A new composite facial and scalp transplantation model in rats.

There are limited sources of autogenous tissue available for reconstruction of severe facial and scalp deformities caused by extensive tumor ablation, burns, or trauma. Allografts from cadaveric sources may serve as a reconstructive alternative. However, technical and immunological aspects of harvesting and transplanting face and scalp flaps limit the routine use of such procedures. For evaluation of the feasibility of composite-tissue reconstruction, an experimental model of composite face/scalp flap transplantation in rats was designed. Technical aspects of the model, survival rates, and the complications encountered during development of the model are presented. A total of 64 animals, in three experimental groups, were studied. In group I, the anatomical study group (n = 6), the anatomical features of the face and scalp region in rats were explored. Groups II and III were the transplantation groups. Isograft transplantations were performed between identical Lewis rats (RT11 to RT11), and allografts were transplanted, across major histocompatibility complex barriers, between Lewis-Brown Norway rats (RT1l/n) and Lewis rats (RT11). In group II (the control group, n = 8), transplantation of nonvascularized composite face/scalp isografts and allografts was performed. In group III (the transplantation group, n = 50), vascularized face/scalp isografts (n = 36) and allografts (n = 14) were transplanted. Complications included partial or total flap necrosis, death attributable to food aspiration, and poor general condition. To prevent acute and chronic allograft rejection, cyclosporine A (16 mg/kg per day) therapy was initiated 24 hours after transplantation; the dose was tapered to 2 mg/kg per day within 4 weeks and was maintained at that level thereafter. Long-term survival (>170 days) was achieved, without any signs of rejection, with low-dose (2 mg/kg per day) cyclosporine A therapy. This is the first report documenting successful composite face/scalp flap transplantation in the rat model.

Is Sp1 binding site polymorphism within COL1A1 gene associated with tennis elbow?

Tennis elbow defines a condition of pain and tenderness over the lateral epicondyle of the humerus. The exact aetiology of the injury is not yet fully understood. The major constituent of tendons is type 1 collagen which is encoded by COL1A1 gene. The aim of the study was to determine whether Sp1 binding site polymorphism (SNP rs1800012; 1546G/T) within the intronic region of COL1A1 gene is associated with tennis elbow. One hundred and three tennis elbow patients and one hundred and three healthy subjects without any history of previous ligament or tendon injuries were recruited for this genetic association study. All participants were genotyped for the COL1A1 Sp1 binding site polymorphism by using PCR-RFLP method. There were no observed statistical differences in the genotype (p=0.17) or allele (p=0.11) distributions between the groups. G allele frequency in patients and controls was 82.5% and 76.21%, and T allele frequency was 17.5% and 23.79% respectively. This study has shown that there is no association between this polymorphism and tennis elbow within the population studied.

Composite vascularized skin/bone transplantation models for bone marrow-based tolerance studies.

There is an ongoing need to understand the mechanisms of bone marrow-based allograft tolerance. This is important in clarifying the diverse variables influencing the ultimate outcome of the solid organ and composite tissue transplants. To establish bone marrow transplantation as a routine clinical application, further experimental studies should be conducted to overcome the obstacles related to the bone marrow transplantation. These obstacles include graft versus host disease, immunocompetence, and toxicity of the conditioning regimens. For these purposes, novel experimental models are needed. In an attempt to provide a reliable research tool for bone marrow-based tolerance induction studies, we introduced different experimental models of modified vascularized skin/bone marrow (VSBM) transplantation technique for tolerance induction, monitoring, and maintenance studies. In this skin/bone transplantation model, the technical feasibility of concurrent or consecutive transplantation of the combination of bilateral vascularized skin, vascularized bone marrow, or vascularized skin/bone marrow transplants was investigated. Isograft transplantations were performed between genetically identical Lewis (LEW, RT1) rats. Five different experimental designs in 5 groups of 5 animals each were studied. Group I: Bilateral vascularized skin (VS) transplantation; group II: bilateral vascularized skin/bone transplantation; group III: vascularized skin transplantation on one side and vascularized skin/bone transplantation on the contralateral side; group IV: vascularized bone transplantation on one side and vascularized skin/bone transplantation on the contralateral side; group V: vascularized bone transplantation on one side and vascularized skin transplantation on the contralateral side. Successful transplantations were performed in all groups. The survival of the isograft transplants was evaluated clinically and histologically. All skin flaps remained pink and pliable and grew new hair. The viability of the compact bone, bone marrow and skin at 100 days posttransplant was confirmed by histologic evaluation, and bone marrow revealed active hematopoiesis. Bilateral skin/bone transplantation model may serve as an experimental tool to study new strategies in tolerance induction by altering the amount of the immunogenic load in the form of skin transplant and bone marrow delivery in the vascularized form, allowing for expedited engraftment of stem and progenitor cells.

Composite vascularized skin/bone graft model: a viable source for vascularized bone marrow transplantation.

In this study, we introduce a new model for vascularized skin and bone marrow transplantation. Twenty-five Lewis (RT1(1)) rats were studied. Anatomic dissection studies were performed in 5 animals. In the experimental group, 10 isograft transplantations were performed between Lewis rats. Combined groin skin and femoral bone flaps were transplanted based on the femoral artery and vein. Transplants were evaluated on a daily basis. All flaps survived without problems over 100 days posttransplant. The skin component remained pink and pliable, and grew new hair. Histological examination of the femoral bone (except the femoral head) revealed active hematopoiesis with a viable compact and cancellous bone components on day 100 posttransplant. This model can be applied to tolerance induction studies across the major Histocompatibility (MHC) barrier, where bone will serve as donor of stem and progenitor cells, and the skin flap will serve as a monitor of graft rejection.