TGF-β is a multifunctional cytokine that regulates many aspects of cellular function, including periosteal mesenchymal cell proliferation, differentiation. This experiment is to study its effects on bone defect repai...TGF-β is a multifunctional cytokine that regulates many aspects of cellular function, including periosteal mesenchymal cell proliferation, differentiation. This experiment is to study its effects on bone defect repair. A rabbit radial bone defect model was used to evaluate the effect of TGF-β, which was extracted and purified from bovine blood platelets, on the healing of a large segmental osteoperiosteal defect. A 1. 5-centimeter segmental defect was created in the mid-upper part of the radial shaft of adult rabbits. The defect was filled with implant containing TGF-β that consisted of carrier and bovine TGF-β. Limbs served as controls received carrier alone. The defectswere examined radiographically and histologically at 4, 8,12 , 16 and 20 weeks after implantation. The results showed that in TGF-β implant group . the defect areas at 12 weeks post operation were bridged by uniform new bone and the cut ends of cortex could not be seen;while in control group, the defects remained clear. Only a small amount of new bone formed as a cap on the cut bone ends. In the experimental group, new lamellar and woven bone formed in continuity with the cut ends of the cortex. An early medullar canal appears to be forming and contained normal-appearancing marrow elements; while the control group displayed entirely fibrous tissue within the defect site. Remnants of the cancellous bone carrier were observed in the control specimen. These data demonstrate that exogenous TGF-β initiate osteogenesis and stimulate the bone defects repair in animal model.展开更多
Objective:To report the clinical outcome of repairing massive bone defects biologically in limbs by homeochronous using structural bone allografts with intramedullary vascularized fibular autografts. Methods: From Jan...Objective:To report the clinical outcome of repairing massive bone defects biologically in limbs by homeochronous using structural bone allografts with intramedullary vascularized fibular autografts. Methods: From January 2001 to December 2005, large bone defects in 19 patients (11 men and 8 women, aged 6 to 35 years) were repaired by structural bone allografts with intramedullary vascularized fibular autografts in the homeochronous period. The range of the length of bone defects was 11 to 25 cm (mean 17.6 cm), length of vascularized free fibular was 15 to 29 cm (mean 19.2 cm), length of massive bone allografts was 11 to 24 cm (mean 17.1 cm). Location of massive bone defects was in humerus(n=1), in femur(n=9) and in tibia(n=9), respectively. Results: After 9 to 69 months (mean 38.2 months) follow-up, wounds of donor and recipient sites were healed inⅠstage, monitoring-flaps were alive, eject reaction of massive bone allografts were slight, no complications in donor limbs. Fifteen patients had the evidence of radiographic union 3 to 6 months after surgery, 3 cases united 8 months later, and the remained one case of malignant synovioma in distal femur recurred and amputated the leg 2.5 months, postoperatively. Five patients had been removed internal fixation, complete bone unions were found one year postoperatively. None of massive bone allografts were absorbed or collapsed at last follow-up. Conclusion: The homeochronous usage of structural bone allograft with an intramedullary vascularized fibular autograft can biologically obtain a structure with the immediate mechanical strength of the allograft, a potential result of revascularization through the vascularized fibula, and accelerate bone union not only between fibular autograft and the host but also between massive bone allograft and the host.展开更多
Compared with non-degradable materials,biodegradable biomaterials play an increasingly important role in the repairing of severe bone defects,and have attracted extensive attention from researchers.In the treatment of...Compared with non-degradable materials,biodegradable biomaterials play an increasingly important role in the repairing of severe bone defects,and have attracted extensive attention from researchers.In the treatment of bone defects,scaffolds made of biodegradable materials can provide a crawling bridge for new bone tissue in the gap and a platform for cells and growth factors to play a physiological role,which will eventually be degraded and absorbed in the body and be replaced by the new bone tissue.Traditional biodegradable materials include polymers,ceramics and metals,which have been used in bone defect repairing for many years.Although these materials have more or fewer shortcomings,they are still the cornerstone