Full-thickness skin graft versus split-thickness skin graft for radial forearm free flap donor site closure: protocol for a systematic review and meta-analysis

Abstract: Background The radial forearm free flap (RFFF) serves as a workhorse for a variety of reconstructions. Although there are a variety of surgical techniques for donor site closure after RFFF raising, the most common techniques are closure using a split-thickness skin graft (STSG) or a full-thickness skin graft (FTSG). The closure can result in wound complications and function and aesthetic compromise of the forearm and hand. The aim of the planned systematic review and meta-analysis is to compare… Show more

“…Skin grafting remains a prevalent clinical intervention for addressing extensive skin defects, involving the use of autologous or allogeneic skin grafts to facilitate healing and regeneration of the affected skin area. 130,131 Nevertheless, autologous grafts face a scarcity of skin sources, while allogeneic grafts are susceptible to immune rejections, thereby limiting their clinical application. 131,132 Silk scaffolds produced through electrostatic spinning exhibit high porosity and excellent pore connectivity, which are favorable for sustaining blood flow and facilitating oxygen exchange in traumatic injuries.…”

“…Skin grafting remains a prevalent clinical intervention for addressing extensive skin defects, involving the use of autologous or allogeneic skin grafts to facilitate healing and regeneration of the affected skin area. , Nevertheless, autologous grafts face a scarcity of skin sources, while allogeneic grafts are susceptible to immune rejections, thereby limiting their clinical application. , Silk scaffolds produced through electrostatic spinning exhibit high porosity and excellent pore connectivity, which are favorable for sustaining blood flow and facilitating oxygen exchange in traumatic injuries. Additionally, they effectively hinder the loss of moisture and proteins from wounds. , Certain cell regulatory factors and living cells have been incorporated into scaffolds to facilitate cell growth, proliferation, and migration within them, thereby enhancing the rate of formation (Figure ).…”

Electrospun Nanofiber Scaffold for Skin Tissue Engineering: A Review

“…Skin grafting remains a prevalent clinical intervention for addressing extensive skin defects, involving the use of autologous or allogeneic skin grafts to facilitate healing and regeneration of the affected skin area. 130,131 Nevertheless, autologous grafts face a scarcity of skin sources, while allogeneic grafts are susceptible to immune rejections, thereby limiting their clinical application. 131,132 Silk scaffolds produced through electrostatic spinning exhibit high porosity and excellent pore connectivity, which are favorable for sustaining blood flow and facilitating oxygen exchange in traumatic injuries.…”

“…Skin grafting remains a prevalent clinical intervention for addressing extensive skin defects, involving the use of autologous or allogeneic skin grafts to facilitate healing and regeneration of the affected skin area. , Nevertheless, autologous grafts face a scarcity of skin sources, while allogeneic grafts are susceptible to immune rejections, thereby limiting their clinical application. , Silk scaffolds produced through electrostatic spinning exhibit high porosity and excellent pore connectivity, which are favorable for sustaining blood flow and facilitating oxygen exchange in traumatic injuries. Additionally, they effectively hinder the loss of moisture and proteins from wounds. , Certain cell regulatory factors and living cells have been incorporated into scaffolds to facilitate cell growth, proliferation, and migration within them, thereby enhancing the rate of formation (Figure ).…”

Electrospun Nanofiber Scaffold for Skin Tissue Engineering: A Review