Prabhakar Reddy Veerareddy

Bioavailability enhancement of zaleplon via proliposomes: Role of surface charge.

The present systematic study focused to investigate the combined advantage of proliposomes and surface charge for improved oral delivery of zaleplon. The zaleplon loaded proliposomes were prepared using hydrogenated soyphosphatidylcholine (HSPC) and cholesterol (CHOL) in varying ratios, and the optimized formulation was tailored with dicetyl phosphate and stearylamine to obtain negative and positive charged vesicles, respectively. The formulations were characterized for micromeritics, size, zeta potential, and entrapment efficiency. Further, in vitro release and dissolution study carried out provide an insight on the stability and enhanced dissolution of zaleplon from proliposome formulations. The solid state characterization (SEM, DSC, and PXRD) studies unravel the transformation of zaleplon to amorphous or molecular state from the native crystalline form. To depict the conclusions, in situ single-pass perfusion and bioavailability studies were carried out in rats. The significant increase in effective permeability coefficient (Peff) and rate and extent of absorption from cationic vesicles indicate the importance of surface charge for effective uptake across the gastrointestinal tract. Overall a two- to fivefold enhancement in bioavailability in comparison with control confers the potential of proliposomes as suitable carriers for improved oral delivery of zaleplon.

Enhanced bioavailability of exemestane via proliposomes based transdermal delivery.

Exemestane, a novel steroidal aromatase inactivator used in the treatment of advanced breast cancer has limited bioavailability (42%) due to poor solubility, extensive first-pass metabolism, and also the absorption is dependent on formulation type and food. The present study is aimed to evaluate the feasibility of proliposomes for transdermal delivery of exemestane. The prepared proliposomes were characterized for size, zeta potential, and entrapment efficiency. The size of the vesicles was found to be between 440 and 700 nm with high entrapment efficiency for the formulation containing greater amounts of phosphatidylcholine. Differential scanning calorimetry and Fourier transform infrared studies were performed to understand the phase transition behavior and mechanism for skin permeation, respectively. The drug release across cellophane membrane follows zero-order kinetics by diffusion. Ex vivo permeation enhancement assessed from flux, permeability coefficient, and enhancement ratio were significantly higher for proliposome gels compared with control. A significant improvement in the bioavailability (2.4-fold) was observed from optimized proliposome gel compared with control (oral suspension). The stability data reveal that the formulations are more stable when stored at 4°C. In conclusion, proliposomal gels offer potential and prove to be efficient carriers for improved and sustained transdermal delivery of exemestane.

Solubility enhancement and physicochemical characterization of carvedilol solid dispersion with Gelucire 50/13

The objective of the study was enhancement of dissolution of poorly soluble carvedilol by solid dispersions (SDs) with Gelucire 50/13 using solvent evaporation method. The solubility of carvedilol showed linear increase with increasing concentrations of Gelucire indicating AL type solubility diagrams. SDs characterized for physicochemical characteristics using differential scanning calorimetry and X-ray diffractometry revealed transformation of crystalline form of drug to amorphous form which was confirmed by scanning electron micrographs. Further fourier transform infrared spectroscopy results suggested there is no drug carrier interaction. From the dissolution parameters such as mean dissolution time, dissolution efficiency and drug release rate, improved dissolution characteristics for SDs were observed compared with physical mixture and pure drug. Thus SDs of carvedilol in Gelucire 50/13 showed enhanced solubility and dissolution rate compared to pure drug.

Formulation, evaluation and pharmacokinetics of colon targeted pulsatile system of flurbiprofen

Objective: The intent of the present investigation is to develop colon targeted compression coated flurbiprofen pulsatile release tablets that retard the drug release in the upper gastro intestinal system but progressively release in the colon. Materials and methods: Flurbiprofen core tablets were prepared by direct compression method and were compression coated with hydroxypropyl methylcellulose and Eudragit S100. The formulation is optimized based on the in vitro drug release study and further evaluated by X-ray imaging and pharmacokinetic studies in healthy humans for colonic delivery. Results and discussions: The optimized formulation showed negligible drug release (7.26 ± 0.05%) in the initial lag period followed by progressive release (99.27 ± 0.46%) for 24 h. The X-ray imaging study in human volunteers showed that the tablets reached the colon without disintegrating in the upper gastrointestinal tract. The Cmax of colon targeted tablets was 10792.62 ng/mL at Tmax 10 h where as in case of immediate release tablets the Cmax was 15684.79 ng/mL at Tmax 3 h signifies the ability of compression coated tablets to target the colon. Conclusion: Development of pulsatile release compression coated tablets using combination of time dependent and pH sensitive approaches was suitable to target the flurbiprofen to colon.

