Showing papers by "Anjanapura V. Raghu published in 2022"

Applications of hydrogel‐based delivery systems in wound care and treatment: An up‐to‐date review

Abstract: Natural wound healing is a highly complex and regulated process. Disruption and barriers to cellular and tissue repair processes contributes to impaired wound healing, including sustained infections. Superficial wound healing requires many factors to work in concrete at the wound site, and thus many treatment options and wound dressings have evolved to address the barriers to wound healing. Biomaterials are proven to encourage the wound healing process by stimulating repair and regeneration of injured tissues and preventing wound infections. A wide range of natural and synthetic hydrophilic and porous formulations such as foams, films, fibers, and hydrogels have been examined for these applications. Among these formulations, polymeric hydrogels have gained considerable interest in the medical applications. They effectively absorb wound exudates and provide a moist environment for aiding the wound healing process. However, chronic wounds that are sustained longer might need supplementary healing features as addendums such as antimicrobials, stem cells, growth factors, peptides, vitamins, and natural compounds. Therefore, when combined with hydrogels healing supporting addendums promote rapid and effective wound healing. Although there have been several advancements in biopolymer-based hydrogel systems, only limited reviews on various management strategies in wound healing are available in medical research and applications. Therefore, in this review, we have compiled and integrated various hydrogel-based approaches with the potential to improve chronic wound healing and advance important outcomes. In addition, in-situ injectable hydrogel preparation that have the advantage of packing patient wounds of different sizes and using 3D printing based tailor-made hydrogels, and bio-inks for wound closure applications are also highlighted.

A microplate‐based Response Surface Methodology model for growth optimization and biofilm formation on polystyrene polymeric material in a Candida albicans and Escherichia coli co‐culture

Abstract: Biofilm formation is one of the crucial factors for virulence in Candida albicans, Escherichia coli and their polymicrobial biofilm formed on medical prosthetics. In this study, high biofilm forming C. albicans M207 from a case of invasive candidiasis and a standard strain of bacterial culture E. coli ATCC 39936 were used for initial screening and media optimization using One Variable at a time (OVAT) and Response Surface Methodology (RSM) models, respectively, in polystyrene microtiter plates for in vitro biofilm studies. Sucrose and peptone significantly affected biofilm formation when screened by OVAT. Media optimization by Central Composite Design (CCD) showed that pH significantly affected biofilm formation for all the cultures which was further validated at critical parameters. Biofilm was quantified by growth OD measurements, MTT and CV assays in the presence and absence of FBS precoating and compared with standard Trypticase Soy Broth (TSB) media which did not show any significant difference. This high throughput polystyrene microtiter plate assay for preliminary screening of nutritional components using OVAT and media optimization using RSM model is being reported for the first time for biofilm formation by C. albicans and E. coli in a single and dual species environment. This study is essential for functional analysis of in-vitro growth and biofilm formation by these two pathogenic strains on polymeric hospital equipments and to develop suitable control measures to inhibit biofilm formation by C. albicans and E. coli single species and their co-culture.