Osteoblasts were cultured and isolated from a piece of tibial pettiosteum of four New-Zealandrabbits. After subeultured,these cells Were incubatd in vitro with tritiated thvmidine for 36 hoursand then these labeled cells were implanted in the subeutaneous layer of the defects of the auriclarcartilage and the radial bone, After 2 weeks and 4 weeks respectively, these rabbits were killed andthe spoimens were obtained from the site where the cells had been transplanted. The transformation of these cells was observed by autoradiographic method. The results indicated that nearly all of the cultured cells were labeled. After 2 weeks, it was observed that many labeled osteoblasts were in different stages of differentiation, some were beried by extracellular matrix and resembled osteocyte, thers were differentiated into chondrocyte-like cell. In addition, some labeled osteoblasts were congregated in the form of multinucleated osteoclast. After 4 weeks , in the subcutaneous layer the labeled osteoblasts were changed to osteoid tissue and in the defect of the auricular crtilage these cells transformed into chondritic tissue; moreover, those labeled osteoblsts which had been implanted into the radial defect had differentiated into typical bone tissue. The results of this research indicated that the osteoblasts isolated from the periosteum if reimplanted to the same donor might be possible to repair the bone and cartilage defects.
In order to observe the effects of different facing directions of the germinal layer of periosteum on the cartilage regeneration, the human fibrin adhesive agent was used to adhere autogenous periosteum to repair the articular cartilage defect of rabbits. Twentyfour rabbits with 48 knee joints were divided randomly into two groups. A 0.6cm×1.2cm articular cartilage defect was created on the femoral trochlea until there was bleeding from the subchondral bone. A piece of periosteum, sized 0.75cm×1.5cm, was removed from the medial aspect of upper tibia. The periosteum was adhered to the defect by human fibrin adhesive agent. In Group 1 the germinal layer faced the subchondral bone and in Group 2 the germinal layer faced the joint cavity. The cartilage regeneration in both groups was observed by naked eyes and light microscope in 2nd and 6th weeks and by electron microscope after Safronin Ostained in 12th and 20th weeks. The results showed that before the 6th week, the cartilage regeneration was faster in Group 2 than that in Group 1. After that there was no significant difference in regeneration between the two groups. This suggested that the facing direction of the germinal layer was not a critical factor on cartilage regeneration. It was also found that the strength of the adhesive agent was not enough. The regenerated cartilage was proved to be hyaline cartilage.
To evaluate the initial cl inical effect of the autologous bone marrow integrating artificial bone and il ium periosteum transplantation in treatment of problematic nonunion. Methods From January 2004 to July 2006, 12 patients (13 l imbs)with problematic nonunion were treated with autologous bone marrow integrating artificial bone and il iumperiosteum. There were 8 males and 4 females, aged 17-58 years old. The position of nonunion were the tibia in 7 l imbs, the femur in 3 l imbs, the humerus in 2 l imbs. The operated number was 1-4, mean 2.5. The time from injury to therapy was 13 months to 9 years, mean 47.6 months. The bone defect distance was 6-30 mm (mean 15 mm) through 1 ∶ 1 X-rays before operation. Eleven l imbs were treated by internal fixation (10 l imbs by the bone nail and 1 l imb by the l imited contact-dynamic compression plate), 2 l imbs were treated by the external fixation. The X-ray films were taken at 1 day, 1, 3, 6, 9, 12 months after operation to observe fracture union. Results All patients were followed up for 12-26 months (mean 17.5 months) and achieved union within 4-7 months (mean 6 months). No deformity of rotation, angulation and crispation occurred in 13 l imbs, but functional impairment occurred in 6 l imbs after union of fracture. Conclusion Autologous bone marrow integrating artificial bone and il ium periosteum transplantation for treatment of problematic nonunion has the satisfactory result.
Abstract To investigate the ectopic new bone formation following implantation of bovine hydroxyapatite Bio-oss together with free periosteum, 12 chabb: ch rabbits were selected. In 10 rabbits, Bio-oss block together with free periosteum was implanted in the gastrocnemius muscle of one leg randomly, and Bio-oss block alone was implanted in the same muscle of the other leg. In the other 2 rabbits, the periosteum was implanted into the gastrocnemius musle of both legs. Histologic examination and quantitative analysis of newbone formation were performed at 3 and 6 weeks postoperatively. The results showed that in the legs implanted bovine hydroxyapatite Bio-oss together with freeperiosteum, new bone formation began at 5th day after implantation. The area ofnew bone composed of 19.0% of the specimens at 3 weeks postoperatively. No boneformation through out the experimental period in Bio-oss block alone implantedlegs and also periosteum implanted legs. We concluded that bovine hydroxyapatite Bio-oss has a good capacity of osteoconduction. New bone can be formed after the implantation of hydroxyapatite combined with free periosteum.
OBJECTIVE To introduce a new method of bone defect repairing after bone cyst curettage. METHODS Eight cases with bone cyst were treated with this new method. The pieces of autogenous periosteum were implanted into the hematoma within the enveloped bone defect created after the bone cyst curettage. Among these patients, there were 5 males and 3 females, aged from 14 to 36 years old. All the lesions located in the upper of femur except one being located in humerus. The results were evaluated through the postoperative radiological findings with the preoperative ones and analysis of clinical functions. RESULTS All the patients were followed up for 2 to 11 years. X-ray films showed that osteogenesis developed well and that the enveloped bone defects had been repaired. No recurrence was found and the function of the affected limbs were maintained. CONCLUSION Autogenous periosteum grafting is effective in the treatment of solitary bone cyst.
