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Objective:To investigate the clinical efficacy of induced membrane technique in the staged treatment of adult chronic hematogenous osteomyelitis (CHOM) of long bone.Methods:The clinical data were retrospectively analyzed of the 22 adult patients with CHOM of long bone who had been admitted to the 920th Hospital, Joint Logistics Support Force of PLA from January 2016 to December 2019. There were 18 males and 4 females, aged from 16 to 56 years (average, 31.81 years). Their disease duration ranged from 0.6 to 42.0 years, averaging 18.4 years. By the Cierny-Mader anatomical classification, 4 cases were type Ⅰ, 6 cases Type Ⅲ, and 12 cases type Ⅳ. In the first stage, the bone defects were filled with antibiotic bone cement after thorough debridement. In the second stage when the infection had been controlled, the bone defects were repaired with bone grafts after removal of the bone cement. Bone healing time and complications were followed up. The treatment effects were evaluated by comparisons of the infection control indexes [including clinical manifestations like local redness, swelling, pus, and pain, and blood white blood cell count, C-Reactive protein (CRP), and erythrocyte sedimentation rate (ESR) as well] before the primary surgery, before the secondary surgery and at the last follow-up.Results:The volumes of the bone defects after stage-one debridement ranged from 54 cm 3 to 176 cm 3 (mean, 90.9 cm 3). All patients were followed up for 20 to 51 months (mean, 30.1 months) after surgery. All bone defects healed after 4 to 11 months (mean, 6.6 months). Postoperatively, infection developed at the bone extraction site of the posterior superior iliac spine in 3 cases and pain was observed at the donor site in one case, but the conditions were relieved after symptomatic treatment. Fracture and plate breakage occurred at the bone defect site in one case who had fallen down 7 months after operation, but responded to reoperation. The last follow-up revealed such symptoms as redness, swelling and pus discharge in none of the patients. The white blood cell count [(5.70 ± 1.57) × 10 9/L and (5.65 ± 1.58) × 10 9/L], CRP [(7.56 ± 2.57) mg/L and (7.25 ± 3.83) mg/L] and ESR [(9.64 ± 2.90) mm/h and (10.55 ± 5.23) mm/h] before the secondary surgery and at the last follow-up were significantly lower than those before the primary surgery [(8.24 ± 2.18) × 10 9/L, (49.54 ± 19.56) mg/L, and (42.68 ± 13.77) mm/h] (all P < 0.05). However, there were no significant differences between the indexes before the secondary surgery and at the last follow-up ( P > 0.05). Conclusion:In the staged treatment of adult CHOM of long bone, the induced membrane technique can effectively control infection, achieve repair of bone defects, and reduce complications.
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Objective:To investigate the clinical effect of induced membrane technique combined with staged internal fixation for treatment of infected femoral nonunion.Methods:A retrospective case series study was conducted to analyze the clinical data of 21 patients with infected femoral nonunion treated from January 2016 to December 2018 in 920th Hospital of Joint Logistics Support Force of PLA. There were 13 males and 8 females, with the age of 18-57 years [(38.9±6.7)years]. The duration of nonunion was 7-78 months [(27.1±11.4)months]. All patients were treated by induced membrane technique in two stages. At stage I, the original internal fixation was removed and debrided thoroughly, then the antibiotic-loaded bone cement and locking compression plate (LCP) were placed. The length of bone defect following debridement was 5-15 cm[(7.4±1.9)cm]. At stage II, the bone defect was reconstructed with bone grafts and fixed with the intramedullary nail and/or LCP. The wound condition, white blood cell count, C-reactive protein (CRP) and erythrocyte sedimentation rate (ESR) were recorded after stage I surgery and at the last follow-up to measure infection control. The complications and bone healing time were recorded. The bone healing was evaluated by the Paley criteria and the functional recovery of the affected limb was evaluated by the range of motion of the knee at the last follow-up.Results:All patients were followed up for 23-43 months [(31.9±6.7)months]. The infection recurred in 4 patients after stage I surgery, and the wound healed after repeated debridement. There was no infection recurrence after stage II surgery. The white blood cell count, CRP and ESR were (6.1±1.8)×10 9/L, (10.1±3.1)mg/L, (10.2±3.4)mm/h at the last follow-up, significantly decreased from preoperative (15.0±4.8)×10 9/L, (69.8±14.8)mg/L, (66.2±13.2)mm/h ( P<0.05). The incidence of complications was 43%. Besides infection recurrence in 4 patients after stage I surgery, the donor site at the posterior superior iliac spine in 3 patients showed delayed healing, and the limb shortening occurred in 2 patients with the discrepancy of 3 cm and 4 cm. Bony union was observed in all patients within 6-16 months [(8.8±2.7)months]. The results were excellent in 19 patients and good in 2 patients according to the Paley criteria at the last follow-up. The knee range of motion was significantly improved from preoperative 30.0°(15.0°, 110.0°) to 90.0°(61.5°, 120.0°) at the last follow-up ( P<0.05). Conclusion:For infected femoral nonunion, the induced membrane technique combined with staged internal fixation can effectively control infection, achieve bony union, and promote functional recovery.
