Saad M Alrobaiea1, Jie Ding1, Zengshuan Ma1, Edward E Tredget2. 1. Wound Healing Research Group, Department of Surgery, University of Alberta , Edmonton, Canada . 2. Wound Healing Research Group, Department of Surgery, University of Alberta, Edmonton, Canada.; Divisions of Plastic and Reconstructive Surgery and Critical Care, University of Alberta, Edmonton, Canada.
Abstract
Objective: Hypertrophic scar (HTS) is a dermal form of fibroproliferative disorder that develops following deep skin injury. HTS can cause deformities, functional disabilities, and aesthetic disfigurements. The pathophysiology of HTS is not understood due to, in part, the lack of an ideal animal model. We hypothesize that human skin with deep dermal wounds grafted onto athymic nude mice will develop a scar similar to HTS. Our aim is to develop a representative animal model of human HTS. Approach: Thirty-six nude mice were grafted with full thickness human skin with deep dermal scratch wound before or 2 weeks after grafting or without scratch. The scratch on the human skin grafts was made using a specially designed jig that creates a wound >0.6 mm in depth. The xenografts were morphologically analyzed by digital photography. Mice were euthanized at 1, 2, and 3 months postoperatively for histology and immunohistochemistry analysis. Results: The mice developed raised and firm scars in the scratched xenografts with more contraction, increased infiltration of macrophage, and myofibroblasts compared to the xenografts without deep dermal scratch wound. Scar thickness and collagen bundle orientation and morphology resembled HTS. The fibrotic scars in the wounded human skin were morphologically and histologically similar to HTS, and human skin epithelial cells persisted in the remodeling tissues for 1 year postengraftment. Innovation and Conclusions: Deep dermal injury in human skin retains its profibrotic nature after transplantation, affording a novel model for the assessment of therapies for the treatment of human fibroproliferative disorders of the skin.
Objective: Hypertrophic scar (HTS) is a dermal form of fibroproliferative disorder that develops following deep skin injury. HTS can cause deformities, functional disabilities, and aesthetic disfigurements. The pathophysiology of HTS is not understood due to, in part, the lack of an ideal animal model. We hypothesize that human skin with deep dermal wounds grafted onto athymic nude mice will develop a scar similar to HTS. Our aim is to develop a representative animal model of humanHTS. Approach: Thirty-six nude mice were grafted with full thickness human skin with deep dermal scratch wound before or 2 weeks after grafting or without scratch. The scratch on the human skin grafts was made using a specially designed jig that creates a wound >0.6 mm in depth. The xenografts were morphologically analyzed by digital photography. Mice were euthanized at 1, 2, and 3 months postoperatively for histology and immunohistochemistry analysis. Results: The mice developed raised and firm scars in the scratched xenografts with more contraction, increased infiltration of macrophage, and myofibroblasts compared to the xenografts without deep dermal scratch wound. Scar thickness and collagen bundle orientation and morphology resembled HTS. The fibrotic scars in the wounded human skin were morphologically and histologically similar to HTS, and human skin epithelial cells persisted in the remodeling tissues for 1 year postengraftment. Innovation and Conclusions: Deep dermal injury in human skin retains its profibrotic nature after transplantation, affording a novel model for the assessment of therapies for the treatment of human fibroproliferative disorders of the skin.
Authors: James J Tomasek; Giulio Gabbiani; Boris Hinz; Christine Chaponnier; Robert A Brown Journal: Nat Rev Mol Cell Biol Date: 2002-05 Impact factor: 94.444
Authors: Jie Ding; Zengshuan Ma; Hongbin Liu; Peter Kwan; Takashi Iwashina; Heather A Shankowsky; Donald Wong; Edward E Tredget Journal: Wound Repair Regen Date: 2014 Sep-Oct Impact factor: 3.617
Authors: Stefan Rössler; Sebastian Philipp Nischwitz; Hanna Luze; Judith C J Holzer-Geissler; Robert Zrim; Lars-Peter Kamolz Journal: Medicina (Kaunas) Date: 2022-05-30 Impact factor: 2.948