of our development of a new generation of degradable materials.With the rapid development of modern science and technology,in the 21 st century,more and more kinds of new biodegradable materials emerge in endlessly,such as new intelligent micro-nano materials and cell-based products.At the same time,there are many new fabrication technologies of improving biodegradable materials,such as modular fabrication,3 D and 4 D printing,interface reinforcement and nanotechnology.This review will introduce various kinds of biodegradable materials commonly used in bone defect repairing,especially the newly emerging materials and their fabrication technology in recent years,and look forward to the future research direction,hoping to provide researchers in the field with some inspiration and reference.展开更多
Because of its simplicity,reliability,and replicability,the Masquelet induced membrane technique(IMT)has become one of the preferred methods for critical bone defect reconstruction in extremities.Although it is now us...Because of its simplicity,reliability,and replicability,the Masquelet induced membrane technique(IMT)has become one of the preferred methods for critical bone defect reconstruction in extremities.Although it is now used worldwide,few studies have been published about IMT in military practice.Bone reconstruction is particularly challenging in this context of care due to extensive soft-tissue injury,early wound infection,and even delayed management in austere conditions.Based on our clinical expertise,recent research,and a literature analysis,this narrative review provides an overview of the IMT application to combat-related bone defects.It presents technical specificities and future developments aiming to optimize IMT outcomes,including for the management of massive multi-tissue defects or bone reconstruction performed in the field with limited resources.展开更多
Objective: To study the effect of transforming growth factor β/bone morphogenetic protein (TGFβ/BMP) composite on healing of large segmental bone defects and the interaction between TGF-β and BMP.Methods: A 1. 5-ce...Objective: To study the effect of transforming growth factor β/bone morphogenetic protein (TGFβ/BMP) composite on healing of large segmental bone defects and the interaction between TGF-β and BMP.Methods: A 1. 5-centimeter segmental defect was created in the mid-upper part of the radial shaft of adultrabbit. The defects were filled with implant of TGF-β/carrier, BMP/carrier and TGF-a/BMP/carrier, respectively. Purified bovine TGF-β 120 μg and BMP 12 mg were used in the composite. The defects were examined radiographically and histologically at 4, 8. 12 and 16 weeks post-operation (PO). Results: In groupof TGF-β/carrier, the defect areas were bridged at 4 weeks PO, with material of uniform radiodensity. Conices of the cut ends were obscured by the new bone. By 16 weeks PO, the defects were bridged by uniformnew bone and the cut ends of cortex could not be seen in all groups. In group of BMP/carrier, the defectswere filled with more irregular woven callus in comparison with the other two groups. The TGF-β/BMP--implanted defect sites in animals killed at 16 weeks PO showed histologically new larnellar and woven bone,formed in continuity with the cut ends of the cortex. The medullar cavity was recanalized and contained marrow elements with normal appearance. ConClUsion: These data demonstrate the synergistic action betweenTGF-β and BMP in the process of bone healing, and the better effect of TGF-β/BMP composite than that ofsingle TGF-β or BMP on bone repair.展开更多
目的:深入研究全髋关节置换术(total hip arthroplasty,THA)治疗髋臼骨折继发创伤性关节炎的临床疗效。方法:回顾性分析2019年10月至2022年6月,采用THA治疗15例髋臼骨折继发创伤性关节炎患者,男8例,女7例,年龄40~76(59.20±9.46)岁...目的:深入研究全髋关节置换术(total hip arthroplasty,THA)治疗髋臼骨折继发创伤性关节炎的临床疗效。方法:回顾性分析2019年10月至2022年6月,采用THA治疗15例髋臼骨折继发创伤性关节炎患者,男8例,女7例,年龄40~76(59.20±9.46)岁。记录术前及术后假体松动、髋关节脱位、髋关节活动度、神经损伤等情况,采用Harris评分、视觉模拟评分(visual analogue scale,VAS)、影像学检查评价髋关节功能及手术疗效。结果:15例均顺利完成手术,术中无神经、血管损伤,术后切口均Ⅰ期甲级愈合,无感染。随访时间6~39(18.33±9.27)个月。其中1例术后半年发生髋臼侧假体松动,经过翻修手术后恢复良好;1例髋关节脱位,经切开复位处理后治愈,无不良后果。术后末次随访Harris评分(88.60±4.01)分,与术前(47.20±11.77)分相比,差异有统计学意义(P<0.05)。术后末次随访VAS评分1(1)分,与术前8(2)分相比,差异有统计学意义(P<0.05)。末次随访时,本组所有患者疼痛症状减轻或消失,关节功能满意;末次随访影像学资料显示关节假体贴合良好,无异位骨化发生,假体无松动。结论:THA治疗髋臼骨折继发创伤性关节炎疗效可靠,能有效提高患者的生活质量。术前对患者全面评估、骨缺损评估,术中髋臼、股骨、内固定物与骨缺损的处理是手术成功的关键因素。展开更多