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Objective:To investigate the efficacy of induced membrane technique combined with anterolateral thigh flap transfer in treating composite foot defect.Methods:A retrospective case series study was performed for 7 patients with composite foot defect treated at 920th Hospital of Joint Logistic Support Force of PLA from February 2014 to December 2018. There were 5 males and 2 females, with the age of 20-73 years [(38.9±16.3)years]. The composite defect located at the forefoot in 5 patients, midfoot in 1, and hindfoot in 1. There were 9 metatarsal bone defects, 1 medial cuneiform bone defect, and 1 calcaneus bone defect. The size of soft tissue defect varied from 6 cm×5 cm to 70 cm×35 cm. At stage I, the anterolateral thigh flap transfer and vancomycin loaded cement implantation were performed. The flap survival and complications were recorded. At stage II, the cement was removed and autogenous bone was grafted into the induced membrane. The duration of two-stage operation, bone union time, and complications were recorded. The postoperative function was assessed using Maryland foot score system before operation and at the last follow-up and postoperative compications were documented.Results:All patients were followed up for 22-54 months [(33.8±9.7)months]. At stage I, flaps survived in all patients, and bulking of the flap was seen in 3 patients. One patient with calcaneus bone defect had repeated infection after operation, and received debridement. At stage II, 6 patients received bone grafting surgery. The duration of two-stage operation was 2-4 months [(2.8±0.9)months]. The bone union time was 3 and 7 months [(4.7±1.2)months]. At the last follow-up, the Maryland foot function score was 63-92 points [(82.1±8.7)points], significantly different from 0 point before operation ( P<0.01). The results were excellent in 1 patient, good in 5, and fair in 1. Except for one nonunion of metatarsal bone, all the other 8 sites were with bone union uneventfully. Conclusion:The induced membrane technique combined with anterolateral thigh flap transfer is an effective protocol for composite foot defect, which can well repair soft tissue and bone defect, and restore walking.
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BACKGROUND: It remains unclear regarding the difference in bone healing effects after early-stage versus late-stage bone grafting within induced membrane. OBJECTIVE: To investigate the difference in bone healing effects of bone grafting within induced membrane in the repair of bone defects and the major factors that affect bone healing. METHODS: Sixty-three patients with tibial bone defect who received treatment with induced membrane technique during January 2007 to August 2017 in Wuxi People’s Hospital and Wuxi Orthopedics Hospital, China. These patients consisted of 38 males and 25 females and were aged 16-69 years. According to the time of bone grafting within induced membrane after bone cement filling, these patients were divided into an early stage group (n=25, bone grafting in the induced membrane 6-8 weeks after filling bone cement) and a late stage group (n=38, bone grafting in the induced membrane 10-12 weeks after filling bone cement). The healing of bone defect and functional recovery of affected limbs were evaluated. The causes of delayed healing and nonunion were analyzed. This study was approved by the Medical Ethics Committee of Wuxi People’s Hospital and Wuxi Orthopedics Hospital, China (approval No. LW2019001). RESULTS AND CONCLUSION: Bone graft was successfully completed in 63 patients. The induced membrane formed in the early stage group was thin and there were relatively more capillaries, while the induced membrane formed in the late stage group was usually thick and there were relatively few capillaries. All 63 patients were followed up for 16-50 months. In the early stage group, the wound or incision healed at first intention in 22 patients and delayed healing was observed in 3 patients. In the late stage group, the wound or incision healed at first intention in 34 patients, delayed healing was observed in 2 patients, and healing by the second intention was observed in 2 patients. In the early stage group, there was 1 patient developing delayed healing, no nonunion was observed, the clinical healing time was averaged 6.64 (range 5.0-12.0 months) months. In the late stage group, delayed healing occurred in 2 patients and nonunion was observed in 1 patient. The clinical healing time was averaged 7.42 (range 5.0-16.0 months) months. There were no significant differences in the healing time and nonunion between the early stage and late stage groups (P > 0.05). In the early stage group, excellent functional recovery of affected limb was observed in 13 patients, good recovery in 11 patients, and fair recovery in 1 patient, and it was 17, 18 and 3 patients respectively in the late stage group. There was no significant difference in functional recovery of affected limbs between early stage and late stage groups (P > 0.05). These results showed that bone grafting within the induced membrane at different time has slight, but not significant effect on healing of bone defect. Other factors, such as the size and the integrity of induced membrane, the quality and quantity of bone graft material, and the stability of bone stumps had more significant effects on the healing of bone defects, in particular on the healing rate.
