Comparison of cell-scaffold interactions in a biological and a synthetic wound matrix.

Wound healing is a central physiological process that restores the barrier properties of the skin after injury, comprising close coordination between several cell types (including fibroblasts and macrophages) in the wound bed. The complex mechanisms involved are executed and regulated by an equally complex, reciprocal signalling network involving numerous signalling molecules such as catabolic and anabolic inflammatory mediators (e.g.

A Composite Application Technique of Single-stage Dermal Templates to Improve Handling and Ease of Use.

The "work horse" for the treatment of full-thickness defects of any etiology, including chronic nonhealing wounds and traumatic injuries, is generally autologous split-thickness skin grafts (STSGs), meshed, hand-fenestrated, or a sheet graft. Advancements in skin tissue engineering have allowed for the integration of dermal substitutes to be combined with autologous STSGs, adding valuable options for restoring the skin's complex multilayered structure. Although dermal templates offer a promising avenue for more nuanced reconstruction in certain cases, their application is not without challenges, particularly when they are made from delicate materials.

Fractional ablative laser therapy for the treatment of severe burn scars: A pilot study of the underlying mechanisms.

Ablative fractional resurfacing is clinically an efficient treatment for burn scar management. The aim of this pilot study was to investigate the poorly understood mechanisms underlying ablative fractional CO2 laser (AFL-CO2) therapy in relation to biomarkers S100 and 11β-hydroxysteroid dehydrogenase type 1 (11β-HSD1). S100 stains for Langerhans cells and neuronal cells, potentially representing the pruritus experienced.

Thermoresponsive and Injectable Hydrogel for Tissue Agnostic Regeneration.

Injectable hydrogels can support the body's innate healing capability by providing a temporary matrix for host cell ingrowth and neovascularization. The clinical adoption of current injectable systems remains low due to their cumbersome preparation requirements, device malfunction, product dislodgment during administration, and uncontrolled biological responses at the treatment site. To address these challenges, a fully synthetic and ready-to-use injectable biomaterial is engineered that forms an adhesive hydrogel that remains at the administration site regardless of defect anatomy.