Microwave assisted chitosan-polyethylene glycol hydrogel membrane synthesis of curcumin for open incision wound healing.

Chitosan and polyethylene glycol hydrogel membranes containing curcumin were synthesized using microwave technology at fixed frequency, power and time of 2450 MHz, 500 Watt and 120 s. Polymers were solubilized separately, combined with drug and mixed in two different ratios i.e. F1=80:20 and F2=85:15. The untreated and microwave treated hydrogel membranes were analyzed for degree of swelling, degree of degradation, tensile strength, surface morphology, vibrational and thermal analysis and in vitro drug release. Results indicated that F2(micro) showed a significantly high degree of swelling (96.49±1.21 %), low degradation (9.88±1.68 %), sustained drug release through slow erosion (55.1±3.11 %) via non-Fickian diffusion. The vibrational and thermal analysis revealed rigidification of hydrophilic domains of the polymers by formation of hydrogen bonds between chitosan and PEG moieties (OH/NH) and elasticity of hydrophobic domains (asymmetric and symmetric CH moieties and/or C=O moieties) which not only significantly increased the transition temperature and enthalpy (297.2±3.2 °C and 4.24±1.4 J/g) of the chitosan moiety but also resulted in enhanced tensile strength (18.2±1.3 Mpa). In vivo wound healing study revealed significantly faster wound healing in the F2(micro) treated animal group in comparison to a control animal group where at day 14, a significant re-epithelization (87.26 %) with smaller wound size was observed. Hence microwave assisted chitosan-PEG hydrogel membrane of curcumin is advocated to be a suitable plate form for wound healing applications.

Analyzing Immune Cell Infiltration and Copper Metabolism in Diabetic Foot Ulcers.

Background: Diabetes impairs wound healing, notably in diabetic foot ulcers (DFU). Stress, marked by the accumulation of lipoylated mitochondrial enzymes and the depletion of Fe-S cluster proteins, triggers cuproptosis-a distinct form of cell death. The involvement of copper in the pathophysiology of DFU has been recognized, and currently, a copper-based therapeutic strategy is emerging as a viable option for enhancing ulcer healing. This study investigates genes linked to copper metabolism in DFU, aiming to uncover potential targets for therapeutic intervention. Methods: Two diabetic wound Gene Expression Omnibus (GEO) datasets were analyzed to study immune cell dysregulation in diabetic wounds. Differentially expressed genes related to copper metabolism were identified and analyzed using machine learning methods. Gene ontology, pathway enrichment, and immune infiltration analyses were performed using DFU samples. The expression of identified genes was validated using qRT-PCR and single-cell RNA sequencing. Results: Ten genes associated with copper metabolism were identified. Among these, SLC31A1 and ADNP were found to be significantly differentially expressed in DFU. Notably, SLC31A1 exhibited higher expression in macrophages, whereas ADNP was found to be highly expressed in fibroblasts and chondrocytes. Conclusion: The study indicates a close link between copper metabolism, the infiltration of immune cells, and DFU. It proposes that copper metabolism could influence the progression of DFU through the activation of immune responses. These observations offer fresh perspectives on the underlying mechanisms of DFU and identify potential targets for therapeutic intervention.

Photochemically Driven Polymeric Biocompatible and Antimicrobial Thiol-Acrylate Nanocomposite Suitable for Dental Restoration.

The development a photochemically driven polymeric composite for dental restorative materials to restore tooth cavities with antibacterial, biocompatibility, and outstanding mechanical properties is an urgent need for clinical application in stomatology. Herein, a series of polyurethane acrylate (PUA) prepolymers and antibacterial polyurethane acrylate quaternary ammonium salts (PUAQASs) were synthesized, and their mechanical and biological properties were explored. The unique secondary mercaptan with a long shelf life and low odor was used to reduce oxygen inhibition and increase cross-linking density; meanwhile, modified photocurable nano zirconia (nano ZrO2) enhances mechanical properties of the nanocomposites and possesses preeminent dispersion in the matrix. The results show that minimal inhibitory concentrations (MICs) of PUAQASs are 200 and 800 µg/mL for Staphylococcus aureus and Escherichia coli, respectively. The addition of secondary thiols significantly increases the photopolymerization rate and monomer conversion. The highest hardness and modulus reach 1.8 and 8.7 GPa compared to 1.8 and 8.3 GPa for commercial resin. The lap shear stress on the pig bone is 912 MPa, and that on commercial resin is 921 MPa. Most importantly, the photochemically driven polymeric composite has excellent biocompatibility and significantly better antimicrobial properties than commonly used commercial resins.