Labiba K. El-Khordagui

Hydrotropic agents: a new definition

Abstract The term hydrotropic agent was first introduced by Neuberg (1916) to designate anionic organic salts which, at high concentrations, considerably increase the aqueous solubility of poorly soluble solutes. In the present study, an attempt is made to extend the definition of the term to include cationic and non-ionic organic compounds bearing the essential structural features of Neubergs hydrotropes. The results obtained indicate that model planar cationic compounds such as p -aminobenzoic acid hydrochloride and procaine hydrochloride, and neutral molecules such as resorcinol and pyrogallol confer typical hydrotropic properties.

Effects of microneedle length, density, insertion time and multiple applications on human skin barrier function: Assessments by transepidermal water loss

Microneedle (MN) arrays have attracted considerable attention in recent years due to their ability to facilitate effective transdermal drug delivery. Despite appreciable research, there is still debate about how different MN dimensions or application modes influence permeabilization. This study aimed to investigate this issue by taking transepidermal water-loss measurements of dermatomed human skin samples following the insertion of solid polymeric MNs. Insertions caused an initial sharp drop in barrier function followed by a slower incomplete recovery - a paradigm consistent with MN-generation of microchannels that subsequently contract due to skin elasticity. While 600 μm-long MNs were more skin-perturbing than 400 μm MNs, insertion of 1000 μm-long MNs caused a smaller initial drop in integrity followed by a degree of long term permeabilization. This is explainable by the longest needles compacting the tissue, which then decompresses over subsequent hours. Multiple insertions had a similar effect as increasing MN length. There was some evidence that increasing MN density suppressed the partial barrier recovery caused by tissue contraction. Leaving MNs embedded in skin seemed to reduce the initial post-insertion drop in barrier function. Our results suggest that this in vitro TEWL approach can be used to rapidly screen MN-effects on skin.

Antimicrobial PLGA ultrafine fibers: Interaction with wound bacteria

The structure and functions of polymer nanofibers as wound dressing materials have been well investigated over the last few years. However, during the healing process, nanofibrous mats are inevitably involved in dynamic interactions with the wound environment, an aspect not explored yet. Potential active participation of ultrafine fibers as wound dressing material in a dynamic interaction with wound bacteria has been examined using three wound bacterial strains and antimicrobial fusidic acid (FA)-loaded electrospun PLGA ultrafine fibers (UFs). These were developed and characterized for morphology and in-use pharmaceutical attributes. In vitro microbiological studies showed fast bacterial colonization of UFs and formation of a dense biofilm. Interestingly, bacterial stacks on UFs resulted in a remarkable enhancement of drug release, which was associated with detrimental changes in morphology of UFs in addition to a decrease in pH of their aqueous incubation medium. In turn, UFs by allowing progressively faster release of bioactive FA eradicated planktonic bacteria and considerably suppressed biofilm. Findings point out the risk of wound reinfection and microbial resistance upon using non-medicated or inadequately medicated bioresorbable fibrous wound dressings. Equally important, data strongly draw attention to the importance of characterizing drug delivery systems and establishing material-function relationships for biomedical applications under biorelevant conditions.

Bioburden-responsive antimicrobial PLGA ultrafine fibers for wound healing.

Despite innovation in the design and functionalization of polymer nanofiber wound healing materials, information on their interaction with the biochemical wound environment is lacking. In an earlier study, we have reported the interaction of fusidic acid-loaded PLGA ultrafine fibers (UFs) with wound bacteria. Massive bacterial colonization and the formation of a dense biofilm throughout the mat were demonstrated. This was associated with a marked enhancement of initial drug release at concentrations allowing eradication of planktonic bacteria and considerable suppression of biofilm. The present study aimed at extending earlier findings to gain more mechanistic insights into the potential response of the fusidic acid-laden UFs under study to controlled microbial bioburden. Initial drug release enhancement was shown to involve surface erosion of the ultrafibrous mats likely mediated by microbial esterase activity determined in the study. Release data could be correlated with microbial bioburden over the inoculum size range 10³-10⁷ CFU/ml, suggesting a bioburden-triggered drug release enhancement mechanism. Moreover, the effectiveness of fusidic acid-laden UFs in the healing of either lightly contaminated or Staphylococcus aureus heavily infected wounds in a rat model suggested in-use relevant antimicrobial release patterns. Findings indicated active participation of polymer ultrafine wound dressings in a dynamic interaction with the wound milieu, which affects their structure-function relationship. Understanding such an interaction is fundamental to the characterization and performance assessment of wound materials under biorelevant conditions and the design of polymer-based infection-responsive biomaterials.

