Nitrendipine matrix type transdermal therapeutic systems could be prepared with the required flux having suitable mechanical properties.
P-Glycoprotein (P-gp), the most extensively studied ATP-binding cassette transporter, functions as a biological barrier by extruding toxic substances and xenobiotics out of cells. Drug efflux pumps such as P-gp play a functional role in determining the pharmacokinetics of drugs administered by oral and parenteral routes. Determining the activity of drug efflux transport proteins has important implications in the identification of substrates and/or inhibitors. The significant role of the small intestine in reducing the oral bioavailability of drugs is due to metabolic enzymes and efflux transporters. The role of cytochrome P-450 3A (CYP3A) and P-gp in intestinal drug disposition has been highlighted. This review examines the structure, localisation and functional role of P-gp, the mechanism of drug efflux and drug-herb interactions.
A buccal patch for systemic administration of carvedilol in the oral cavity has been developed using two different mucoadhesive polymers. The formulations were tested for in vitro drug permeation studies, buccal absorption test, in vitro release studies, moisture absorption studies and in vitro bioadhesion studies. The physicochemical interactions between carvedilol and polymers were investigated by Fourier transform infrared (FTIR) Spectroscopy. According to FTIR the drug did not show any evidence of an interaction with the polymers used and was present in an unchanged state. XRD studies reveal that the drug is in crystalline state in the polymer matrix. The results indicate that suitable bioadhesive buccal patches with desired permeability could be prepared. Bioavailability studies in healthy pigs reveal that carvedilol has got good buccal absorption. The bioavailability of carvedilol from buccal patches has increased 2.29 folds when compared to that of oral solution. The formulation AC5 (HPMC E 15) shows 84.85 + 0.089% release and 38.69 + 6.61% permeated through porcine buccal membrane in 4 hr. The basic pharmacokinetic parameters like the C max , T max and AUC total were calculated and showed statistically significant difference (P<0.05) when given by buccal route compared to that of oral solution.
Aims:The objective of the present study was to develop a bioadhesive bilayered buccal patch of Nimodipine (15 mg) using Eudragit Rs 100 as secondary layer and a primary layer with Hydroxy propyl methyl cellulose and Hydroxy propyl cellulose JF. Methodology: Bilayered buccal patches were prepared by solvent casting technique. The absence of physiochemical interactions between NMDP and the polymer were investigated by differential scanning calorimetry (DSC). Bilayered buccal patches of NMDP were evaluated for in vitro drug permeation through porcine buccal membrane, in vitro drug release, moisture absorption, surface pH, mechanical properties and in vitro bioadhesion. Results:The results indicated that suitable bioadhesive bilayered buccal patches with desired permeability could be prepared. The bioavailability study was performed in healthy humans in a crossover experimental design. Bioavailability studies revealed that nimodipine possessed good buccal absorption. The relative bioavailability of the optimized buccal patch was found to be 205% in comparison to 30 mg marketed oral tablet. The formulation CC3 showed 68.84 ± 1.4% release and 46.85 ± 5.1% of drug permeated
The current study aims to formulate an anti-hypertensive drug manidipine self-nanoemulsifying drug delivery system (SNEDDS) employing different novel polymers to enhance solubility and drug release manidipine. The optimal concentration of excipients chosen based on solubility study further confirmed by self-emulsification region of pseudo ternary phase diagram. Manidipine SNEDDS optimized employing box-behnken design (BBD) through the study of factors - the amount of capryol 90(A), cremophor RH40 (B) and triacetin (C) and responses -droplet size (Y1), zeta potential (Y2), and cumulative percentage of drug release after 60 minutes (Y3). All formulations were evaluated for particle size, zeta potential, polydispersity index, entrapment efficiency, drug content, and in-vitro drug release. The optimized formulation was characterized for FTIR, SEM, and stability studies. The study indicates that manidipine optimized formulation MF11 comprising of capryol 90 (40.0%), cremophor RH40 (10.0%) and triacetin (30.0%) exhibited minimum droplet size (76.5 ± 2.87), best zeta potential (-24.7 ± 1.31mV) and entrapment efficiency (98.23 ± 1.74%) content uniformity (99.12 ± 1.28%) maximum drug release (98.79 ± 1.68%). The fourier transform infrared spectroscopy (FTIR) studies of MF11 indicated no significant interaction amid the drug and formulation excipients. The scanning electron microscopy (SEM) data revealed that particle size is in the nanometer range with a zeta potential value >5 mV indicating higher absorption and stability. Accelerated stability studies indicated the formulation to be stable for 3 months. Hence the results revealed that application of SNEDDS formulation technique for manidipine increased solubility and drug release.
Objective: The aim was to formulate and evaluate self-nanoemulsifying drug delivery systems (SNEDDS) of ramipril, an antihypertensive drug to improve the solubility and bioavailability. Methods: Based on solubility studies oil phase (Sefsol 218), surfactant (Acrysol EL135), and cosurfactant (Transcutol P), respectively, were selected to prepare SNEDDS. Ramipril SNEDDS optimized employing box-Behnken design through the study of factors. All formulations were evaluated for particle size, zeta potential (ZP), polydispersity index (PDI), entrapment efficiency (EE), drug content, and in vitro drug release. The optimized formulation was characterized for Fourier transform infrared (FTIR), scanning electron microscopy (SEM), stability studies, and pharmacokinetic study. Results: The mean particle size, PDI, ZP, EE, content uniformity, and in vitro drug release profile of optimized ramipril-loaded SNEDDS (RF14) were found to be 75.3±2.21nm, 0.126±0.05, −24.4±5.78mV, 98.74±1.97%, 99.52±1.67%, and 98.65±1.73%, respectively. FTIR studies revealed that there is no incompatibility between drug and excipients, SEM images exhibited nanoparticles to be more porous and in spherical shape. Stability studies indicated formulation was stable for 6 months. In vivo studies were conducted for optimized formulation RF14, the Tmax was found to be 0.5±0.62 and 0.5±0.95 h for the optimized and commercial formulations respectively, while Cmax was 25.16±1.73 ng/mL was significant (p<0.05) as compared to the ramipril pure drug 8.02±0.086 ng/mL. AUC0-t of the SNEDDS formulation was higher 355.49±1.76ng h/ml compared to pure drug 116.57±1.64 ng h/ml indicated higher amount of drug concentration in blood proving better systemic absorption of ramipril from SNEDDS formulation as compared to the pure drug. Conclusion: It is concluded from the results that ramipril was successfully formulated into SNEDDS with higher concentration with fast action.
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