Ethosomes: a potential nanovesicular carrier to enhancing the drug delivery against skin barriers.

Ethosomes, which are liposomes like structures, mainly composed primarily of ethanol, have attracted considerable attention due to their potential to enhance the drug permeation via skin. The article discusses the formulation and preparation methods of ethosomes, offering insights into the various factors that influence their size, shape, and stability. Moreover, it explores the techniques used to assess the physicochemical properties of ethosomes and their impact on drug delivery effectiveness. The article also elucidates the mechanism by which ethosomes enhance skin permeation, emphasising their ability to modify the lipid structure and fluidity of the stratum corneum. Additionally, the review investigates the applications of ethosomes in diverse drug delivery scenarios, including the delivery of small molecules, peptides, and phytoconstituents. It highlights the potential of ethosomes to improve drug bioavailability, extend drug release, and achieve targeted delivery to specific skin layers or underlying tissues.

Liposomes like advanced drug carriers: from fundamentals to pharmaceutical applications.

AIMS: There are around 24 distinct lipid vesicles described in the literature that are similar to vesicular systems such as liposomes. Liposome-like structures are formed by combining certain amphiphilic lipids with a suitable stabiliser. Since their discovery and classification, self-assembled liposome-like structures as active drug delivery vehicles captured researchers' curiosity. METHODOLOGY: This comprehensive study included an in-depth literature search using electronic databases such as PubMed, ScienceDirect and Google Scholar, focusing on studies on liposome and liposomes like structure, discussed in literature till 2024, their sizes, benefits, drawback, method of preparation, characterisation and pharmaceutical applications. RESULTS: Pharmacosomes, cubosomes, ethosomes, transethosomes, and genosomes, all liposome-like structures, have the most potential due to their smaller size with high loading capacity, ease of absorption, and ability to treat inflammatory illnesses. Genosomes are futuristic because of its affinity for DNA/gene transport, which is an area of focus in today's treatments. CONCLUSION: This review will critically analyse the composition, preparation procedures, drug encapsulating technologies, drug loading, release mechanism, and related applications of all liposome-like structures, highlighting their potential benefits with enhanced efficacy over each other and over traditional carriers by paving the way for exploring novel drug delivery systems in the Pharma industry.

DEVELOPMENT AND EVALUATION OF IVABRADINE HCI-LOADED POLYMERIC MICROSPHERES PREPARED WITH EUDRAGIT L100-55 (METHACRYLIC ACID-ETHYL ACRYLATE COPOLYMER) AND ETHYL CELLULOSE FOR CONTROLLED DRUG RELEASE.

The objective of this study was to prepare and evaluate ivabradine HCl-loaded microspheres consisting of Eudragit LIOO-55 and ethyl cellulose prepared by oil-in-oil solvent evaporation method. Ivabradine HCl was encapsulated into microspheres by in situ method. The resultant microspheres were characterized with respect to drug loading, flow properties, Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), X-ray diffractometry (XRD), thermal analysis and release behavior. Chemical stability of IBH after being encapsulated into microspheres was confirmed by FTR, DSC and XRD. FTIR spectra reflect- ed no interaction between drug and excipients. TGA indicates that prepared microspheres showed much better thermal stability than pure drug ivabradine. SEM images showed formulation of microspheres in spherical shape. The maximum perceniage entrapment efficiency was found to be 81 ± 2.15 and percentage yield was 88 ± 2.65. The maximum in vito drug release was 94.5% for the pH 7.4 and demonstrated that all drug-loaded formulations had a pH-dependent drug release. The cumulative drug release data were analyzed by applying different kinetic models. Korsmeyer-Peppas equation was used to determine value of n which follows non-Fickian diffusion.

Chitin: A versatile biopolymer-based functional therapy for cartilage regeneration.

Chitin is the second most abundant biopolymer and its inherent biological characteristics make it ideal to use for tissue engineering. For many decades, its properties like non-toxicity, abundant availability, ease of modification, biodegradability, biocompatibility, and anti-microbial activity have made chitin an ideal biopolymer for drug delivery. Research studies have also shown many potential benefits of chitin in the formulation of functional therapy for cartilage regeneration. Chitin and its derivatives can be processed into 2D/3D scaffolds, hydrogels, films, exosomes, and nano-fibers, which make it a versatile and functional biopolymer in tissue engineering. Chitin is a biomimetic polymer that provides targeted delivery of mesenchymal stem cells, especially of chondrocytes at the injected donor sites to accelerate regeneration by enhancing cell proliferation and differentiation. Due to this property, chitin is considered an interesting polymer that has a high potential to provide targeted therapy in the regeneration of cartilage. Our paper presents an overview of the method of extraction, structure, properties, and functional role of this versatile biopolymer in tissue engineering, especially cartilage regeneration.