Pharmacokinetics of a losartan potassium released from a transdermal therapeutic system for the treatment of hypertension.

Monolithic transdermal therapeutic systems (TTS) were developed for sustained antihypertensive effect of losartan potassium using the polymers Eudragit E 100 and polyvinyl pyrrolidone VA 64. The developed formulations (polymeric films) were evaluated for physical characteristics, ex vivo (histopathology) and in vivo (pharmacokinetic studies). Pharmacokinetic parameters, such as C(max), t(max), and AUC were estimated. The transdermal formulation in the present study was found to enhance the relative bioavailability of losartan potassium by 2.2 times with reference to an oral delivery. The increased bioavailability might be due to elimination of hepatic first pass metabolism. Thus, the transdermal formulation F3E with polymeric composition of Eudragit E 100 and polyvinyl pyrrolidone VA 64 (5:3) was found to provide prolonged steady state concentrations of losartan potassium with minimal fluctuations and improved bioavailability.

Transdermal therapeutic system of enalapril maleate using piperidine as penetration enhancer.

The aim of this work was to formulate transdermal therapeutic system (TTS) of an antihypertensive drug, enalapril maleate (EM) using a new penetration enhancer, piperidine hydrochloride (PH), belonging to the class of Dihydropyridines. The TTS of EM was prepared by solvent evaporation technique using polymers Eudragit E100 and polyvinyl pyrrolidone K-30 in varying ratios, 5% w/w dibutylphthalate as plasticizer and 10% w/w PH as penetration enhancer. The TTS was evaluated for in-vitro drug release using paddle over disc method and ex-vivo skin permeation using modified Keshary and Chein diffusion cell. The interaction studies were carried out by comparing the results of assay, UV and TLC analysis for pure drug and medicated and TTS formulation. Skin irritation potential of TTS was assessed by visual examination of treated rat skin. Stability studies were conducted according to ICH guidelines at a temperature of 40+/-0.5 degrees C and 75+/-5% RH. The optimized formulation was evaluated for preclinical bioavailability and antihypertensive efficacy using albino rat model. The optimized formulation provided 87.3% drug release in-vitro and a flux of 380 microg/cm(2)/hr over a period of 48 hours. No chemical interaction was found between the drug and excipients and there were no signs of skin irritation on application of patch. The optimized formulation was stable with a tentative shelf life of two years. Significant fall in BP (p<0.001) was observed in experimental hypertensive rats which was maintained for 2 days. There was 3 fold improvement in bioavailability with TTS vis-à-vis marketed tablet (AUC(0 to t) : 1253.9 ng.h/ml vs. 422.88 ng.h/ml). These preclinicial studies indicate the feasibility of matrix-type TTS of EM for 2 day management of hypertension. Further studies on human beings are warranted to establish clinical utility of the above TTS.

Antipsoriatic microemulsion gel formulations for topical drug delivery of babchi oil (Psoralea corylifolia).

The aim of this study was to investigate and evaluate a microemulsion gel-based system of babchi oil (Psoralea corylifolia) for the treatment of psoriasis, which could provide improved permeation of the drug through the skin and increased patient compliance. Babchi oil is used because its chief constituent psoralen is a photoactive furocoumarin that binds to DNA when exposed to UV light to form photoproducts with pyrimidine base. This action inhibits DNA synthesis and causes decrease in cell proliferation. Moreover, babchi oil, in addition to providing psoralen, also acts as an oily phase for microemulsion system. The presence of surfactant and cosurfactant increases the permeation. On the basis of qualitative and quantitative estimation of all eight brands of babchi oil, Bakuchi Tail was selected for microemulsion formulation. Microemulsions were prepared by aqueous phase-titration method. Pseudoternary phase diagrams were constructed for the identification of microemulsion existence zones. Prepared microemulsions were subjected to different thermodynamic stability tests and characterized for droplet size, viscosity and refractive index. In vitro skin permeation of babchi oil through rat abdominal skin was determined by the Franz diffusion cell. The in vitro skin permeation profile of formulation F2, which consisted of 1.67% v/v of babchi oil, 8.33% v/v of oleic acid, S(mix) 55% v/v of Tween 80 Transcutol-P (S/Co ratio 1:1) and 35% v/v of distilled water, was significant when compared with other microemulsion formulations (p < 0.05). Formulation F2 was converted into microemulsion gel by adding 1% Carbopol-940 and coded as MGF2. Formulation MGF2 was selected for its in vivo antiinflammatory effects determined by footpad edema. The results suggested that microemulsion gel is a potential vehicle for improved topical delivery of psoralen and that microemulsion gels are potential vehicles for improved topical delivery of babchi oil.