Objective To review the research progress of the role of periosteum in distraction osteogenesis. Methods The related domestic and foreign literature about the role of periosteum in distraction osteogenesis in recent years was extensively reviewed, summarized, and the mechanism and influencing factors of periosteum during traction and osteogenesis were analyzed. Results The periosteum is rich in all kinds of cells (mesenchymal stem cells, osteoblasts, etc.), microvessel and various growth factors, which are necessary for the formation of new bone. It can promote the formation of new bone in the process of traction osteogenesis significantly. Conclusion The periosteum plays an important role in the progress of distraction osteogenesis.
OBJECTIVE: To study the treatment efficacy of vascularized periosteum graft and bone filling material for long bone defect. METHODS: Forty young and forty adult rabbits were divided into four groups respectively according to the bone filling materials. A 3 cm long segment was removed from the middle part of the rabbit radius to make a bone defect model. The periosteum was reserved and restored to set up a vascularized tubulate periosteum graft. On the left side, autogenous bone graft, decalcified allograft, tricalcium phosphate, and hydroxyapatite were used to fill in the bone defect respectively; on the right side, no bone filling material was used as controls. The repairing effect of bone defect was evaluated by roentogenography, biomechanical, and histological methods. RESULTS: In young rabbits, bone defects on both sides healed in the 6th week after operation. The bending strength of radius in the tricalcium phosphate group and in the hydroxyapatite group were lower in the 12th week and there was significant difference when compared with autogenous bone graft group, decalcified allograft group and control group (P lt; 0.05). The repairing mechanism included intramembranous and endochondral ossification, and intramembranous ossification was prevalent. In the adult rabbits, the repairing rates of bone defect were 50% in the autogenous bone graft group, 40% in the decalcified allograft group, 30% in the tricalcium phosphate group and in the hydroxyapatite group and 42.5% in the control group, respectively. CONCLUSION: In young rabbits, large bone defect can be repaired with vascularized tubulate periosteum graft with or without the combining use of bone filling materials. The bone filling material which will be substituted slowly is disadvantageous to the recovery of bone strength. In adult rabbits, vascularized tubulate periosteum graft combined with bone filling materials can not repair the large bone defect effectively.
Objective To investigate the clinical application of periosteal autograft in repair of cartilage defect caused by osteoarthritis of knee. Methods From 1996 to 1999, 36 knees of cartilage defect of knee joint in 28 cases were treated. In the operation, the cracked degenerative cartilage was removed before free periosteum from tibia was transplanted to repair the defect, and the meniscuses in 8 knees of the 36 knees were reconstructed. After operation, early continuous passive movement was adopted for 4 weeks, and 8 knees with reconstruction ofthe meniscus were immobilized by plaster splint for 7 days after operation and before passive movement. All of the cases were followed up for 1 to 4 years before clinical evaluation in symptoms, signs and radiological findings. Results The general satisfactory rate was 86.1%, in which the function was excellent in 22 knees and good in 9 knees. Conclusion The periosteal autograft is a good choice for repairing cartilage defect due to osteoarthritis, with a satisfactory outcomein the short term.
ObjectiveTo summarize the application status and progress of the strategies to augment tendon-to-bone healing. MethodsThe present researches focused on augmentation of tendon-to-bone healing were extensively reviewed. ResultsThe present strategies to augment healing of tendon-to-bone by enhancing the location environment, and increasing the cell numbers and relative growth factor. The mainly strategies include using calcium phosphate materials, biocompatible scaffolds and glue, growth factors, cell matrix, platelet-rich plasma, and periosteum. Although periosteum have been used in clinical and got some possitive effects, the others still not be used in clinical and needs further studies. ConclusionThere are many strategies to enhance the ability of tendon-to-bone healing, which got some positive results, but results of studies were varied. Thus, further fundamental research and clinical studies are required to achieve the best effects.
Objective To study and compare boneforming mechanismafter compound of autologous periosteum-wrapped tendon with spongiosa homogenate and other implants in articular cavity, and to explore the possibility of the compound as a substitute for the lunate in Kienbock’s disease.Methods Forty-five New Zealand white rabbits were randomly divided into three groups: periosteum group(group A, n=15), composite group(group B, n=15), and control group(group C, n=15). The three sorts of implants were placed into articular cavity of the knee respectively. The changes of bone formation and bone morphogenetic protein (BMP) distribution of the implants were examined under optical microscope with HE and immunohistochemical staining and measured by CT 3, 6 and 9 weeks after operation.Results The result of BMP staining was negative after 3 weeks and positive in new cartilage cells after 9 weeks in group A. The positive BMP staining was observed in group B after 3 weeks and 9 weeks, which mainly distributed in new bone cells and cartilage cells. And negative BMP staining was observed every stage in groupC. The quantitative CT bone mineral density (BMD) values of 3 implants were analyzed, the difference was significant between the groups (Plt;0.01), except that between groups A and C in the 3rd week (Pgt;0.05). Conclusion The above results demonstrated that the compound of autologous periosteum-wrapped tendon and spongiosa homogenate can produce bone and cartilage massively under the induction of periosteum and bone-forming factors such as BMP in spongiosa homogenate and the compound can be used as a substitute for the lunate.