Solid self-nanoemulsifying drug delivery system (S-SNEDDS) of darunavir for improved dissolution and oral bioavailability: In vitro and in vivo evaluation.

The current study was aimed to investigate the potential of solid self-nanoemulsifying drug delivery system (S-SNEDDS) composed of Capmul MCM C8 (oil), Tween 80 (surfactant) and Transcutol P (co-surfactant) in improving the dissolution and oral bioavailability of darunavir. Liquid self-nanoemulsifying drug delivery systems (L-SNEDDS) were developed by using rational blends of components with good solubilizing ability for darunavir which were selected based on solubility studies, further ternary phase diagram was constructed to determine the self-emulsifying region. The prepared L-SNEDDS formulations were evaluated to determine the effect of composition on physicochemical parameters like rate of emulsification, clarity, phase separation, thermodynamic stability, cloud point temperature, globule size and zeta potential. In vitro drug release studies showed initial rapid release of about 13.3 ± 1.4% within 30 min from L-SNEDDS followed by slow continuous release of entrapped drug and reached a maximum of 62.6 ± 3.5% release at the end of 24h. The globule size analysis revealed the formation of nanoemulsion (144 ± 2.3 nm) from the optimized L-SNEDDS formulation and was physically adsorbed onto neusilin US2. In vitro dissolution studies indicated faster dissolution of darunavir from the developed S-SNEDDS with 3 times greater mean dissolution rate (MDR) compared to pure darunavir. Solid state studies concluded the presence of drug in non-crystalline amorphous state without any significant interaction of drug with the components of S-SNEDDS. Furthermore, in vivo pharmacokinetic studies in Wistar rats resulted in enhanced values of peak drug concentration (Cmax) for L-SNEDDS (2.98 ± 0.19 µg/mL) and S-SNEDDS (3.7 ± 0.28 µg/mL) compared to pure darunavir (1.57 ± 0.17 µg/mL).

Development of isradipine loaded self-nano emulsifying powders for improved oral delivery: in vitro and in vivo evaluation.

Isradipine (ISR) is a potent calcium channel blocker with low oral bioavailability due to low aqueous solubility, extensive first-pass metabolism and P-glycoprotein (P-gp)-mediated efflux transport. In the present investigation, an attempt was made to develop isradipine-loaded self-nano emulsifying powders (SNEP) for improved oral delivery. The liquid self-nano emulsifying formulations (L-SNEF/SNEF) of isradipine were developed using vehicles with highest drug solubility, i.e. Labrafil® M 2125 CS as oil phase, Capmul® MCM L8 and Cremophor® EL as surfactant/co-surfactant mixture. The developed formulations revealed desirable characteristics of self-emulsifying system such as nano-size globules ranging from 32.7 to 40.2 nm, rapid emulsification (around 60 s), thermodynamic stability and robustness to dilution. The optimized stable self-nano emulsifying formulation (SNEF2) was transformed into SNEP using Neusilin US2 (SNEP(N)) as adsorbent inert carrier, which exhibited similar characteristics of liquid SNEF. The solid state characterization of SNEP(N) by Fourier transform infrared spectroscopy, differential scanning calorimetry, powder X-ray diffraction and scanning electron microscopic studies shown transformation of crystalline drug into amorphous form or molecular state without any chemical interaction. The in vitro dissolution of SNEP(N) compared to pure drug was indicated by 18-fold increased drug release within 5 min. In vivo pharmacokinetic studies in Wistar rats showed significant improvement of oral bioavailability of isradipine from SNEP(N) with 3- and 2.5-fold increments in peak drug concentration (C(max)), area under curve (AUC(0-∞)) compared to pure isradipine. In conclusion, these results signify the improved oral delivery of isradipine from developed SNEP.

Development of a self-microemulsifying drug delivery system of domperidone: In vitro and in vivo characterization.

The main objective of this work was to prepare a self-micro emulsifying drug delivery system (SMEDDS) for enhancement of oral bioavailability of domperidone, a poorly water soluble drug. The solubility of the drug was determined in various vehicles. A pseudo ternary phase diagram was constructed to identify the self-micro emulsification region. The in vitro self-micro emulsification properties and droplet size analysis of SMEDDS were studied following their addition to water under mild agitation. Further, the resultant formulations were investigated for clarity, phase separation, globule size, effect of pH and dilutions (1:100, 1:500, 1:1000) and freeze-thaw stability. The optimized formulation, SMEDDS-B used for in vitro dissolution and bioavailability assessment, contained oil (Labrafac CC, 25 %, m/m), surfactant (Tween 80, 55 %, m/m), and co-surfactant (Transcutol®, 20 %, m/m). The preliminary oral bioavailability of domperidone from SMEDDS was 1.92-fold higher compared to that of domperidone suspension in rats. The AUC0-24 and cmax values were 3.38 ± 0.81 µg h mL-1 and 0.44 ± 0.03 µg mL-1 for SMEDDS-B formulation in comparison with 1.74 ± 0.18 µg h mL-1 and 0.24 ± 0.02 µg mL-1 for domperidone suspension, suggesting a significant increase (p < 0.05) in oral bioavailability of domperidone from SMEDDSS.

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.

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.

Formulation and pharmacokinetics of diclofenac lipid nanoemulsions for parenteral application.