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BACKGROUND: At present, scholars at home and abroad try to promote the growth of bone graft by changing the types and morphology of implant materials, and improving the thickness and smoothness of induced membrane. OBJECTIVE; To compare the degree of vascularization and the expression of some osteogenic factors in the polymethylmethacrylate bone cement membrane with different surface roughness degrees at different femoral bone defects in rats. METHODS: Forty-eight male Sprague-Dawley rats (purchased from the Experimental Animal Center of Guangzhou University of Chinese Medicine) were used to establish rat models of critical-size femur defect. These rat modes were then randomly divided into groups A, B, C and D. Polymethylmethacrylate bone cement occupiers with surface roughness 0.05). Immunohistochemical staining revealed that the positive expression of bone morphogenetic protein 2, transforming growth factor (31 and vascular endothelial growth factor protein was similar among four groups (P>0.05). These findings suggest that the change of surface roughness of bone cement has no significant effect on the histomorphological structure of induced membrane and the expression of bone morphogenetic protein 2, transforming growth factor pi and vascular endothelial growth factor in induced membrane at 6 weeks after implantation of bone cement spacer.
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BACKGROUND: Studies have found that polymethylmethacrylate bone cement implanted in the subcutaneous region, muscle and other parts can form induced membrane. The induced membrane favors vascularization and secretes multiple osteogenic factors. OBJECTIVE: To investigate the differences in the level of vascularization and the expression of osteogenic factors in the induced membrane among subcutaneous region, muscle and femoral bone defects. METHODS: Thirty-six male SD rats (purchased from the Experimental Animal Center of Guangzhou University of Chinese Medicine) were randomly divided into three groups (n=12/group). Polymethylmethacrylate antibiotic cement spacers were implanted in the subcutaneous tissue, muscle and femoral bone defects of the hind limbs. At 6 weeks after implantation, the induced membrane around the bone cement was removed. The change in membrane morphology was observed by hematoxylin-eosin staining. Expression of bone morphogenetic protein-2, transforming growth factor-31 and vascular endothelial growth factor in the induced membrane was detected by western blot, RT-qPCR and immunohistochemistry. This study was approved by Animal Ethics Committee, Guangzhou University of Chinese Medicine, China (approval No. 20181101006). RESULTS AND CONCLUSION: Hematoxylin-eosin staining showed that induced membrane formed in each group. The number of vessels in the outer layer of the membrane tissue section was higher in the femoral bone defect groups than that in the muscle and subcutaneous tissue group. The number of fibroblasts and myofibroblasts in the inner layer close to the bone cement was higher in the femoral bone defect group than in the muscle and subcutaneous tissue groups. Immunohistochemical staining revealed that bone morphogenetic protein-2, transforming growth factor-31 and vascular endothelial growth factor expression levels were highest in the femoral bone defect group and lowest in the subcutaneous tissue group. Western blot and RT-qPCR showed that bone morphogenetic protein 2, transforming growth factor 31 and vascular endothelial growth factor expression levels were significantly higher in the femoral bone defect group than in the muscle and subcutaneous tissue groups (P < 0.001). These findings suggest that different surrounding tissue conditions have different important influences on tissue structure and osteogenic factor expression in the induced membrane. Polymethylmethacrylate bone cement implanted in the femoral bone defects can improve the quality of induced membrane formation, lead to a larger amount of newly formed vessels and higher osteogenic factor expression in the induced membrane.
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BACKGROUND: The course of infectious bone nonunion is often difficult to heal and has a high risk of recurrence, which brings great trouble to patients’ lives. With the continuous research on the induced membrane technique, the advantages of the treatment of infectious nonunion with the induced membrane technique have gradually emerged and become a new research direction of medical work. OBJECTIVE: To explore the action mechanism of induced membrane technology in the treatment of infectious nonunion. METHODS: The relevant domestic and foreign literatures from 2013 to 2019 of PubMed, MEDLINE, Wanfang, CNKI, VIP, and Ubiquitous Chinese Biomedical Literature Database were retrieved. The key words were “induced membrane technique, infectious nonunion, induced membrane, growth factor” in Chinese and English. RESULTS AND CONCLUSION: The biological structure and function of the induced membrane are similar to that of the periosteum. It can induce the formation of osteoblasts and promote the growth of bone tissue. The induced membrane can secrete many kinds of growth factors, such as vascular endothelial growth factor, bone morphogenetic protein 2 and transforming growth factor β1. The application of induced membrane technology in clinic, especially in the field of fracture, has achieved remarkable results, which provides a new choice for the treatment of infectious nonunion. Exploring the most suitable stuffing material and bone grafting time and the dynamic ratio of the two have become the breakthrough point and challenge of this technology.
