Bepridil: a pharmacological reappraisal of its potential beneficial effects in angina and tissue protection following ischemia.

In this review the pharmacologic properties of the calcium antagonist bepridil have been reexamined, particularly the evidence for an intracellular locus of action for the drug. Physicochemical properties of bepridil show it to be highly lipophylic, rapidly and extensively taken up, and accumulated in certain tissues. Combined electrophysiologic and mechanical studies have provided convincing, but indirect, evidence for an intracellular action of bepridil in cardiac muscle. Bepridil also fulfills, to a greater or lesser extent, certain important pharmacologic criteria necessary for evoking an intracellular action of a drug in cardiac and vascular smooth muscle: 1. Responses to agonists known to utilize intracellular calcium in the response are inhibited to a similar extent to depolarization-induced K+ responses. 2. Phasic and tonic responses to noradrenaline in vascular tissues are not, or are only to a minor extent, differentially antagonized. 3. Responses to the calcium ionophore A 23187 are antagonized. 4. Activity is retained following removal of the cell membrane by surfactants. 5. Isolated enzyme systems (e.g., calmodulin, myosin light-chain kinase) are affected by the drug at similar concentrations to those that are effective in whole cells or tissues. Finally results obtained with bepridil in ischemic myocardium have been reviewed to ascertain whether its broader pharmacologic spectrum over the calcium-entry blockers is associated with enhanced tissue protective properties. Positive results with bepridil in hypoxic myocytes and ischemic myocardium distinguishes this drug from the classical antianginal agents verapamil, nifedipine, and diltiazem. It is suggested that bepridil, because of its paucity of hemodynamic effects, may be of special therapeutic interest in the management of silent ischemia where cellular mechanisms leading to cytoprotection are more desirable than strong hemodynamic activity.