In vitro-in vivo wound healing efficacy of Tridax Procumbens extract loaded Carboxymethylcellulose film.

In this work, Tridax Procumbens Extracts (TPE) were blended with Carboxymethylcellulose (CMC), and film was developed through the casting method. The phytochemical screening of the TPE/CMC film was carried out and found the presence of carbohydrates, tannins, saponins, and cardiac glycosides. The presence of elements such as C, O, Na, P, Cl, K, Ca, Mn, and Nb in TP/CMC film was confirmed through EDX. The melting point of the film was found around 291 ± 0.5 °C which was determined through the DSC curve. The maximum tensile strength of the TPE/CMC was found as 14 ± 0.5 MPa. The film showed antibacterial activity against Escherichia coli, Streptococcus pyogenes, Staphylococcus aureus, and Vibrio cholera compared to the control. Cell viability study exhibited 95 % and 98 % cell proliferation for the test film after interacting with the L929 cell line for 18 h and 24 h. The optical contact angle of the TPE/CMC film was also determined. The in-vivo, wound healing studies on adult mice showed healing within 10 days only and the histopathological results revealed the maximum number of fibroblasts with a high density of collagen fibers in the test group indicating that the prepared film can be an effective wound dressing material.

Evaluation of cashew gum-polyvinyl alcohol (CG-PVA) electrospun nanofiber mat for scarless wound healing in a murine model.

Modern-day treatment for burns and wounds demands scarless healing which is becoming a challenging clinical problem. Thus, to alleviate such issues, it becomes essential to develop biocompatible and biodegradable wound dressing material for skin tissue regeneration, which could heal the wound in a very short span leaving no scars. The present study focuses on the development of nanofiber of Cashew gum polysaccharide-Polyvinyl alcohol using electrospinning. The prepared nanofiber was optimized based on uniformity of fiber diameter (FESEM), mechanical property (Tensile Strength), and optical contact angle (OCA) and was subjected to evaluation of: antimicrobial activity against Streptococcus aureus and Escherichia coli, hemocompatibility, and in-vitro biodegradability. The nanofiber was also characterized using different analytical techniques including thermogravimetric analysis, Fourier-transform infrared spectroscopy, and X-ray diffraction. The cytotoxicity was also investigated on L929 fibroblast cells using an SRB assay. The in-vivo wound healing assay showed accelerated healing in comparison to untreated wounds. The in-vivo wound healing assay and histopathological slides of regenerated tissue confirmed that the nanofiber has the potential to accelerate healing properties.

Evaluating neem gum-polyvinyl alcohol (NGP-PVA) blend nanofiber mat as a novel platform for wound healing in murine model.

Modern-day treatment demands scarless wound healing utilizing scaffolds in the form of nanofiber mats which are tissue and environment-friendly. Neem gum polysaccharide (NGP) in conjugation with Polyvinyl alcohol (PVA) in the form of nanofibers exhibits antimicrobial properties mimicking extracellular matrix for tissue growth. Different grades of nanofibers mats (NFM) were prepared by combining different ratios of NGP and PVA which were later crosslinked using glutaraldehyde vapors (25 % w/v in 0.5 M HCl), and optimized grade G14 exhibited maximum tensile strength with smooth surface morphology, hemocompatible properties, in-vitro biodegradability and antimicrobial action against S. aureus & E. coli. G14 was analytically characterized using different analytical techniques viz. Fourier-transform infrared spectroscopy (FTIR), Thermogravimetric analysis (TGA), which indicated polymer-polymer compatibility. The surface hydrophobicity as detected using Optical contact angle (OCA) confirmed the hydrophobicity of NFM with increased glutaraldehyde vapor for crosslinking when compared to non-crosslinked NFM. Histopathology slides indicated G14 CL-NFM accelerated the wound healing in mice with dense collagen and fibroblasts when compared to control mice suggesting the tissue engineering potential of the prepared device.

Green nanofiber mat from HLM-PVA-Pectin (Hibiscus leaves mucilage-polyvinyl alcohol-pectin) polymeric blend using electrospinning technique as a novel material in wound-healing process.

The present work is focused on fabrication of novel nanofiber (NF) mat as wound-healing scaffold using blends of novel combination of Hibiscus rosa-sinensis leaves mucilage (HLM)-Polyvinyl alcohol (PVA)-Pectin, which was never reported previously. Different ratios of the polymeric blends were electrospun by setting different parameters to achieve best possible electrospun nanofiber mat which was later crosslinked by glutaraldehyde vapor. The optimized formulation of nanofiber mat was characterized using Fourier-transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), and thermogravimetric analysis (TGA). The crosslinked sample was evaluated for its efficacy in wound healing using Swiss albino mice model, where rapid healing of excised wound was observed with faster epithelization in test mice group than control mice within a period of 8 days. The hemolysis test with optimized crosslinked nanofiber mat CrNF(S7-CL) indicated it to be hemo-compatible. There were no traces of optimized CrNF(S7-CL) when placed under the skin hypodermis in test mice groups revealing its biodegradable nature. The degradation pattern of CrNF(S7-CL) in soil reflects its eco-friendly behavior. Thus, the prepared nanofiber grade CrNF(S7-CL) can be considered as a novel material for faster wound healing and can also be explored for other biomedical applications.