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BACKGROUND: With the constant development of current society, traumatic bone injury caused by the traffic and other accidents becomes more and more common. Bone defect scope is increasingly extend, and the treatment results in the long cycle, the high cost, and the uncontrolled effect, accompanied with infections, bone nonunion and other complications, which not only causes the painfulness of the patient physically and mentally, but also is a difficult problem and challenge for orthopedic surgeons at the same time. OBJECTIVE: To analyze the advantages and disadvantages of traditional treatments and their latest progress, and focus on the research progress and advantages of tissue engineering technology in treating bone defect. METHODS: The author took “bone defect, bone transplantation, tissue engineering, induced membrane technology, bone transfer technology, endothelial progenitor cells, 3 D printing technology” as the key words, and data were summarized by searching CNKI, Wanfang and Pub Med databases. Totally 120 related literatures were retrieved. Through reading the title, abstract and part of the literature content, the outdated, ambiguous and repetitive literatures were excluded. Finally, 49 literatures meeting the inclusion criteria were selected for review. RESULTS AND CONCLUSION:(1) Traditional bone defect treatment has certain defects. The emergence of bone tissue engineering technology is expected to become one of the most effective ways for bone defect.(2) Seed cells have good osteogenic properties and can secrete some important factors.(3) Scaffold material can provide mechanical strength for patients in early stage, and has advantages of good biocompatibility, bone induction, and controllable degradation.(4) The urgent problem of vascularization is also being solved gradually, which can bring good news to the patients with bone defect.
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BACKGROUND: Masquelet technique is one of the effective methods to repair large bone defects. This technique requires the use of more autologous bone in the second stage of surgical treatment. However, the source of autologous bone is limited and the complications in the donor area are inevitable. How to reduce the use of autologous bone is an urgent problem to be solved. OBJECTIVE: By combining with the development status of induced membrane technology at home and abroad, this review introduced some effective methods to reduce the amount of autologous bone in induced membrane technology, including filling bone graft replacement materials and some special surgical methods. METHODS: The first author used a computer to retrieve the literature published in PubMed, CNKI and Wanfang databases from January 1996 to September 2019. The search terms were “Masquelet technique; induced membrane; bone transport technique; autologous bone; bone defect; bone graft; 3D printing; tissue engineering”. RESULTS AND CONCLUSION: Since the emergence of the Masquelet technique, the technique has been constantly improved and innovated by scholars. However, there is no international consensus on how to reduce the use of autologous bone in the second stage of Masquelet technique. At present, each of improvement methods has its own advantages and disadvantages, and clinicians need to choose according to objective conditions. The method proposed by Jong-Keon Oh, using gelfoam as the bone grafting center and the peripheral ring for bone grafting, is simple and practical. Tissue engineering technology has potential for development. With the further study of seed cells and scaffold materials, it will gradually replace the existing treatment schemes. According to the existing research, the research direction of Masquelet technique in the future can be roughly summarized into four directions: The improvement of membrane technology, the improvement of surgical methods, the application of combined materials, and the application of 3D printing and tissue engineering technology. These directions need further exploration and development by scholars.
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Objective: To investigate the effect of Masquelet technique combined with artificial dermis on repairing bone and soft tissue defects in rabbits, and to observe the microstructure and vascularization of induced membrane, so as to guide the clinical treatment of Gustilo-Anderson type Ⅲ open fracture with large bone defect and soft tissue defect. Methods: Eighty male rabbits, weighing 2.03-2.27 kg (mean, 2.11 kg), were selected. The bilateral thighs of 64 rabbits were randomly divided into experimental group and control group, the remaining 16 rabbits were sham operation group. Bone and soft tissue defect models of femur were made in all rabbits. In the experimental group, the first stage of Masquelet technique was used [polymethyl methacrylate bone cement was filled in bone defect area] combined with artificial dermis treatment; in the control group, the first stage of Masquelet technique was used only; in the sham operation group, the wound was sutured directly without any treatment. Four rabbits in sham operation group and 16 rabbits in the experimental group and control group were sacrificed at 2, 4, 6, and 8 weeks after operation, respectively. The induced membranes and conjunctive membranes were observed on both sides of the femur. The membrane structure was observed by HE staining, and the microvessel density (MVD) was counted by CD34 immunohistochemical staining. Results: Gross observation showed that the spongy layer of collagen in the artificial dermis of the experimental group disappeared completely at 4 weeks after operation, and the induced membrane structure of the experimental group and the control group was complete; the membrane structure of the control group was translucent, and the membrane structure of the experimental group was thicker, light