Transethosomes: Cutting edge approach for drug permeation enhancement in transdermal drug delivery system.

The skin is a major route of drug administration. Despite the high surface area of the skin, drug delivery via the skin route is problematic due to its physiological obstacles. The formulation scientist has developed a vesicular system to enhance the skin's absorption of bioactive substances. Among numerous vesicular systems, concept of transethosomes (TEs) introduced in 2012 are being tested for drug delivery to the dermis. When transferosomes and ethosomes interact, TEs are produced. It consists of water, ethanol, phospholipids, and an edge activator. Ethanol and the edge activator increase the absorption of medication through the skin. In the presence of ethanol and an edge activator, skin permeability can increase. The advantages of TEs include increased patient compliance, bypassing first-pass metabolism, including non-toxic raw components, being a noninvasive method of drug delivery, being more stable, biocompatible, biodegradable, and administered in semisolid form. TEs can be produced through the use of hot, cold, mechanical dispersion, and conventional techniques. The morphology, shape, size, zeta potential, drug loading efficiency, vesicle yield, biophysical interactions, and stability of TEs define them. Recent studies reported successful transdermal distribution of antifungal, antiviral, anti-inflammatory, and cardiovascular bioactive while using ethosomes with significant deeper penetration in skin. The review extensively discussed various claims on TEs developed by researchers, patents, and marketed ethosomes. However, till today no patens being granted on TEs. There are still lingering difficulties related to ethanol-based TEs that require substantial research to fix.

Liranaftate loaded Xanthan gum based hydrogel for topical delivery: Physical properties and ex-vivo permeability.

A topical microemulsion (ME)-based hydrogel was developed to enhance permeation of an antifungal drug, liranaftate (LRFE) for effective eradication of cutaneous fungal infection. Pseudo-ternary phase diagrams were used to determine the existence of MEs region. ME formulations were prepared with Di-isopropyl adaptate, Cremophore-EL, Ethanol and distilled water. Xanthan Gum (1.5% w/w) was used for preparation of hydrogel of LRFE microemulsion (HLM) and characterized. The in-vitro and ex-vivo evaluation of prepared HLM and saturated drug solution were compared. The viscosity, average droplet size and pH of HLM were 142.30±0.42 to 165.15±0.21Pas, 52.53-93.40nm and 6.6-7.1, respectively. Permeation rate of LRFE from optimized formulation (HLM-3), composed with Di-isopropyl adaptate (4.5% w/w), Cremophor-EL (30% w/w), Ethanol (10% w/w) and water (52% w/w) was observed higher in compare with other HLMs and saturated drug solution. HLM-3 was stable, six times higher drug deposition capacity in skin than saturated drug solution and did not caused any erythema based on skin sensitivity study on rat. The average zone of inhibition of HLM-3 (25.52±0.26mm) was higher in compare with saturated drug solution (13.44±0.40mm) against Candida albicans.

Enhanced bioavailability of cinnarizine nanosuspensions by particle size engineering: Optimization and physicochemical investigations.

Cinnarizine (CIN), a poorly soluble drug with erratic bioavailability due to pH dependent solubility has limited advantage to formulate oral solid dosage forms in subject having low gastric acidity. In present study precipitation-ultrasonication was used to fabricate nanosuspensions of cinnarizine stabilized by Poly vinyl alcohol (PVA) to enhance the bioavailability. We investigated the effects of PVA concentration (X1) and solvent to antisolvent ratio (X2) on the quality attributes like mean particle size (Y1); % drug content (Y2); and time required to 90% drug release (Y3) via 3(2) factorial design. The morphology of nanosuspensions was found almost spherical by SEM observation. DSC and FT-IR studies revealed lack of significant interactions between CIN and PVA. Nanosuspensions of mean particle size 621.08 nm was achieved. The dissolution rate obtained from all formulations were markedly higher than pure CIN. Response surface methodology and optimized polynomial equations were used to select the optimal formulation i.e. 0.2% W/V of X1 and 1:42 of X2 to get the desired response Y1; 636.78 nm, Y2; 95.24% and Y3; 7.09 min that were in reasonable agreement with the observed value. The in-vivo study in rat demonstrated that Cmax and AUC0→12 values of nanosuspension were approximately 2.8-fold and 2.7-fold greater than that of reference preparation respectively.

Formulation and process optimization of naproxen nanosuspensions stabilized by hydroxy propyl methyl cellulose.

In present study precipitation-ultrasonication was used to obtain nanosuspensions of poorly water-soluble drug, naproxen (NPX). We investigated the effects of HPMC concentration (X1) and time of ultrasonication (X2) on imperative attributes like mean particle size (Y1), % drug content (Y2), and time required to 90% drug release (Y3) via 3(2) factorial design. The morphology of nanosuspensions was found almost spherical by SEM observation. DSC and XRD studies suggested slight crystalline change in drug. FT-IR revealed lack of significant interactions between NPX and HPMC. Nanosuspensions of mean particle size 530.55 nm was achieved. Dissolution rate obtained from all nanosuspensions were markedly higher than pure NPX. Response surface methodology and optimized polynomial equations were used to select optimal formulation i.e. 1.36%W/V of X1 and 13.9 min of X2 to get desired response Y1; 727.97 nm, Y2; 95.59% and Y3; 8.67 min that were in reasonable agreement with observed value.