, Membrane, Action (philosophy), Heart Conduction System, Medicine, Humans, Cardiology and Cardiovascular Medicine, business, Neuroscience, Ion Channel Gating, Ion channel

Published

1995

4. Voltage-independent effects of extracellular K+ on the Na+ current and phase 0 of the action potential in isolated cardiac myocytes

Author

D. J. Wendt, David W. Whalley, C F Starmer, Augustus O. Grant, and Y. Rudy

Subjects

Male, medicine.medical_specialty, Time Factors, Physiology, Heart Ventricles, Kinetics, Ischemia, Action Potentials, Sodium Channels, medicine, Extracellular, Myocyte, Animals, Heart Atria, Cells, Cultured, Membrane potential, Analysis of Variance, Chemistry, Myocardium, Conductance, Depolarization, Heart, medicine.disease, Surgery, Membrane, Biophysics, Potassium, Rabbits, Cardiology and Cardiovascular Medicine

Abstract

A rise in [K+]o, by depolarizing the resting membrane potential and partially inactivating the inward Na+ current (INa), is believed to play a critical role in slowing conduction during myocardial ischemia. In multicellular ventricular preparations, elevation of [K+]o has been suggested to decrease Vmax to a greater extent than expected from membrane depolarization alone. The mechanism of this voltage-independent effect of [K+]o is currently unknown, and its significance in single cardiac cells has not been determined. We have examined the voltage-independent effects of elevated [K+]o on INa and the action potential upstroke in isolated rabbit atrial and ventricular myocytes under voltage- and current-clamp conditions. Superfusate [K+] was varied from 5 mmol/L to 14 or 24 mmol/L, whereas [Na+] was maintained at 150 mmol/L. In cultured atrial cells and excised outside-out patches from freshly isolated atrial and ventricular cells, the amplitude and kinetics of INa were unchanged by elevation of [K+]o. In atrial cells, action potentials elicited from a holding potential of -70 mV had a similar Vmax (114.9 +/- 5.7 versus 112.2 +/- 4.8 V/s, mean +/- SEM, n = 6) and action potential amplitude (115.0 +/- 2.4 versus 113.4 +/- 3.9 mV) in 5 and 24 mmol/L [K+]o. In contrast, in ventricular cells at a holding potential of -70 mV, increasing [K+]o fro 5 to 14 mmol/L decreased Vmax from 161.8 +/- 18.0 to 55.3 +/- 5.0 V/s (n = 7, P < .001) and action potential amplitude from 128.1 +/- 1.3 to 86.6 +/- 5.4 mV (P < .001). This voltage-independent decrease in Vmax and action potential amplitude induced by elevated [K+]o was abolished in the presence of 1 mmol/L Ba2+, suggesting that it is attributable to an increased background K+ conductance. We conclude that elevation of [K+]o to levels expected during ischemia causes a marked voltage-independent depression of Vmax in ventricular cells, which may, in turn, contribute to the slowing of myocardial conduction characteristic of early ischemia.

Published

1994