red opaque, accompanied by small vessel proliferation. The membrane structure of the experimental group and the control group increased gradually from 6 to 8 weeks after operation. In the sham operation group, only scar tissue proliferation was observed over time. HE staining showed that a large number of muscle fibers and a small amount of collagen fibers proliferation with inflammatory cell infiltration could be seen in the experimental group and the control group at 2 weeks after operation; most of the sham operation group were muscle fibers with a small amount of interfibrous vessels. At 4 weeks after operation, collagen fibers increased and some blood vessels formed in the experimental group. The nuclei of collagen fibers in the control group were round-like, while those in the experimental group were flat-round. At 6 and 8 weeks after operation, the collagen fibers in the experimental group and the control group increased. The nuclei of the collagen fibers in the control group were still round-like. The nuclei of the collagen fibers in the experimental group were fusiformis and deeply stained compared with those in the control group. The proliferation of blood vessels was observed in both groups, and the number of proliferation vessels in the experimental group was increased compared with that in the control group. In the sham operation group, a large number of fibroblasts still appeared, but no significant proliferation of blood vessels with time was observed. CD34 immunohistochemical staining showed that MVD in each group increased gradually with the prolongation of time after operation. MVD in the sham operation group was significantly higher than that in the experimental group and the control group at 2 weeks after operation, and significantly smaller than that in the experimental group and the control group at 4, 6, and 8 weeks after operation ( P0.05). Conclusion: Masquelet technique combined with artificial dermis in the treatment of femoral bone defect and soft tissue defect in rabbits can significantly promote the vascularization of membrane structure at 4-6 weeks after operation. The combination of these two methods has guiding significance for the treatment of Gustilo-Anderson type Ⅲ open fracture with bone and soft tissue defects.
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Objective@#To evaluate the induced membrane technique combined with microsurgery for repair of open leg fractures of Gustilo types ⅢB-C.@*Methods@#This retrospective study reviewed 15 patients who had been treated for open leg fractures of Gustilo types ⅢB and ⅢC by the induced membrane technique and microsurgery between January 2015 and January 2017 at Institute of Orthopedics, 920 Hospital, The Joint Logistic Service of The People’s Liberation Army. They were 10 men and 5 women, aged from 18 to 41 years(average 32 years). There were 9 cases of Gustilo type IIIB and 6 ones of Gustilo type IIIC. After thorough debridement, the fractures were reduced and fixated temporarily using external frames. The bone defects were filled with antibiotic bone cement to induce biofilm formation. After necessary reconstruction of limb structures, including neurovascular repair and transposition of tendon and nerve, crucial soft-tissue wounds were covered with surgical flaps. In the secondary surgery 6 to 8 weeks later, with the external frames replaced by internal fixation or not, the bone cement was removed without damaging the biofilm before graft reconstruction with autogenous cancellous bone.@*Results@#The 15 legs were all salvaged successfully. The in-hospital time ranged from 21 to 39 days (mean, 29 days). Crucial wounds were repaired primarily without any severe or persistent infection. Follow-ups ranged from 12 to 24 months (average, 15 months). Bone union time ranged from 10 to 17 months (average, 11.2 months) with satisfactory aesthetic and functional recovery of the leg.@*Conclusion@#Reconstruction of open leg fractures of Gustilo types Ⅲ B-C with induced membrane technique and microsurgery can result in decreased therapeutic duration, reduced complications and positive outcomes.
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Objective To evaluate the induced membrane technique combined with microsurgery for repair of open leg fractures of Gustilo types Ⅲ B-C.Methods This retrospective study reviewed 15 patients who had been treated for open leg fractures of Gustilo types ⅢB and ⅢC by the induced membrane technique and microsurgery between January 2015 and January 2017 at Institute of Orthopedics,920 Hospital,The Joint Logistic Service of The People's Liberation Army.They were 10 men and 5 women,aged from 18 to 41 years (average 32 years).There were 9 cases of Gustilo type ⅢB and 6 ones of Gustilo type ⅢC.After thorough debridement,the fractures were reduced and fixated temporarily using external frames.The bone defects were filled with antibiotic bone cement to induce biofilm formation.After necessary reconstruction of limb structures,including neurovascular repair and transposition of tendon and nerve,crucial soft-tissue wounds were covered with surgical flaps.In the secondary surgery 6 to 8 weeks later,with the external frames replaced by internal fixation or not,the bone cement was removed without damaging the biofilm before graft reconstruction with autogenous cancellous bone.Results The 15 legs were all salvaged successfully.The in-hospital time ranged from 21 to 39 days (mean,29 days).Crucial wounds were repaired primarily without any severe or persistent infection.Follow-ups ranged from 12 to 24 months (average,15 months).Bone union time ranged from 10 to 17 months (average,11.2 months) with satisfactory aesthetic and functional recovery of the leg.Conclusion Reconstruction of open leg fractures of Gustilo types Ⅲ B-C with induced membrane technique and microsurgery can result in decreased therapeutic duration,reduced complications and positive outcomes.