Propylene Glycol Liposomes as a Topical Delivery System for Miconazole Nitrate: Comparison with Conventional Liposomes

Propylene glycol (PG)-phospholipid vesicles have been advocated as flexible lipid vesicles for enhanced skin delivery of drugs. To further characterize the performance of these vesicles and to address some relevant pharmaceutical issues, miconazole nitrate(MN)-loaded PG nanoliposomes were prepared and characterized for vesicle size, entrapment efficiency, in vitro release, and vesicle stability. An issue of pharmaceutical importance is the time-dependent, dilution-driven diffusion of propylene glycol out of the vesicles. This was addressed by assessing propylene glycol using gas chromatography in the separated vesicles and monitoring its buildup in the medium after repeated dispersion of separated vesicles in fresh medium. Further, the antifungal activity of liposomal formulations under study was assessed using Candida albicans, and their in vitro skin permeation and retention were studied using human skin. At all instances, blank and drug-loaded conventional liposomes were included for comparison. The results provided evidence of controlled MN delivery, constant percent PG uptake in the vesicles (≈45.5%) in the PG concentration range 2.5 to 10%, improved vesicle stability, and enhanced skin deposition of MN with minimum skin permeation. These are key issues for different formulation and performance aspects of propylene glycol-phospholipid vesicles.

Development of a dissolution medium for glibenclamide

A dissolution medium for slightly soluble drugs was developed using glibenclamide as a model of such drugs. The medium consists of a hydroalcoholic surfactant solution with a relatively low alcohol and Tween 80 content buffered at pH 7.4. The composition of the medium was selected on the basis of solubility data at 37°C obtained according to a central composite experimental design. The discriminating power of the medium selected (phosphate buffer pH 7.4 containing 8.5% alcohol and 0.24% Tween 80) was assessed relative to that of phosphate buffer pH 7.4, a medium usually used for the dissolution testing of glibenclamide and borate buffer pH 9.5, a medium recently recommended by the FDA. The dissolution data obtained for two commercial brands of glibenclamide tablets indicate superiority of the proposed system as a discriminatory dissolution medium for glibenclamide tablets.

Alendronate PLGA microspheres with high loading efficiency for dental applications

Purpose: Alendronate sodium, used systemically as a bone protective agent, proved to also be effective locally in various dental bone applications. Development of alendronate-loaded microspheres with high loading efficiency for such applications would be greatly challenged by the hydrophilicity and low MW of the drug. The aim of this study was to incorporate alendronate sodium, into poly (lactide-co-glycolide) (PLGA) microspheres (MS) with high loading efficiency. Methods: Three multiple emulsion methods: water-in-oil-in-water (W/O/W), water-in-oil-in-oil (W/O1/O2) and solid-in-oil-in-oil (S/O1/O2) were tested. In addition to entrapment efficiency, MS were characterized for surface morphology, particle size, in vitro drug release and in vitro degradation of the polymer matrix. Alendronate microspheres with maximum drug loading and good overall in vitro performance were obtained using the W/O1/O2 emulsion technique. Results: Drug release from the microspheres exhibited a triphasic release pattern over a period of 13 days, the last fast release phase being associated with more rapid degradation of the PLGA matrix. Conclusions: Biocompatible, biodegradable PLGA microspheres incorporating alendronate sodium with high loading efficiency obtained in this study may offer promise as a delivery system for bisphosphonates in dental and probably other clinical applications.

Microneedle/nanoencapsulation-mediated transdermal delivery: Mechanistic insights

Graphical abstract Using PLGA nanoparticles (NPs) with similar size and zeta potential, skin permeation of nanocapsulated dyes across microneedle-treated skin is determined by the molecular characteristics. Findings are important for the microneedle-mediated transdermal and dermal delivery of nanocapsulated therapeutic agents.

Effect of microneedle treatment on the skin permeation of a nanoencapsulated dye

Objectives  The aim of the study was to investigate the effect of microneedle (MN) pretreatment on the transdermal delivery of a model drug (Rhodamine B, Rh B) encapsulated in polylactic‐co‐glycolic acid (PLGA) nanoparticles (NPs) focusing on the MN characteristics and application variables.

Liposomal formulation for dermal and transdermal drug delivery: past, present and future.

Although the formulation of effective topical drug delivery system is one of the most sophisticated pharmaceutical preparations, it has attracted researchers due to many medical advantages associated with it. Topical drug delivery systems can act superficially on skin surface, locally in dermal layer of the skin or transdermally to provide successful delivery of drug molecules to the systemic circulation avoiding the traditional problems and limitations of conventional routes of drug delivery. Many novel formulations have been utilized topically to enhance either permeability or drug targeting to a specific layer of the skin such as Liposomes, ethosomes, transfersomes, niosomes and catezomes. The main problem with all of these formulations is that there is no distinct barrier between the targeting and localization action to a certain layer of the skin and the transdermal action to the circulation of these preparations. Any minimal change in the formulation could transform it from a local targeting preparation to a systemic one. This article deals with the innovations pertaining to the use of various types of liposomal preparations and liposomal like preparations for topical drug delivery and the patents associated with it.