BACKGROUND: Cell-based treatments have demonstrated the capacity to enhance reconstructive outcomes in recent decades but are hindered in clinical utility by regulatory hurdles surrounding cell culture. This investigation examines the ability of a noncultured stromal vascular fraction derived from lipoaspirate to enhance bone healing during fracture repair to further the development of translatable cell therapies that may improve outcomes in irradiated reconstruction. METHODS: Isogenic male Lewis rats were divided into three groups: fracture, irradiated fracture, and irradiated fracture with stromal vascular fraction treatment. Irradiated groups received a fractioned dose of 35 Gy before mandibular osteotomy. Stromal vascular fraction was harvested from the inguinal fat of isogenic donors, centrifuged, and placed intraoperatively into the osteotomy site. All mandibles were evaluated for bony union and vascularity using micro-computed tomography before histologic analysis. RESULTS: Union rates were significantly improved in the irradiated fracture with stromal vascular fraction treatment group (82 percent) compared to the irradiated fracture group (25 percent) and were not statistically different from the fracture group (100 percent). Stromal vascular fraction therapy significantly improved all metrics of bone vascularization compared to the irradiated fracture group and was not statistically different from fracture. Osteocyte proliferation and mature bone formation were significantly reduced in the irradiated fracture group. Bone cellularity and maturity were restored to nonirradiated levels in the irradiated fracture with stromal vascular fraction treatment group despite preoperative irradiation. CONCLUSIONS: Vascular and cellular depletion represent principal obstacles in the reconstruction of irradiated bone. This study demonstrates the efficacy of stromal vascular fraction therapy in remediating these damaging effects and provides a promising foundation for future studies aimed at developing noncultured, cell-based therapies for clinical implementation.
BACKGROUND: Cell-based treatments have demonstrated the capacity to enhance reconstructive outcomes in recent decades but are hindered in clinical utility by regulatory hurdles surrounding cell culture. This investigation examines the ability of a noncultured stromal vascular fraction derived from lipoaspirate to enhance bone healing during fracture repair to further the development of translatable cell therapies that may improve outcomes in irradiated reconstruction. METHODS: Isogenic male Lewis rats were divided into three groups: fracture, irradiated fracture, and irradiated fracture with stromal vascular fraction treatment. Irradiated groups received a fractioned dose of 35 Gy before mandibular osteotomy. Stromal vascular fraction was harvested from the inguinal fat of isogenic donors, centrifuged, and placed intraoperatively into the osteotomy site. All mandibles were evaluated for bony union and vascularity using micro-computed tomography before histologic analysis. RESULTS: Union rates were significantly improved in the irradiated fracture with stromal vascular fraction treatment group (82 percent) compared to the irradiated fracture group (25 percent) and were not statistically different from the fracture group (100 percent). Stromal vascular fraction therapy significantly improved all metrics of bone vascularization compared to the irradiated fracture group and was not statistically different from fracture. Osteocyte proliferation and mature bone formation were significantly reduced in the irradiated fracture group. Bone cellularity and maturity were restored to nonirradiated levels in the irradiated fracture with stromal vascular fraction treatment group despite preoperative irradiation. CONCLUSIONS: Vascular and cellular depletion represent principal obstacles in the reconstruction of irradiated bone. This study demonstrates the efficacy of stromal vascular fraction therapy in remediating these damaging effects and provides a promising foundation for future studies aimed at developing noncultured, cell-based therapies for clinical implementation.
Authors: D S Steinbrech; B J Mehrara; P B Saadeh; G Chin; M E Dudziak; R P Gerrets; G K Gittes; M T Longaker Journal: Plast Reconstr Surg Date: 1999-09 Impact factor: 4.730
Authors: Daniel A De Ugarte; Kouki Morizono; Amir Elbarbary; Zeni Alfonso; Patricia A Zuk; Min Zhu; Jason L Dragoo; Peter Ashjian; Bert Thomas; Prosper Benhaim; Irvin Chen; John Fraser; Marc H Hedrick Journal: Cells Tissues Organs Date: 2003 Impact factor: 2.481
Authors: Sagar Satish Deshpande; Alexis Donneys; Aaron Samuel Farberg; Catherine N Tchanque-Fossuo; Peter A Felice; Steven Richard Buchman Journal: Ann Plast Surg Date: 2014-01 Impact factor: 1.539
Authors: Alexis Donneys; Qiuhong Yang; Marcus Laird Forrest; Noah S Nelson; Ti Zhang; Russell Ettinger; Kavitha Ranganathan; Alicia Snider; Sagar S Deshpande; Mark S Cohen; Steven R Buchman Journal: NPJ Regen Med Date: 2019-05-21