Fibronectin-Enriched Interface Using a Spheroid-Converged Cell Sheet for Effective Wound Healing

Micro-fragmented collagen hydrogel wound dressing: Enhanced porosity facilitates elevated stem cell survival and paracrine effects for accelerated wound maturation

Human Adipose-derived stem cells (hADSCs), known for their mesenchymal stem cell properties, including multilineage differentiation and self-renewal, hold significant promise for chronic wound regeneration. Typically, hADSCs are utilized in cellular aggregates or hydrogels to enhance therapeutic efficacy. However, limitations such as reduced cell viability, inadequate mass transfer rates, and diminished paracrine effects hinder their clinical applications. This study explores an innovative approach by encapsulating hADSCs within a collagen/hyaluronic acid micro-fragmented collagen hydrogel wound dressing (MCWD). The resulting micro-fragmented collagen hydrogel-hADSC composite created through the integration of micro-sized hydrogel units and cells demonstrated markedly improved cell viability and activity, as well as superior therapeutic outcomes compared to conventional cell aggregates (CA) and collagen hydrogel wound dressings (CWD). In vitro assessments showed that the highly porous structure of MCWD promotes better mass transfer and enhances the viability and cytokine production of hADSCs associated with the paracrine effect. In vivo experiments further validated the effectiveness of the MCWD, revealing significant enhancements in cell proliferation, skin thickness restoration, collagen maturation, and blood vessel formation. These findings underscore the potential of MCWD as an advanced solution for wound healing applications.

Merged Red and NIR Light Sources for Photobiomodulation Therapy in Diabetic Wound Healing

Photobiomodulation (PBM) is considered an effective and safe therapeutic modality in supporting the treatment of complications from a global pandemic-diabetes. In this study, PBM therapy is investigated to accelerate wound healing in diabetic mice (DM), under the combined biological effects of red light from a red organic light-emitting diode (ROLED) and near-infrared (NIR) light from an NIR conversion film (NCF) with dispersed CuInS2/ZnS quantum dots (QDs). The QD concentration and the NCF structure were optimized to maximize the optical properties and mechanical stability. A merged red/NIR device (MRND) was produced by integrating the optimized NCF and ROLED for PBM therapy. As a result of irradiating DM with MRND at a dose of 2 J/cm2, after 10 days, the wounds recovered three times faster than DM without MRND. Additionally, MRND light not only restored the epidermal thickness to normal but also significantly reduced the levels of pro-inflammatory cytokines. The experimental results show that the proposed PBM therapy has the potential to improve the quality of life of diabetic patients by helping them with rapid wound healing.

Stem Cell-Laden Engineered Patch: Advances and Applications in Tissue Regeneration

Stem cell-based therapies are emerging as significant approaches in tissue engineering and regenerative medicine, applicable to both fundamental scientific research and clinical practice. Despite remarkable results in clinical studies, challenges such as poor standardization of graft tissues, limited sources, and reduced functionality have hindered the effectiveness of these therapies. In this review, we summarize the engineering approaches involved in fabricating stem cell assisted patches and the substantial strategies for designing stem cell-laden engineered patches (SCP) to complement the existing stem cell-based therapies. We then outline the potential applications of SCP in advancing tissue regeneration and regenerative medicine. By combining living stem cells with engineered patches, SCP can enhance the functions of both components, particularly for tissue engineering applications. Finally, we addressed current challenges, such as ethical considerations, high costs, and regulatory hurdles and proposed future research directions to overcome these barriers.

Current progress of protein-based dressing for wound healing applications - A review

Protein-based wound dressings have garnered increasing interest in recent years owing to their distinct physical, chemical, and biological characteristics. The intricate molecular composition of proteins gives rise to unique characteristics, such as exceptional biocompatibility, biodegradability, and responsiveness, which contribute to the promotion of wound healing. Wound healing is an intricate and ongoing process influenced by multiple causes, and it consists of four distinct phases. Various treatments have been developed to repair different types of skin wounds, thanks to advancements in medical technology and the recognition of the diverse nature of wounds. This review has literature reviewed within the last 3-5 years-the recent progress and development of protein in wound dressings and the fundamental properties of an ideal wound dressing. Herein, the recent strides in protein-based state-of-the-art wound dressing emphasize the significant challenges and summarize future perspectives for wound healing applications.

Fibroblast function recovery through rejuvenation effect of nanovesicles extracted from human adipose-derived stem cells irradiated with red light

Fibroblasts (hDFs) are widely employed for skin regeneration and the treatment of various skin disorders, yet research were rarely investigated about restoration of diminished therapeutic efficacy due to cell senescence. The application of stem cell and stem cell-derived materials, exosomes, were drawn attention for the restoration functionality of fibroblasts, but still have limitation for unintended side effect or low yield. To advance, stem cell-derived nanovesicle (NV) have developed for effective therapeutic reagents with high yield and low risk. In this study, we have developed a method using red light irradiated human adipose-derived stem cells (hADSCs) derived NV (R-NVs) for enhancing the therapeutic efficacy and rejuvenating hDFs. Through red light irradiation, we were able to significantly increase the content of stemness factors and angiogenic biomolecules in R-NVs. Treatment with these R-NVs was found to enhance the migration ability and leading to rejuvenation of old hDFs to levels similar to those of young hDFs. In subsequent in vivo experiments, the treatment of old hDFs with R-NVs demonstrated a superior skin wound healing effect, surpassing that of young hDFs. In summary, this study successfully induced rejuvenation and leading to increased therapeutic efficacy to R-NVs treated old hDFs previously considered as biowaste.