Exploring the Potent Combination of Quercetin-Boronic Acid, Epalrestat, and Urea Containing Nanoethosomal Keratolytic Gel for the Treatment of Diabetic Neuropathic Pain: In Vitro and In Vivo Studies.

Transdermal penetration of therapeutic moieties from topical dosage forms always remains a challenge due to the presence of permeation impeding keratin which should be addressed. The purpose of the study was to formulate quercetin and 4-formyl phenyl boronic acid (QB complex) used for the preparation of nanoethosomal keratolytic gel (EF3-G). The QB complex was confirmed by Fourier transform infrared spectroscopy while skin permeation, viscosity, and epalrestat entrapment efficiency were used for the optimization of nanoethosomal gel. The keratolytic effect of the proposed nanoethosomal gel with urea (QB + EPL + U) was calculated in rat and snake skin. The spherical shape of nanoethosomes was confirmed by scanning electron microscopy. According to the findings of stability studies, viscosity decreases as temperature increases, proving their thermal stability. The negative charge of optimized EF3 with 0.7 PDI proved narrow particle size distribution with homogeneity. Optimized EF3 showed two folds increase of epalrestat permeation in highly keratinized snake skin as compared to rats' skin after 24 h. Antioxidant behaviors of EF3 (QB) > QB complex > quercetin > ascorbic acid proved reduction of oxidative stress in DPPH reduction analysis. Interestingly, the hot plate and cold allodynia test in the diabetic neuropathic rat model reduced 3-fold pain as compared to the diabetic control group which was further confirmed by in vivo biochemical studies even after the eight week. Conclusively, ureal keratolysis, primary dermal irritation index reduction, and improved loading of epalrestat render the nanoethosomal gel (EF3-G) ideal for the treatment of diabetic neuropathic pain.

Formulation and evaluation of sustained release ocular inserts of betaxolol hydrochloride using arabinoxylan from Plantago ovata.

The purpose of the current studies was to develop ocular insert of betaxolol hydrochloride (BXH), using arabinoxylan (AX) as a film former. The inserts were prepared by sandwiching I mg of BXH between two films of AX. Six different formulations of ocular inserts were prepared in such a way that first three formulations contained varying concentrations of AX along with glycerol as plasticizer, whereas, rest of the formulations were added with 0.5mg of sodium alginate, sandwiched between two films of AX along with 1mg of BXH. Chemical compatibilities of the ingredients were assessed by using FTIR. Prepared ocular inserts were subjected to various physicochemical characterizations. The dissolution studies showed that ocular inserts containing sodium alginate with the AX showed sustained release effect better than the formulations with AX alone. Addition of sodium alginate resulted in inhibition of sudden release in initial phase and further sustained the release of drug from ocular inserts. Ocular inserts were pH compatible to the eyes as well as there was no interaction among the drug and excipients, suggesting that the selected excipients were suitable for the development of sustained release ocular inserts of BXH.