Objective To review the osteogenic mechanism and osteogenic effects of bone morphogenetic protein 6 (BMP-6) so as to provide the basis for further research of BMP-6. Methods The related articles about the osteogenic mechanism and the osteogenic effects of BMP-6 in experimental animals were extensively summarized. Results BMP-6 from bone matrix can transduct the osteogenic signal to bone marrow mesenchymal stem cells (BMSCs) by means of Smad protein signal transduction pathway. And the BMSCs which received the signals will differentiate into osteoblasts and chondroblasts. Therefore, BMP-6 plays an important role in the development and maturation of bone and cartilage. In addition, BMP-6 has a close relation with bone diseases, such as fracture, osteoporosis, and bone tumor. Conclusion The deep research of BMP-6 is expected to provide a new therapeutic approach for treating bone diseases of nonunion, osteoarthritis, and osteoporosis.
Objective To observe the influence on adjacent lumbar bone density after strengthening of T12, L1 segment vertebral osteoporotic compression fracture by percutaneous vertebroplasty (PVP) and percutaneous kyphoplasty (PKP) in postmenopausal female. Methods Between January 2008 and June 2011, 59 patients with T12, L1 segment thoracolumbar osteoporotic compression fracture were treated with PVP in 29 cases (PVP group) and PKP in 30 cases (PKP group), who were in accordance with the inclusion and exclusion criteria. No significant difference was found in gender, duration of menopause, disease druation, causes of injury, fractured vertebral body, and vertebral fracture classification between 2 groups (P gt; 0.05). The kyphosis Cobb angle of surgical area was measured at preoperation, 1 week after operation, and last follow-up; the lower three lumbar spine bone mineral density (BMD) of the surgical area, the femoral neck BMD, and body mass index (BMI) of patients were measured at perioperative period and last follow-up to find out the statement of anti-osteoporosis; FRAX online tools were used to evaluate the probability of major osteoporotic fracture and hip fracture of the next 10 years. Results The average follow-up was 25.5 months (range, 12-48 months) in 2 groups. There was significant difference in kyphosis Cobb angle of T12, L1 between preoperation and last follow-up in 2 groups (P lt; 0.05); the Cobb angle of PKP group was significantly less than that of PVP group at 1 week after operation and last follow-up (P lt; 0.05). No significant difference was found in BMI between 2 groups, and between perioperative period and last follow-up in the same group (P gt; 0.05). The lower three lumbar spine BMD of the surgical area and its T value at last follow-up was improved significantly when compared with BMD at perioperative period (P lt; 0.05); there was no significant difference in the lower three lumbar spine BMD and its T value between 2 groups at perioperative period (P gt; 0.05), but significant difference was found between two groups at last follow-up (P lt; 0.05). Difference was not significant in the femoral neck BMD and its T value between 2 groups, and between perioperative period and last follow-up in the same group (P gt; 0.05). The probability of major osteoporotic fracture and hip fracture of the next 10 years was not significantly different between 2 groups and between perioperative period and last follow-up in the same group (P gt; 0.05). Conclusion The increased BMD of adjacent lumbar spine can improve the strength of the vertebral body and reduce the incidence of adjacent vertebral fracture in patients with T12, L1 segment vertebral osteoporotic compression fracture after PVP/PKP, and PKP is superior to PVP increasing BMD of adjacent lumbar spine.
To observe the histology change of the insertion using different diamertrical bone tunnel in anterior cruciate l igament (ACL) reconstruction. Methods Ninety Japanese rabbits were selected, wihout female and male l imit, weighing 2.5-3.0 kg, and were randomly divided into 3 groups, 30 in each group. The ratio of transplantation l igament diameter and bone tunnel diameter was 1/1 (group A), the ratio was 1/1.5 (group B), and the ratio was 1/2 (group C). Bone tunnel observation and histology observation were carried out in the 4th, 8th and 16th weeks postoperat ively. Results Wound healed well in 3 groups. The mean time of walking functional recovery was 1.5, 2.0 and 3.5 days in groups A, B and C respectively. After 4 weeks of operation, more soft tissues at tunnel entry were observed in group A and group B than in group C; after 8 weeks of operation, there was no crevice at bone-tunnel entry of the groups A and B, there was no improvement in group C; after 16 weeks of operation, groups A and B showed the normal insertion, group C had no normal insertion. Histology observation: in groups A, B and C, bone-tunnel was filled with loose connective tissue after 4 weeks of operation; group A and group B emerged the discontinuation ACL insertion tidal l ine after 8 weeks of operation, group C had no insertion; groups A and B emerged the similarity normal ACL insertion tidal l ine structure after 16 weeks of operation, but group C had no this structure. The results of ultimate tensile strength in groups A, B and C were (75.44 ± 7.06), (91.37 ± 6.14) and (126.91 ± 4.61) N respectively at 4 weeks; the results were (74.31 ± 4.81), (88.30 ± 7.46) and (124.34±8.44) N respectively at 8 weeks; and the results were (62.20 ± 5.32), (71.53 ± 5.99) and (83.62 ± 5.69) N respectively at 16 weeks. There was no significant difference between group A and group B (P gt; 0.05), and there were significant differences between groups A, B and group C (P lt; 0.05). Conclusion In the ACL reconstruction, the ratioof transplantation l igament diameter and bone tunnel diameter being 1/1.5 will not affect the insertion outcome, but if theratio less than the l imit it will affect the insertion outcome.