The objective of the present study was to formulate and determine the pharmacokinetics of stable o/w parenteral lipid nanoemulsions (LNEs) of diclofenac acid used to treat arthritic conditions. The LNEs of diclofenac acid with a mean size ranging from 200 to 240 nm and a zeta potential of -29.4 ± 1.04 mV (negatively charged LNEs) and 62.1 ± 3.5 (positively charged LNEs) emulsions were prepared by hot homogenization and ultrasonication process. The influence of formulation variables, such as the change in proportion of cholesterol, was studied, and optimized formulations were developed. The optimized formulations were relatively stable during centrifugal stress, dilution stress, and storage. The drug content and entrapment efficiency were determined using high-performance liquid chromatography. The in vitro drug release was carried out in phosphate-buffered saline pH 7.4 and cumulative amount of drug released was estimated using a UV-visible spectro-photometer. During in vivo pharmacokinetic studies in male Wistar rats, diclofenac serum concentration from LNEs was higher than that of Voveran injection and was detectable up to 12 h. Diclofenac in LNEs showed improved pharmacokinetic profile with increase in area under the curve, elimination half-life and mean residence time in comparison to Voveran. LAY ABSTRACT: Our aim was to prepare and determine the pharmacokinetics of injectable lipid nanoemulsions of diclofenac acid for treating arthritic conditions by reducing the frequency of dosing and pain at site of injection. The nanoemulsions of diclofenac acid were prepared by homogenization and ultrasonication process. The sizes and charges of oil globules were determined. The effect of cholesterol on stability of emulsion was studied, and an optimized preparation was developed. The optimized formulations were stable during centrifugation, dilution, and storage. The total amount of drug in emulsion and percentage amount of drug present in emulsion globules were determined using high-performance liquid chromatography. The drug release from preparation was carried out in phosphate-buffered saline pH 7.4. The cumulative amount of drug released was estimated using a spectrophotometer. The time course of the released drug in rat serum was determined. Diclofenac concentrations from lipid nanoemulsions were higher than that of Voveran injection (solution form) in serum.

Albumin coupled lipid nanoemulsions of diclofenac for targeted delivery to inflammation.

Diclofenac lipid nanoemulsions (DLNEs) were prepared with different compositions. Based on size, PDI, zeta potential, and in vitro drug release, the optimized DLNEs (DLNE-4 and DLNE-7) were developed and evaluated for drug content, entrapment efficiencies, and stability in comparison to the control formulation (DLNE-1). The albumin was coupled to DLNE-7 globules (DLNE-8) by water soluble carbodiimide (EDC) method, purified, and quantified by modified Bradford method. The pharmacokinetic study was conducted in inflammation (granuloma air pouch model) induced rats. The maximum peak concentration of DLNE-8 was almost fourfold to fivefold in comparison to drug solution in granuloma air pouch fluid (GAPF). The therapeutic availability (TA) of DLNE-8 was 2.89, 2.34, and 1.66 times that of drug solution, DLNE-4 and DLNE-7, respectively. The GAPF/serum ratio of diclofenac from DLNE-8 was above one at all time points indicating the targeting potential of albumin ligated LNEs to inflammatory sites. FROM THE CLINICAL EDITOR: This study demonstrates targeted delivery of diclofenac to an inflammatory environment using the granuloma air pouch model and diclofenac nanoemulsions with different compositions.

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.

Development of indinavir submicron lipid emulsions loaded with lipoamino acids-in vivo pharmacokinetics and brain-specific delivery.

The aim of our present work was to develop indinavir O/W submicron lipid emulsions (SLEs) loaded with lipoamino acids for specific delivery to brain. Tetradecyl aspartic acid (A) and decyl glutamic acid (G) loaded stable SLEs of indinavir having a mean size range of 210-220 nm and average zeta potential of -23.54±1.2 mV were developed using homogenization and ultrasonication. The cumulative % drug release from different SLEs varied in between 26% and 85%. The formulations, SLE, SLE-A3, and SLE-G3 were stable to the centrifugal stress, dilution stress, and storage at RT. The total drug content and entrapment efficiency were determined by HPLC method. During pharmacokinetic studies in male Wistar rats there was no significant difference in the serum levels of indinavir for SLE, SLE-A3 and SLE-G3 formulations at all time points. In tissue distribution studies, the therapeutic availability (TA) of indinavir in brain and kidneys for SLE-A3 were 4.27- and 2.66-fold whereas for SLE-G3 were 2.94 and 2.12 times, respectively, higher than that of indinavir solution. But when compared with that of SLE, in brain tissue the levels of indinavir from SLE-G3 and SLE-A3 varied in between 2.5- and 3.38-fold. While in case of the kidney, it was between 1.23- and 1.54-fold only. However, the TA is not significantly different in tissues like the heart, liver, and spleen. Thus, brain-specific delivery of indinavir was improved by including tetradecyl aspartic acid and decyl glutamic acid in submicron lipid emulsions.

Brain specific delivery of pegylated indinavir submicron lipid emulsions.

The aim of this study was to develop stable parenteral pegylated indinavir submicron lipid emulsions (SLEs) for improving brain specific delivery. The O/W SLEs were prepared by homogenization and ultra sonication process. The sizes of oil globules varied from 241.5 to 296.4nm and zeta potential from -26.6 to -42.4mV. During in vitro drug release studies the cumulative amount of drug released within 12h from SLE-5, DSP2-3 and DPP5-3 was 71.8±0.76, 66.09±1.45 and 68.33±1.29, respectively. The total drug content and entrapment efficiencies were determined. The optimized formulations were stable for the effect of centrifugal stress, thermal stress, dilution stress and storage. In vivo pharmacokinetic and tissue distribution studies were performed in Swiss albino mice, the therapeutic availability (TA) of DSP2-3 was 3.59 times and 2.36 times in comparison to drug solution and SLE-5 respectively, where as DPP5-3 showed TA 2.8 and 1.84 times the drug solution and SLE-5, respectively. The brain to serum ratio of indinavir from DSP2-3 and DPP5-3 varied between 0.4 and 0.7 at all time points indicated the preferential accumulation of drug in brain. In conclusion, pegylated SLEs improved brain specific delivery of indinavir and will be useful in treating chronic HIV infection.