Effects of a calcium channel blocker on cardiac output distribution in conscious hypertensive dogs

Inhibition of smooth muscle myosin as a novel therapeutic target for hypertension

We examined a novel therapeutic approach for hypertension, a small-molecule direct inhibitor of smooth muscle myosin, CK-2018448 (CK-448), which is an N,N'-alkylurea (U.S. Patent Publication 2009-0275537 A1) in conscious dogs with renal hypertension and compared its efficacy with that of a calcium channel blocker, amlodipine. Dogs were instrumented with a miniature left ventricular pressure gauge, an aortic pressure catheter, and ultrasonic flow probes in the ascending aorta and renal and iliac arteries for measurement of cardiac output and regional blood flow. In the hypertensive state, mean arterial pressure increased from 101 ± 3.8 to 142 ± 1.9 mm Hg. At the doses selected, CK-448 and amlodipine increased cardiac output similarly (30 ± 11% versus 33 ± 6.4%) and similarly reduced mean arterial pressure (-22 ± 3.6% versus -16 ± 3.4%) and total peripheral resistance (-36 ± 5.9% versus -37 ± 5.8%). CK-448 had the greatest vasodilator effect in the renal bed, where renal blood flow increased by 46 ± 9.0%, versus 11 ± 3.4% for amlodipine (p < 0.01). CK-488 produced significantly less vasodilation in the limb, where iliac blood flow did not change; in contrast, it rose by 48 ± 12% with amlodipine (p < 0.01). The minimal effects on limb blood flow could limit the development of peripheral edema, an adverse side effect of Ca(2+) channel blockers. In addition, in a rodent model of hypertension, oral administration of a smooth muscle myosin inhibitor resulted in a sustained antihypertensive effect. Thus, the smooth muscle myosin inhibitor's preferential effect on renal blood flow makes this drug mechanism particularly appealing, because many patients with hypertension have renal insufficiency, and patients with heart failure could benefit from afterload reduction coupled with enhanced renal blood flow.

Epinephrine-induced decrease in repetitive extrasystole threshold is reversed by tyrosine in conscious dogs

Previous studies indicate that availability of L-tyrosine, the precursor for catecholaminergic neurotransmitters, reduced psychological and physiological effects of stressful situations including hypotension, cold and behavioral stress. The current study examined the effect of L-tyrosine administration on cardiac vulnerability to arrhythmia induced by an infusion of epinephrine in conscious dogs. Heart rate, mean arterial pressure and cardiac electrophysiologic parameters, i.e., effective refractory period and repetitive extrasystole threshold, were measured during infusion of epinephrine (0.3 micrograms/kg/min x 30 min), before and after L-tyrosine (B mg/kg iv bolus). Epinephrine administration significantly increased heart rate by 39% (p less than 0.05), and decreased repetitive extrasystole threshold by 33% (p less than 0.05). Mean arterial pressure and effective refractory period were unchanged. Following L-tyrosine, repetitive extrasystole threshold was restored to baseline levels. Tyrosine may thus ameliorate stress-induced increases in ventricular vulnerability to arrhythmias in conscious animals.

Physiological pharmacokinetics and pharmacodynamics of (+/-)-verapamil in female rats

Tissue distribution and pharmacodynamics of verapamil were evaluated during steady state intravenous (i.v.) infusion and after single dose intraperitoneal (i.p.) drug administration to female Sprague-Dawley rats. In one group of rats, verapamil was infused to a steady state concentration at which time animals were killed. Verapamil-induced decreases in mean arterial pressure (MAP) were monitored during infusion and correlated with concomitantly obtained plasma verapamil concentrations. Tissue (lung, liver, renal medulla, renal cortex, cardiac muscle, skeletal muscle, perirenal fat, brain stem, cerebral cortex, and cerebellum) and plasma samples were obtained immediately after animals were killed and verapamil and norverapamil concentrations determined. Another group of rats, after receiving i.p. verapamil, were killed at 1, 3, 5, 19, and 24 h. Elimination from each tissue evaluated was described by a first order process. Elimination half-life of verapamil was similar among plasma and tissues evaluated (1.5 to 2.2 h). The per cent verapamil not bound to plasma proteins was concentration-independent and similar between rats receiving i.p. (mean +/- S.D.) (2.28 +/- 0.72 per cent) and i.v. (2.08 +/- 0.03 per cent) verapamil. MAP and verapamil concentration in plasma (r = 0.75; p less than 0.01) and cardiac muscle (r = -0.82; p less than 0.01) were inversely correlated in a highly significant fashion during both i.v. and i.p. drug administrations. The tissue-to-plasma distribution ratio for verapamil and norverapamil was similar among animals receiving i.p. verapamil at all points of sampling, suggesting distribution equilibrium had been achieved. After steady state i.v. infusion, both verapamil and norverapamil tissue: plasma concentration ratios were greater than after i.p. administration. Higher tissue: plasma verapamil concentration ratios after i.v. administration than after i.p. administration suggest either only a pseudoequilibrium is attained after i.p. administration or that determinants of tissue distribution of racemic verapamil differ with different routes of drug administration. In these studies, MAP provided a reasonable pharmacodynamic marker for verapamil tissue and plasma concentrations.