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OBJECTIVE: To investigate the effects and its mechanism of calcium phosphate bone cement (CPC) loading total flavonoids of Davallia mariesii on osteogenic differentiation of induced membrane in rats. METHODS: Drug-loading CPC and drug-loading polymethyl methacrylate (PMMA) cement were prepared with the contents of Qianggu capsules (total flavonoids of D. mariesii as active ingredient) using CPC and PMMA cement as carrier. Totally 64 male SD rats were randomly divided into drug-loading CPC group, drug-loading PMMA cement group, no-drug CPC group, no-drug PMMA cement group, with 16 rats in each group. The femur of rats was separated and osteotomized to prepare bone defect model, and then the corresponding bone cement was implanted. Four weeks after modeling, the induced membranes of rats were cut and protected. Bone cement was taken out and autogenous cancellous bone was implanted. At the 4th week after modeling, X-ray photographs were taken on the hind limb bones of rats. At the 4th week after modeling and 6th week after bone grafting, induced membranes and new bone were taken from the bone defect area of rats respectively. HE staining was used to observe the morphology of induced membrane, and the width of bone rabecular and the number of osteoblasts of new bone tissue were measured. Immunohistochemistry was used to detect the protein expression of BMP-2 and VEGF in induced membrane. Western blotting assay was used to detect the protein expression of Smad1, Smad4 and Smad7 in new bone. RESULTS: Compared with other 3 groups, the degradation of bone cement in drug-loading CPC group was more obvious in the bone defect areas, which showed that the formation of induced membrane was observed and the bone defect areas were smaller; capillary endothelial cells were abundant and orderly arranged in the induced membranes, and the width of bone trabeculae and the number of osteoblasts in the new bone tissue increased significantly (P<0.05); the protein expression of BMP-2 and VEGF in the induced membrane, the protein expression of Smad1, Smad4 and Smad7 in new bone were increased significantly (P<0.05). CONCLUSIONS: CPC loading total flavonoids of D. mariesii promotes the formation of induced membrane osteoblast in bone defect model rats, which may be associated with regulating osteoblast differentiation by activating BMP-2/Smad pathway; at the same time, it can promote bone healing by promoting the differentiation of vascular endothelial cells, accelerating the formation of capillary network and increasing the expression of vascular endothelial cells.
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Resumen: Objetivo: Demostrar los resultados en la neoformación ósea de tibia utilizando la técnica de inducción de membrana más la transposición de peroné ipsolateral no vascularizado. Caso clínico: Masculino de 25 años, antecedente de sufrir impacto por arma de fuego en pierna izquierda dos años antes, presentó un diagnóstico inicial de fractura expuesta Gustilo IIIB AO 42C3 IO4NV1MT2 con pérdida ósea de 7 cm de diáfisis tibial. Durante su evolución se realizaron múltiples aseos quirúrgicos y colocación de injertos cutáneos con resultados no favorables, por lo que se emplea la técnica de membrana inducida más colocación de peroné ipsolateral no vascularizado, teniendo una evolución a los cuatro meses posterior a su última intervención con deambulación dependiente de bastón. Conclusión: La técnica de inducción de membrana con transposición de peroné ipsolateral no vascularizado podría ser una alternativa adecuada para el manejo de pérdidas óseas en los pacientes.
Abstract: Objective: To demonstrate the outcome of tibial bone neo formation, using induced-membrane technique and non-vascularized ipsolateral fibular graft transposition. Case report: A 25 years old male with a 2 years ago firearm injury in left leg, presenting an initial diagnosis of open fracture Gustilo IIIB AO 42C3 IO4NV1MT2 with a 7cm tibial diaphyseal bone defect. During his hospital evolution multiple interventions were made including surgical debridement and skin grafts placement, with unfavorable results. Therefore, we decided to use the induced-membrane technique and non-vascularized ipsolateral fibular graft transposition, resulting in a cane dependent ambulation, in 4 months evolution after last intervention. Conclusion: Induced-membrane technique and non-vascularized ipsolateral fibular graft transposition could be a successful alternative for the management of patients with severe bone loss.