ObjectiveTo investigate the effect of vascularized peroneus longus tendon graft reconstruction on anterior cruciate ligament (ACL) insertion in rabbits.MethodsEighty healthy New Zealand white rabbits were harvested to prepare ACL injury models and randomly divided into two groups (n=40). The ACL was reconstructed with vascularized peroneus longus tendon graft in group A and peroneus longus tendon graft without blood supply in group B. The survival of animals and the healing of incision were observed after operation; the grafts were taken for gross and histological observations at 4, 8, and 16 weeks; the biomechanical test of the grafts was carried out to record the maximum tensile strength and incidence of ACL insertion rupture at 8 and 16 weeks.ResultsAll animals survived until the experiment completed. General observation showed that the tunnel was combined with grafts, the vascular infiltration was abundant, and no obvious boundary between the tunnel and grafts existed at 16 weeks in group A; there was still an obvious boundary between the tunnel and graft in group B. Histological observation showed that the collagen fibers between tendon and bone in group A increased gradually, the dense fiber connection was formed, and the “tidal-line” like structure similar to the normal ACL insertion was formed at 16 weeks; but the“tidal-line” like structure was not obvious in group B. Biomechanical test showed that there was no significant difference in the incidence of ACL insertion rupture at 8 and 16 weeks between group A and group B (P=0.680; P=0.590), but the maximum tensile strength at 8 and 16 weeks were higher in group A than in group B (t=18.503, P=0.001; t=25.391, P=0.001).ConclusionThe vascularized peroneus longus tendon graft for ACL reconstruction can obviously promote the outcome of the ACL insertion.
Objective To review the application and research progress of artificial intelligence (AI) technology in trauma treatment. MethodsThe recent research literature on the application of AI and related technologies in trauma treatment was reviewed and summarized in terms of prehospital assistance, in-hospital emergency care, and post-traumatic stress disorder risk regression prediction, meanwhile, the development trend of AI technology in trauma treatment were outlooked. Results The AI technology can rapidly analyze and manage large amount of clinical data to help doctors identify patients’ situation of trauma and predict the risk of possible complications more accurately. The application of AI technology in surgical assistance and robotic operations can achieve precise surgical plan and treatment, reduce surgical risks, and shorten the operation time, so as to improve the efficiency and long-term effectiveness of the trauma treatment. ConclusionThere is a promising future for the application of AI technology in the trauma treatment. However, it is still in the stage of exploration and development, and there are many difficulties of historical data bias, application condition limitations, as well as ethical and moral issues need to be solved.
ObjectiveTo review research progress on the design, manufacturing, and clinical application of three-dimensional (3D) printed customized prosthesis in acetabular reconstruction of hip revision surgery. MethodsThe related research literature on 3D printed customized prosthesis and its application in acetabular reconstruction of hip revision surgery was searched by key words of “3D printed customized prosthesis”, “revision hip arthroplasty”, “acetabular bone defect”, and “acetabular reconstruction” between January 2013 and May 2024 in Chinese and English databases, such as CNKI, Wanfang database, PubMed, etc. A total of 34 271 articles were included. After reading the literature titles, abstracts, or full texts, the literature of unrelated, repetitive, low-quality, and low evidence level was screened out, and a total of 48 articles were finally included for analysis and summary. ResultsThe bone growth and mechanical properties of 3D printed customized prosthesis materials are better than those of non-3D printed customized prosthesis, which further solves the problem of elastic modulus mismatch between the implant and natural bone caused by “stress shielding”; the porous structure and antibacterial coating on the surface of 3D printed customized prosthesis have good anti-bacterial effect. 3D printed customized prosthesis can perfectly match the patient’s individual acetabular anatomical characteristics and defect type, thus improving the accuracy of acetabular reconstruction and reducing the surgical time and trauma. Conclusion3D printed customized prosthesis can be used for precise and efficient individualized acetabular reconstruction in hip revision surgery with good early- and mid-term effectiveness. More optimized production technics and procedures need to be developed to improve the efficiency of clinical application and long-term effectiveness.