Effect of physicochemical parameters on skin permeability of antihypertensive.

Studies were carried out to establish a correlation of skin permeability with physicochemical parameters using five antihypertensive drugs. In vitro skin permeation was carried out in vertical type diffusion cells. When steady-state fluxes of the drugs were correlated with physicochemical properties, good correlation was obtained with the reciprocal of melting point. Weak correlation was obtained with partition coefficient, molecular weight and solubility. However skin permeability versus solubility profiles revealed an interesting trend. The initial permeation rates of the poorly water soluble drugs, prazosin hydrochloride and reserpine were higher than their steady-state fluxes and moderately water soluble drug atenolol showed more or less similar permeation throughout the entire span of the study. This trend changed gradually and reversed completely in the highly water soluble drug diltiazem hydrochloride. The study suggests that drug derivatives of low melting point and good aqueous solubility could be favorable candidates for transdermal delivery.

Enhancer aided in vitro permeation of atenolol and prazosin hydrochloride through mice skin.

Effect of penetration enhancers were studied on the permeation of antihypertensive drugs prazosin hydrochloride and atenolol through full thickness skin of swiss albino mice. Atenolol was delivered to skin from saturated alcoholic solution containing 5% of 1-decanol and alcohol alone, while prazosin hydrochloride was saturated in dimethyl formamide(DMF, 5% v/v in water) and dimethyl sulfoxide(DMSO, 5% v/v in water). Atenolol permeation was augmented significantly in decanolic solution and also in pure alcohol. In case of prazosin hydrochloride, significant enhancement of permeation was shown by DMSO but not by DMF.

Comparison of skin permeability of drugs in mice and human cadaver skin.

In vitro percutaneous absorption of four antihypertensive drugs were carried out across the mice and human cavader skin in order to compare their skin permeability. An interesting trend was noticed in these experiments. Poorly water soluble drug prazosin hydrochloride showed 13 times enhanced flux in the mice skin whereas the steady-state flux of the water soluble drug propranolol hydrochloride was almost same in both human cadaver and mice skin. The permeation rate of prazosin hydrochloride and propranolol hydrochloride through the human cadaver skin fluctuated widely over time, but in mice skin, distinct trends were noticed. The study indicates that the overall permeation rate in mice skin is higher than that in the cadaver skin and the meeting of the target-flux in mice skin does not guarantee its good permeability in human skin.