Improved oral bioavailability of fexofenadine hydrochloride using lipid surfactants: ex vivo, in situ and in vivo studies.

Abstract The aim of the present study was to improve the dissolution, permeability and therefore oral bioavailability of the fexofenadine hydrochloride (FEX), by preparing lipid surfactant based dispersions using self-emulsifying carriers, i.e. Gelucire 44/14 (GLC) and d-α-tocopheryl polyethylene glycol 1000 succinate (Vitamin E TPGS or TPGS). The reprecipitation studies were conducted using these carriers to evaluate inhibition of reprecipitation by maintaining super saturation state. The aqueous solubility of the FEX was increased linearly with increasing GLC, TPGS concentrations as verified by the phase solubility studies. The dispersions of FEX were prepared in different drug/GLC (GD) and drug/TPGS (TD) ratios by melt method and evaluated. The prepared dispersions showed improved dissolution rate in distilled water as dissolution media and highest dissolution rate was achieved with dispersions prepared using TPGS. The solid state characterization was carried by differential scanning calorimetry and scanning electron microscopy indicated reduced crystallinity of the drug. Fourier transform infrared spectroscopy revealed the compatibility of drug with carriers. The ex vivo permeation studies conducted using intestinal gut sac technique, resulted in reduced efflux of the drug by inhibiting intestinal P-glycoprotein from the dispersions. The in situ perfusion studies and in vivo pharmacokinetic studies in male wistar rats showed improved absorption and oral bioavailability from the prepared dispersions as compared to pure drug.

Development, evaluation and pharmacokinetics of time-dependent ketorolac tromethamine tablets

Objective: The present study was intended to develop a time-dependent colon-targeted compression-coated tablets of ketorolac tromethamine (KTM) using hydroxypropyl methylcellulose (HPMC) that release the drug slowly but completely in the colonic region by retarding the drug releases in stomach and small intestine. Methods: KTM core tablets were prepared by direct compression method and were compression coated with HPMC. The formulation is optimized based on the in vitro drug release studies and further evaluated by X-ray imaging technique in healthy humans to ensure the colonic delivery. To prove these results, in vivo pharmacokinetic studies in human volunteers were designed to study the in vitro–in vivo correlation. Results and discussions: From the in vitro dissolution study, optimized formulation F3 showed negligible drug release (6.75 ± 0.49%) in the initial lag period followed by slow release (97.47 ± 0.93%) for 24 h which clearly indicates that the drug is delivered to the colon. The X-ray imaging studies showed that the tablets reached the colon without disintegrating in upper gastrointestinal system. From the pharmacokinetic evaluation, the immediate-release tablets producing peak plasma concentration (Cmax) was 4482.74 ng/ml at 2 h Tmax and colon-targeted tablets showed Cmax = 3562.67 ng/ml at 10 h Tmax. The area under the curve for the immediate-release and compression-coated tablets was 10595.14 and 18796.70 ng h/ml and the mean resident time was 3.82 and 10.75 h, respectively. Conclusion: Thus, the compression-coated tablets based on time-dependent approach were preferred for colon-targeted delivery of ketorolac.

In situ absorption and relative bioavailability studies of zaleplon loaded self-nanoemulsifying powders

Self-nanoemulsifying drug delivery systems (SNEDDSs) offer potential as suitable carriers for improved oral delivery of poorly soluble and low bioavailable drugs. To derive self-nanoemulsifying powders (SNEPs), the optimized Z-SNEDDS formulation was adsorbed onto different carriers and based on micromeritics the formulation loaded onto neusilin US2 (SNEP-N) was selected for further characterization. The solid-state characterization (scanning electron microscopy, differential scanning calorimetry and powder X-ray diffraction) studies unravel the transformation of native crystalline state to amorphous and/or molecular state. The higher predictive effective permeability coefficient and fraction absorbed in humans extrapolated from in situ single-pass intestinal absorption study data in rats provide an insight on the potential of SNEPs for augment in absorption across gastrointestinal barrier. Overall a 3.5-fold enhancement in the extent of absorption of zaleplon from SNEP-N formulation proves the feasibility of SNEPs formulation for improved oral delivery of zaleplon.