Liposomal drug delivery systems: an update review.

The discovery of liposome or lipid vesicle emerged from self forming enclosed lipid bi-layer upon hydration; liposome drug delivery systems have played a significant role in formulation of potent drug to improve therapeutics. Recently the liposome formulations are targeted to reduce toxicity and increase accumulation at the target site. There are several new methods of liposome preparation based on lipid drug interaction and liposome disposition mechanism including the inhibition of rapid clearance of liposome by controlling particle size, charge and surface hydration. Most clinical applications of liposomal drug delivery are targeting to tissue with or without expression of target recognition molecules on lipid membrane. The liposomes are characterized with respect to physical, chemical and biological parameters. The sizing of liposome is also critical parameter which helps characterize the liposome which is usually performed by sequential extrusion at relatively low pressure through polycarbonate membrane (PCM). This mode of drug delivery lends more safety and efficacy to administration of several classes of drugs like antiviral, antifungal, antimicrobial, vaccines, anti-tubercular drugs and gene therapeutics. Present applications of the liposomes are in the immunology, dermatology, vaccine adjuvant, eye disorders, brain targeting, infective disease and in tumour therapy. The new developments in this field are the specific binding properties of a drug-carrying liposome to a target cell such as a tumor cell and specific molecules in the body (antibodies, proteins, peptides etc.); stealth liposomes which are especially being used as carriers for hydrophilic (water soluble) anticancer drugs like doxorubicin, mitoxantrone; and bisphosphonate-liposome mediated depletion of macrophages. This review would be a help to the researchers working in the area of liposomal drug delivery.

Fabrication and evaluation of polymeric films for transdermal delivery of pinacidil.

The objective of the present work was to fabricate Eudragit RL 100-polyvinyl acetate films and evaluate their potential for transdermal drug delivery in a quest to develop a suitable transdermal therapeutic system for pinacidil. The polymeric films (composed of Eudragit RL100 and polyvinyl acetate in 2:8, 4:6, 6:4, 8:2 ratios in films P-1, P-2, P-3, P-4 respectively, together with 5% w/w of pinacidil and 5% w/w of dibutylphthalate in all the films) were cast on a glass substrate and evaluated for physicochemical parameters viz. thickness, weight, folding endurance (a measure of fragility), percent elongation at break (a measure of flexibility), drug content uniformity, water absorption capacity, moisture vapour transmission, drug-polymer interaction, in vitro drug release and skin permeation profiles. The films were also evaluated for appearance, smoothness and transparency. The film finally selected was assessed for its skin irritation potential, and its stability on storage under accelerated temperature and humidity conditions. The values of thickness, weight, folding endurance, percent elongation at break, percentage water absorbed, moisture vapour transmission, cumulative amount of drug released and permeated for different films were in the following order: P-1 < P-2 < P-3 < P-4. The results suggest that Eudragit RL 100, a freely permeable polymer, has a major influence on the physicochemical profile of the films. The higher the quantity of Eudragit RL100 in the film, the better its strength and flexibility as well as its higher drug release and skin permeation potential. The final optimized film (with a composition of Eudragit RL 100: polyvinyl acetate: pinacidil monohydrate: dibutylphthalate in 8.0:2.0:0.5:0.5 ratio) was found to be the best in terms of drug release (cumulative amount of drug released in 48 h was 96.09%) and skin permeation (permeability coefficient, 0.0164 cm/h). There was no apparent drug-polymer interaction in the films. The optimized film was seemingly free of potentially hazardous skin irritation. The film was found to be stable and intact at ambient temperature and humidity conditions. The films hold promise for the development of a matrix type transdermal therapeutic system for pinacidil.