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Humans , Male , Adult , Tibia/surgery , Bone Transplantation , Plastic Surgery Procedures , Fibula , Fibula/surgery , Skin Transplantation , Treatment Outcome , Fractures, Open/surgeryABSTRACT
Treatment of large bone defects caused by trauma, osteomyelitis, and tumors has been a major challenge in clinical. In the past, there have been many ways to repair and reconstruct the large bone defects. However, there is a long period of treatment, high technical requirement and complications such as ununion. After Masquelet reported the induced membrane technology in 2000, the technique was widely used in treatment of trauma, osteomyelitis, and large bone defects caused by tumors. It has been obtained good results. It has the advantages of short course, high healing rate, easy operation and easy to master. The induced membrane has unique structural characteristics and biological characteristics. There are many kinds of osteogenic factors that are included in the membrane, such as vascular endothelial growth factor, and morphogenetic protein-2, transforming growth factor-β1, etc. These osteogenic factors contribute to accelerate bone healing. With the development of induced membrane technology. The technology of Reamer Irrigator Aspirator technology, engineering tissue technology and internal fixation is used in clinic.It can provide bone source, promote bone defect reconstruction, improve long-term limb function and reduce complications.This paper retrospectively summarizes the experimental research and clinical progress of Masquelet technique in the treatment of large bone defects.
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Objective To evaluate the induced membrane technique (Masquelet technique) used for restoration of long bone defects of infected tibia.Methods This retrospective study evaluated 44 patients with long bone defect of infected tibia who had been treated at Department of Orthopedics,The Second Affiliated Hospital by the induced membrane technique between January 2004 and January 2017.They were 31 males and 13 females,aged from 18 to 71 years (mean,43.7 years).Of them,17 were complicated with diabetes,13 with primary hypertension,and 12 with more than two basic diseases.Their bone defects ranged from 6 to 17 cm (average,11 cm).Their postoperative fracture healing and complications were observed.Results This cohort received from 2 to 5 operations on average (average,3.7 operations).All the patents obtained bony union after 9 to 13 months (average,11.3 months).Their follow-ups ranged from 16 months to 11 years (average,3.1 years).Nineteen complications related to the surgery occurred in 15 cases.Skin healing problem after implantation of bone cement was found in 5 cases which called for operative intervention,infection relapsed in 8 patients after the first phase of cement implantation which necessitated further surgical debridement for successful management,local haematoma appeared after bone grafting in one case of 17 cm bone defect,implant failure occurred in one case,leg length discrepancy larger than 2 cm was observed in 3 cases,and a discharging sinus developed in one case 2 years after successful healing of a tibial defect.Conclusions The induced membrane technique appears to be a good alternative management for large tibial defects secondary to infection.The technique should be considered in the surgeon's armamentarium and patients conditions as it is effective and associated with a low rate of complications.
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Bone defects,a challenge in orthopedics,are mostly caused by severe trauma,bone tumor and bone infection.Their chief treatments include bone graft,distraction osteogenesis and Masquelet technique.Compared with other treatments,Masquelet technique is simpler and causes fewer complications,especially for infectious defects.In the first stage of Masquelet technique,a bone defect is filled with bone cement.The spacer most commonly used is polymethylmethacrylate(PMMA).PMMA can form induced membrane rich in blood vessels and bioactive components promoting osteogenesis,but it is not biodegradable,lacks bone conductibility,has an obvious thermal effect during operation,and is hard to remove in the second phase of Masquelet technique.Calcium sulfate and calcium phosphate bone cement are biodegradable materials which overcome the defects of PMMA due to their biological absorbability,bone conduction and bone inducement.It is possible for them to replace PMMA in Masquelet technique,but their poor mechanical strength limits their application.There is clinical evidence showing that calcium sulfate bone cement can form obvious induced membrane.As calcium silicate cement can also form a layer of fibrous tissue around the shell,it may be applied in orthopaedic surgery after improvement as a potential filling agent.A structure like induced membrane can form around a silicone prosthesis,and it functions similarly as induced membrane around PMMA and is more resistant to a radiation environment.Silicone has obvious advantages over PMMA after resection of bone tumor.Spacers used in the first stage of Masquelet technique have important effects on formation process and quality of induced membranes.By comparing membranes induced by different types of spacer,we can know more about the effects of spacers on induced membranes in the first stage of Masquelet technique and thus discover the most suitable spacers good for fracture healing and membrane formation.
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Objective To explore the clinical application and effect of induced membrane technique com-bined with anteriolateral thigh(ALT)flap transfer for repair of complex tissue defect of the lower extremity. Methods From June,2011 to June,2014,induced membrane technique combined with ALT flap transfer were applied to repair complex tissue defect of the lower extremity in 12 cases. Of the 12 cases, there were 11 males and one female(their ages ranged from 18 to 45 years, 35 years on average). One caused by road accident,4 cases were caused by crush injury, 7 cases were caused by squeeze injury. First stage, the soft tissue defect were repaired by ALT flap transfer, the bone defect were filled with antibiotic cement after debridement and fixed with external or internal fixation. The area of the ALT flap ranged from 9.0 cm×15.0 cm to 15.0 cm×20.0 cm. The length of bone defect ranged from 3.0 cm to 14.0 cm,one of them was muscucaneous flap. Second stage,bone defect were filled with cancellous bone following cement removal in 6 to 12 weeks,8 weeks on average. Results All cases were successfully repaired. Twelve cases were followed up. A mean follow-up was 20 months. All flaps survived,11 cases were healed in first stage. One case were healed in second stage,healing time ranged from 12 to 18 days; bone healing time ranged from 6 to 9 months, 7 months on average. The functions of supplied regions were not found malfunctional. Conclusion Induced membrane technique combined with anteriolateral thigh flap transfer reduce patient treatment time,improve the ability of resis-tance to infection of bone transfer,is an optimal method to repair the complex tissue defect of the lower extremity.
