Objective To investigate the cl inical appl ication of self-setting CPC loading rhBMP-2 for repair of bone defects and to evaluate the cl inical effect and safety. Methods From June 2006 to September 2007, 112 bone defects patients were treated by CPC loading rhBMP-2 (rhBMP-2/CPC group) or CPC (control group). The range of bone defect was from1 cm × 1 cm × 1 cm to 4 cm × 3 cm × 3 cm. In the control group, 63 patients included 31 males and 32 females, aging from 17 to 70 years with an average of 47.4 years. The bone defects were located as follows: calcaneus in 19 patients, tibial plateau in 20 patients, proximal humerus in 8 patients, distal radius in 9 patients and thoracolumbar vertebrae in 7 patients. In the rhBMP-2/CPC group, 49 patients included 31 males and 18 females, aging from 16 to 68 years with an average of 45.6 years. The bone defects were located as follows: calcaneus in 11 patients, tibial plateau in 16 patients, proximal humerus in 7 patients, distal radius in 2 patients, distal tibia in 2 patients and thoracolumbar vertebrae in 11 patients. All defects were repaired with rhBMP-2/CPC (2-5 g) and CPC (2-50 g) in the rhBMP-2/CPC group and the control group, respectively. Results A total of 108 patients got primary heal ing after operation. Incisions oozing l ight yellow fluids were found in 4 patients (control group in 1, rhBMP-2/CPC group in 3), and then healed through dressing changes and taking glucocorticoid. There were no allergic or toxic reaction, no rush or high fever, no fluctuation of hepatic and renal function, blood routine, CRP and urine routine. All patients were followed up for 12 to 24 months (mean 13.2 months). The X-ray examination showed that the implanted material was firmly bonded to the bone at the interface and the anatomic contour of the bone at the sites of defects was successfully restored, and no ablation occurred. All patients got bone union after 3 months of operation. The movement and function of flexion and extension of affected l imbs recovered to the normal level. Conclusion Repairing bone defects with rhBMP-2/CPC is safe and effective. Using rhBMP-2/CPC is a promising therapy to deal with bone defects.
Objective To study efficiency of vascularized bone graft combining with reconstituted bone xenograft (RBX) in repairing bone defect and the expression of the vascular endothelial growth factor (VEGF) in serum. Methods From January 1998 to December 2002, 27 cases of bones defects were treated and randomly divided into 3 groups according to different repair materials: group A (the vascularized bone graft-RBX group, n=9), group B (the vascularized bone graft group, n=10)and group C(the RBX group, n=8). The bone defect repair, the bone healing time and the bone graft resorption were observed by radiograph after 3 months, 6 months and 12 months of operation, and the expression of VEGF in serum was assayed with lumino-enzyme immunoassay before operation and after operative 2 weeks, 4 weeks, 6 weeks and 8 weeks respectively. Results The X-ray films showed that the bonehealing was achieved in 8 cases of group A, in 6 cases of group B and in 3 cases of group C after 3 months; in 1 case of group A, respectively in 3 cases of both group B and group C after 6 months. The bone graft resorption was observed in1 case of group B and in 2 cases of group C after 12 months. The serum VEGF values after operative 2 weeks and 4 weeks were higher than those before operation in all of 3 groups(Plt;0.05), and the VEGF values of groups A and B were higher than that group C(Plt;0.05) after 4 weeks. There were no significant differences (Pgt;0.05) in serum VEGF level between postoperative 6, 8 weeks and preoperation in 3 groups. Conclusion The expression of serum VEGF obviously increase in the early period of bone transplanting, it is value of clinical evaluation of reparative efficiency of bone defect.