文摘TGF-β is a multifunctional cytokine that regulates many aspects of cellular function, including periosteal mesenchymal cell proliferation, differentiation. This experiment is to study its effects on bone defect repair. A rabbit radial bone defect model was used to evaluate the effect of TGF-β, which was extracted and purified from bovine blood platelets, on the healing of a large segmental osteoperiosteal defect. A 1. 5-centimeter segmental defect was created in the mid-upper part of the radial shaft of adult rabbits. The defect was filled with implant containing TGF-β that consisted of carrier and bovine TGF-β. Limbs served as controls received carrier alone. The defectswere examined radiographically and histologically at 4, 8,12 , 16 and 20 weeks after implantation. The results showed that in TGF-β implant group . the defect areas at 12 weeks post operation were bridged by uniform new bone and the cut ends of cortex could not be seen;while in control group, the defects remained clear. Only a small amount of new bone formed as a cap on the cut bone ends. In the experimental group, new lamellar and woven bone formed in continuity with the cut ends of the cortex. An early medullar canal appears to be forming and contained normal-appearancing marrow elements; while the control group displayed entirely fibrous tissue within the defect site. Remnants of the cancellous bone carrier were observed in the control specimen. These data demonstrate that exogenous TGF-β initiate osteogenesis and stimulate the bone defects repair in animal model.
文摘Objective:To report the clinical outcome of repairing massive bone defects biologically in limbs by homeochronous using structural bone allografts with intramedullary vascularized fibular autografts. Methods: From January 2001 to December 2005, large bone defects in 19 patients (11 men and 8 women, aged 6 to 35 years) were repaired by structural bone allografts with intramedullary vascularized fibular autografts in the homeochronous period. The range of the length of bone defects was 11 to 25 cm (mean 17.6 cm), length of vascularized free fibular was 15 to 29 cm (mean 19.2 cm), length of massive bone allografts was 11 to 24 cm (mean 17.1 cm). Location of massive bone defects was in humerus(n=1), in femur(n=9) and in tibia(n=9), respectively. Results: After 9 to 69 months (mean 38.2 months) follow-up, wounds of donor and recipient sites were healed inⅠstage, monitoring-flaps were alive, eject reaction of massive bone allografts were slight, no complications in donor limbs. Fifteen patients had the evidence of radiographic union 3 to 6 months after surgery, 3 cases united 8 months later, and the remained one case of malignant synovioma in distal femur recurred and amputated the leg 2.5 months, postoperatively. Five patients had been removed internal fixation, complete bone unions were found one year postoperatively. None of massive bone allografts were absorbed or collapsed at last follow-up. Conclusion: The homeochronous usage of structural bone allograft with an intramedullary vascularized fibular autograft can biologically obtain a structure with the immediate mechanical strength of the allograft, a potential result of revascularization through the vascularized fibula, and accelerate bone union not only between fibular autograft and the host but also between massive bone allograft and the host.
基金supported by grants from the National Natural Science Foundation of China(11772226,81871777 and 81572154)the Tianjin Science and Technology Plan Project(18PTLCSY00070,16ZXZNGX00130)grants awarded to Xiao-Song Gu by the National Natural Science Foundation of China(31730031 and L1924064)。
文摘Compared with non-degradable materials,biodegradable biomaterials play an increasingly important role in the repairing of severe bone defects,and have attracted extensive attention from researchers.In the treatment of bone defects,scaffolds made of biodegradable materials can provide a crawling bridge for new bone tissue in the gap and a platform for cells and growth factors to play a physiological role,which will eventually be degraded and absorbed in the body and be replaced by the new bone tissue.Traditional biodegradable materials include polymers,ceramics and metals,which have been used in bone defect repairing for many years.Although these materials have more or fewer shortcomings,they are still the cornerstone of our development of a new generation of degradable materials.With the rapid development of modern science and technology,in the 21 st century,more and more kinds of new biodegradable materials emerge in endlessly,such as new intelligent micro-nano materials and cell-based products.At the same time,there are many new fabrication technologies of improving biodegradable materials,such as modular fabrication,3 D and 4 D printing,interface reinforcement and nanotechnology.This review will introduce various kinds of biodegradable materials commonly used in bone defect repairing,especially the newly emerging materials and their fabrication technology in recent years,and look forward to the future research direction,hoping to provide researchers in the field with some inspiration and reference.