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Objective To investigate the clinical effectivity of the muscular flap transposition and induced membrane technique in the emergency treatment for the limb salvage of Gustilo type Ⅲ B/C open fracture of lower leg. Methods From July, 2015 to December, 2017, 10 cases of Gustilo type Ⅲ B/C fracture of lower leg with bone defects were performed limb salvage surgery. Induced membrane technique was used to fill the bone defects in the emergency room.The gastrocnemius and/or soleus muscular flaps were transposed to cover the bone cement or ex-posed bone simultaneously in emergence treatment. After the wound healed completely, traditional bone grafting was used to repair the bone defects. There were 4 cases of Gustilo type Ⅲ B and 6 cases of Gustilo type Ⅲ C. The aver-age length of bone defect was (5.25±1.70) cm ranging from 3.0 cm to 11.0 cm. The gastrocnemius medial head flaps were performed in 5 cases, the combined application with the gastrocnemius medial head flaps and the medial hemimuscular flaps of soleus were performed in 2 cases, and medial hemimuscular flaps of soleus were transposed in 3 cases. Results The wounds in 6 cases were healed at one stage, but 2 cases healed by dressing because the exudate after skin grafting.In 1 case, the cross-leg flap was used to cover the exposed bone cement due to the necro-sis of soleus flap. The other 1 was performed the transposition of the lateral gastrocnemius flaps because the exposure of bone cement after the necrosis of the upper and lateral muscles in lower leg. In the second-stage, the bone defects were reconstructed by traditional bone grafting. The average healed time of bone was 7.2 months ranging from 5 months to 9 months. At the last followed-up time, all patients recovered their function of weight-bearing. The Paley's score of the adjacent joints: excellent in 8 cases and good in 2 cases. Conclusion The combination with induced membrane technique and local muscular flap transposition in emergency surgery is an effective method to limb salvage for the Gustilo type Ⅲ B/C open fracture of lower leg.
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Objective To study the clinical efficacy of two-stage bone transport combined with induced membrane technique in the treatment of post-traumatic tibial osteomyelitis.Methods A retrospective study was conducted of the 14 patients with post-traumatic tibial osteomyelitis who had been treated by two-stage bone transport combined with induced membrane technique from February 2009 to August 2015.They were 12 males and 2 females,aged from 26 to 59 years (average,40.4 years).By the Cierny & Mader classification,they all belonged to type Ⅳ.Their disease course ranged from 6 to 30 months,averaging 15.3 months.The number of their previous operations ranged from 2 to 6 times,averaging 3.3 times.In the first stage of operation,tibial extended external fixation was installed according to preoperative design,followed by early debridement and extensive removal of osteomyelitis lesion.The length of bone defect after resection of osteomyelitis lesion was from 4 to 18 cm (average,8.5 cm).10% vancomycin-contained polymethyl methacrylate (PMMA) bone cement was molded and placed in the bone defects.In the second stage of operation,the PMMA-induced membrane was opened to remove the PMMA bone cement,the bone marrow was drilled through and the induced membrane was then sutured up.Tibial osteotomy was conducted at an appropriate part.The average interval between the first and second stages was from 4 to 7 weeks (average,4.8 weeks).The clinical efficacy was evaluated according to the Paley criteria at final follow-ups.Complications were recorded.Results All the patients were followed up for 15 to 50 months (17.5 months).No relapse of osteomyelitis occurred.The total treatment time ranged from 11 to 19 months,with an average of 14.7 months.The total time for external fixation was from 10 to 18 months,averaging 13.2 months.The external fixator indexes ranged from 31 to 75 day/cm,with an average of 48.5 day/cm.According to Paley criteria at final follow-ups,the clinical efficacy was excellent in 11 and good in 3 cases.Pin tract infection occurred in 9 patients,mal-alignment after removal of external fixation in 6,and malunion or nonunion at the docking site in 5.Conclusions Two-stage bone transport combined with induced membrane technique can cure thoroughly post-traumatic tibial osteomyelitis.Its operation procedures are simple but effective.