Verapamil is a FDA approved drug used to treat high blood pressure and to control chest pain. Verapamil is an L-type calcium channel blocker that also has antiarrythmic activity. The R-enantiomer is more effective at reducing blood pressure compared to the S-enantiomer. However, the S-enantiomer is 20 times more potent than the R-enantiomer at prolonging the PR interval in treating arrhythmias. Verapamil inhibits voltage-dependent calcium channels. Specifically, its effect on L-type calcium channels in the heart causes a reduction in ionotropy and chronotropy, thuis reducing heart rate and blood pressure. Verapamil's mechanism of effect in cluster headache is thought to be linked to its calcium-channel blocker effect, but which channel subtypes are involved is presently not known.

Lercanidipine is antihypertensive drugs which acts by blocking L-type calcium channels, allowing relaxation and opening of blood vessels. Lercanidipine exists as a racemate, with anti-hypertensive activity residing primarily in S-enantiomer. NDA for lercanidipine was submitted to FDA in 2002 by Forest Laboratories, but FDA refused to approve the drug, and lercanidipine is not marketed in USA. Lercanidipine is also investigated in preclinical models of epilepsy and ischemic stroke.

(S)-Lercanidipine is enantiomer of antihypertensive drugs Lercanidipine, that acts by blocking L-type calcium channels, allowing relaxation and opening of blood vessels. The dihydropyridine calcium antagonists promote systemic vasodilatation by a reversible blockade of voltage-dependent Ca2+ influx through L-type channels in the cell membrane. (S)-Lercanidipine has 100- to 200-fold greater affinity than the (R)-enantiomer for the L-type calcium channel. The pharmacokinetics of (S)- Lercanidipine has been evaluated in healthy volunteers, in elderly and non-elderly patients with hypertension, and in patients with renal or hepatic impairment. Patients from these studies were investigated after receiving a single 10 or 20 mg dose of [14C]-labeled rac-Lercanidipine as a solution. The maximum plasma concentrations of (S)-Lercanidipine were reached within 2–3 h and the area under the plasma concentration-time curves were not linearly related to the dose, indicating a saturable first-pass metabolism. The absorption of (S)-LER increases after the ingestion of a high-fat meal. Lercanidipine is highly bound to plasma protein (>98%) in humans. Its volume of distribution of 2–2.5 L/kg was determined in healthy volunteers after intravenous infusion of 2 mg. Lercanidipine is extensively metabolized by CYP 3A4 to inactive pyridine derivatives. A crossover study involving a single administration of either 10 mg of (R)- or (S)-LER or 20 mg of rac-LER as a solution demonstrated no in vivo enantiomer interconversion

(R)-Lercanidipine is enantiomer of antihypertensive drugs Lercanidipine, that acts by blocking L-type calcium channels, allowing relaxation and opening of blood vessels. The dihydropyridine calcium antagonists promote systemic vasodilatation by a reversible blockade of voltagedependent Ca2+ influx through L-type channels in the cell membrane. (S)-Lercanidipine has 100- to 200-fold greater affinity than the (R)-enantiomer for the L-type calcium channel. The pharmacokinectics of (S)- Lercanidipine has been evaluated in healthy volunteers, in elderly and non-elderly patients with hypertension, and in patients with renal or hepatic impairment. Patients from these studies were investigated after receiving a single 10 or 20 mgdose of [14C]-labeled rac-Lercanidipine as a solution. The maximum plasma concentrations of (S)-Lercanidipine were reached within 2–3 h and the area under the plasma concentration–time curves were not linearly related to the dose, indicating a saturable first-pass metabolism. The absorption of (S)-LER increases after the ingestion of a highfat meal. Lercanidipine is highly bound to plasma protein (>98%) in humans. Its volume of distribution of 2–2.5 L/kg was determined in healthy volunteers after intravenous infusion of 2 mg. Lercanidipine is extensively metabolized by CYP 3A4 to inactive pyridine derivatives. A crossover study involving a single administration of either 10 mg of (R)- or (S)-LER or 20 mg of rac-LER as a solution demonstrated no in vivo enantiomer interconversion

Fimasartan is a angiotensin II receptor antagonist which was developed in Korea for the treatment of hypertension. The drug is available in different forms: Kanarb, Dukarb (in combination with Amlodipine), Tuvero (in combination with Rosuvastatin). Fimasartan was tested to be effective in Mexican and Russian population and now is being tested in the USA.

Fimasartan is a angiotensin II receptor antagonist which was developed in Korea for the treatment of hypertension. The drug is available in different forms: Kanarb, Dukarb (in combination with Amlodipine), Tuvero (in combination with Rosuvastatin). Fimasartan was tested to be effective in Mexican and Russian population and now is being tested in the USA.

Lercanidipine is antihypertensive drugs which acts by blocking L-type calcium channels, allowing relaxation and opening of blood vessels. Lercanidipine exists as a racemate, with anti-hypertensive activity residing primarily in S-enantiomer. NDA for lercanidipine was submitted to FDA in 2002 by Forest Laboratories, but FDA refused to approve the drug, and lercanidipine is not marketed in USA. Lercanidipine is also investigated in preclinical models of epilepsy and ischemic stroke.