文摘Because of its simplicity,reliability,and replicability,the Masquelet induced membrane technique(IMT)has become one of the preferred methods for critical bone defect reconstruction in extremities.Although it is now used worldwide,few studies have been published about IMT in military practice.Bone reconstruction is particularly challenging in this context of care due to extensive soft-tissue injury,early wound infection,and even delayed management in austere conditions.Based on our clinical expertise,recent research,and a literature analysis,this narrative review provides an overview of the IMT application to combat-related bone defects.It presents technical specificities and future developments aiming to optimize IMT outcomes,including for the management of massive multi-tissue defects or bone reconstruction performed in the field with limited resources.
文摘Objective: To study the effect of transforming growth factor β/bone morphogenetic protein (TGFβ/BMP) composite on healing of large segmental bone defects and the interaction between TGF-β and BMP.Methods: A 1. 5-centimeter segmental defect was created in the mid-upper part of the radial shaft of adultrabbit. The defects were filled with implant of TGF-β/carrier, BMP/carrier and TGF-a/BMP/carrier, respectively. Purified bovine TGF-β 120 μg and BMP 12 mg were used in the composite. The defects were examined radiographically and histologically at 4, 8. 12 and 16 weeks post-operation (PO). Results: In groupof TGF-β/carrier, the defect areas were bridged at 4 weeks PO, with material of uniform radiodensity. Conices of the cut ends were obscured by the new bone. By 16 weeks PO, the defects were bridged by uniformnew bone and the cut ends of cortex could not be seen in all groups. In group of BMP/carrier, the defectswere filled with more irregular woven callus in comparison with the other two groups. The TGF-β/BMP--implanted defect sites in animals killed at 16 weeks PO showed histologically new larnellar and woven bone,formed in continuity with the cut ends of the cortex. The medullar cavity was recanalized and contained marrow elements with normal appearance. ConClUsion: These data demonstrate the synergistic action betweenTGF-β and BMP in the process of bone healing, and the better effect of TGF-β/BMP composite than that ofsingle TGF-β or BMP on bone repair.
文摘目的:深入研究全髋关节置换术(total hip arthroplasty,THA)治疗髋臼骨折继发创伤性关节炎的临床疗效。方法:回顾性分析2019年10月至2022年6月,采用THA治疗15例髋臼骨折继发创伤性关节炎患者,男8例,女7例,年龄40~76(59.20±9.46)岁。记录术前及术后假体松动、髋关节脱位、髋关节活动度、神经损伤等情况,采用Harris评分、视觉模拟评分(visual analogue scale,VAS)、影像学检查评价髋关节功能及手术疗效。结果:15例均顺利完成手术,术中无神经、血管损伤,术后切口均Ⅰ期甲级愈合,无感染。随访时间6~39(18.33±9.27)个月。其中1例术后半年发生髋臼侧假体松动,经过翻修手术后恢复良好;1例髋关节脱位,经切开复位处理后治愈,无不良后果。术后末次随访Harris评分(88.60±4.01)分,与术前(47.20±11.77)分相比,差异有统计学意义(P<0.05)。术后末次随访VAS评分1(1)分,与术前8(2)分相比,差异有统计学意义(P<0.05)。末次随访时,本组所有患者疼痛症状减轻或消失,关节功能满意;末次随访影像学资料显示关节假体贴合良好,无异位骨化发生,假体无松动。结论:THA治疗髋臼骨折继发创伤性关节炎疗效可靠,能有效提高患者的生活质量。术前对患者全面评估、骨缺损评估,术中髋臼、股骨、内固定物与骨缺损的处理是手术成功的关键因素。