Proliposome powders for enhanced intestinal absorption and bioavailability of raloxifene hydrochloride: effect of surface charge

The primary goal of the present study was to investigate the combined prospective of proliposomes and surface charge for the improved oral delivery of raloxifene hydrochloride (RXH). Keeping this objective, the present systematic study was focused to formulate proliposomes by varying the ratio of hydrogenated soyphosphatidylcholine and cholesterol. Furthermore, to assess the role of surface charge on improved absorption of RXH, anionic and cationic vesicles were prepared using dicetyl phosphate and stearylamine, respectively. The formulations were characterized for size, zeta potential and entrapment efficiency. The improved dissolution characteristics assessed from dissolution efficiency, mean dissolution rate were higher for proliposome formulations. The solid state characterization studies indicate the transformation of native crystalline form of the drug to amorphous and/or molecular state. The higher effective permeability coefficient and fraction absorbed in humans extrapolated from in situ single-pass intestinal absorption study data in rats provide an insight on the potential of proliposomes and cationic surface charge for augment in absorption across gastro intestinal barrier. To draw the conclusions, in vivo pharmacokinetic study carried out in rats indicate a threefold enhancement in the rate and extent of absorption of RXH from cationic proliposome formulation which unfurl the potential of proliposomes and role of cationic charge for improved oral delivery of RXH.

Paliperidone-Loaded Self-Emulsifying Drug Delivery Systems (SEDDS) for Improved Oral Delivery

The present research is aimed to improve the oral delivery of paliperidone by loading into self-emulsifying drug delivery systems (SEDDS). Oleic acid, Tween 80, and capmul MCM L8 were selected as oil, surfactant, and co-surfactant, respectively and phase diagram was constructed and the region was identified for the formation of SEDDS. The stable formulations were analyzed for globule size, robustness to dilution and in vitro drug release. The globule size of all the formulations was found to be in the range of 205 to 310 nm with good size uniformity and seems to be dependent on the proportion of oil in SEEDS formulation. The optimized formulation (F3) has been adsorbed onto neusilin and characterized. The DSC and XRD spectra unravel the presence of molecular state of paliperidone in solid SEDDS. The in vitro dissolution study indicates improved dissolution characteristics with higher dissolution efficiency for solid SEDDS (SEDDS-N) compared to pure drug. Further ex vivo permeation studies carried out using rat intestine suggest a 2- to 3-fold improvement in permeation for SEDDS compared to pure drug. In conclusion, SEDDS prove to be potential carriers for improved oral delivery of paliperidone.

Enhanced oral bioavailability of isradipine via proniosomal systems

The objective of the present research was to develop a proniosomal formulation of isradipine and to evaluate the influence of proniosomal systems on the oral bioavailability of the drug in albino Wistar rats. Proniosomes were prepared by film deposition on carrier’s method using various molar ratios of nonionic surfactants such as span20, span40, span60, and span80 with cholesterol as membrane stabilizing agent and dicetylphosphate as a charge inducer. The formation of niosomes and surface morphology of proniosome formulations were studied by optical and scanning electron microscopy (SEM), respectively. The prepared proniosomes have shown higher dissolution of isradipine compared with pure drug powder. Fourier transform infrared spectroscopy, differential scanning calorimetry, and powder X-ray diffractometry studies were performed to understand the solid state properties of the drug. Ex vivo permeation enhancement assessed from flux, permeability coefficient, and enhancement ratio were significantly higher for proniosomes compared with control. The pharmacokinetic parameters were evaluated in male albino Wistar rats and a significant enhancement in the bioavailability (2.3-fold) was observed from optimized proniosome formulation compared with control (oral suspension). The stability study reveals that the proniosome formulations are stable when stored at 4°C.