Objective To investigate the effect of tissue engineered bone with cryopreservation on healing of bone defects and to explore feasibility of cryopreservation for tissue engineered bone. Methods Tissue engineeredbones were constructed with osteoblasts being seeded onto bio-derived materials made from freshhuman bones,and they were preserved at 4℃ and -196℃ for 3 months and 6 monthsrespectively.They were applied to repair segmental bone defects of rabbit’s radius while the tissue engineered bone without cryopreservation and bio-derived materials were brought into control groups.The experiment was divided into groups A3,A6,B3,B6,C and D(group A3:tissue engineered bones were preserved at 4℃ for 3 months; group A6:tissue engineered bones were preserved at 4℃ for 6 months;group B3:tissue engineered bones were preserved at -196℃ for 3 months; group B6:tissue engineered bones were preserved at -196℃ for 6 months; group C: tissueengineered bones without cryopreservation; group D: bio-derived materials). Macroscopical and histologial examination were done at the 2nd,4th,6th,12th weeks, X-ray examination was done at the 6th,12th weeks and biomechanics were determined at 12th weeks after operation respectively. Results Macroscopical observation showed no significant differences among group A3, A6, B3, B6 and C, but less new bone formation and more obvious boundary in group D were observed. Histological observation showed more collagen and new bone around the edge of implant of group A3, A6, B3, B6 and C than group D, and histological evaluation showed significant differences between group D and other groups(P<0.05). Radiographic observation showed no absorbability of the implant cortex and less new bone formation in group D, but the unity between implant and host bone, medullary cavity reopened, disappearance of fracture line and fine bone modelling were observed in other groups at 12 weeks after operation. Biomechanics between group D and other groups showed significant differences(P<0.05). Conclusion Cryopreservation (4℃ and -196℃) were capable of preserving tissue engineered bone for long time, and tissue engineered bone withcryopreservation has significant effect on healing of bone defects. The methods f it clinical application.
OBJECTIVE: To construct tissue engineering bone with bio-derived materials and bone marrow stromal cells (MSCs), and to investigate the effect of allogeneic engineering bone implants on healing of segmental bone defects. METHODS: MSCs being aspirated aseptically from tibial tuberosities of young rhesus monkeys were induced into osteoblasts in vitro and then were cultured and marked with 5-bromo-2-deoxyuridine (BrdU). Tissue engineering bones were constructed with these labeled osteoblasts being seeded onto bio-derived materials made from fresh human bones which were treated physically and chemically, Then the constructs were implanted in 15 allogeneic monkeys to bridge 2.5 cm segmental bone defects of left radius as experimental groups, bio-derived materials only were implanted to bridge same size defects of right radius as control group. and, 2.5 cm segmental bone defects of both sides of radius were left empty in two rhesus monkeys as blank group. Every 3 monkeys were sacrificed in the 1st, 2nd, 3rd, 6th and 12th weeks postoperatively and both sides of the implants samples were examined macroscopically, histologicaly, and immunohistochemicaly. The two monkeys in blank group were sacrificed in the 12th week postoperatively. RESULTS: Apparent inflammatory reactions were seen around both sides of the implants samples in the 1st, 2nd, 3rd weeks, but it weakened in the 6th week and disappeared at the 12th week. The labeled osteoblasts existed at the 6th week but disappeared at the 12th week. The bone defects in experimental group were repaired and the new bone formed in multipoint way, and osteoid tissue, cartilage, woven bone and lamellar bone occurred earlier when compared with control group in which the bone defects were repaired in ’creep substitution’ way. The bone defects in blank group remained same size at the 12th week. CONCLUSIONS: Engineering bones constructed with bio-derived materials and MSCs were capable of repairing segmental bone defects in allogeneic monkeys beyond ’creep substitution’ way and making it healed earlier. Bio-derived materials being constituted with allogeneic MSCs may be a good option in construction of bone tissue engineering.
Abstract To examine the effects of porous tricalcium phosphate (TCP) combined with autogenous red bone marrow (BM) in therepar of bone defects, 21 cases of bone defects were implanted with the above prepared composite material, 17 cases had benign or low-grade malignant tumors and 4cases had old fractures. Serial X-ray films were taken after surgery. The results showed that new bone formation was seen between the interface of the implantand surrounding host bone after 6 weeks, and osseous union developed after 12 weeks. Evident osteogenesis in all patients was observed after a follow-up for 1~3 years. TCP-BM is both osteoconductive and osteoinductive. Its function was similar to the fresh autogenous cancellous bone graft and TCP-BM had the potencyof promoting the repair of osseous defect. It was suggested that TCP-BM might be an ideal material for treating bone defects.
The causes of development of 56 cases of bone defects from firearm injuries of extremities were analyzed, and the advantages of transfer of vascularized iliac bone graft with deep iliac circumflex vessels in 28 cases and the indications of transfer of vascularked fibular bone graft with fibular vessel in 15 cases and the exporiences in 9 cases from the methed of transter of seapula-cutaneous composite graft were summarized. It was emphatically pointed out that the half-circle typo externa fixators had its unique advantages in the treatment of the bone defects of long bones of extremities from firearm injuries. It would enentually become the method of priority for the treatment of fractures, nonunion of fractures and bone defects of extremities from firearm injuries.