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BACKGROUND:Repairing tuberculosis bone defect has become a research focus with the development of anti-tuberculosis functional bone tissue engineering scaffold. OBJECTIVE:To evaluate the preparation, drug release performance and osteogenic properties of the anti-tuberculosis functional bone tissue engineering scaffold. METHODS:PubMed, Chinese Journal Ful-text Database, Wanfang databases were searched by computer for articles addressing functional bone tissue engineering scaffold for repair of tuberculosis bone defect. The keywords were“bone tissue engineering scaffold;tuberculosis;bone defect”in English and Chinese. RESULTS AND CONCLUSION:The anti-tuberculosis functional bone tissue engineering scaffold has good drug delivery, biocompatibility, osteogenic properties and anti-tuberculosis properties. As a good choice to avert bone defect relapse, the scaffold enables a long and stable drug release into bone defects to enhance the therapeutic efficacy of anti-tuberculosis drugs topical y. Given the technical deficiencies, we can only combine two drugs with the anti-tuberculosis bone tissue engineering scaffold, although the combined use of three or four anti-tuberculosis drugs is preferred. Additional y, a complete course of anti-tuberculosis treatment often lasts for 6-12 months, which cannot be achieved by the existing anti-tuberculosis bone tissue engineering scaffold. Up to now, the effect of this scaffold has not yet been confirmed in animal models, although how to prepare this scaffold has been reported.
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BACKGROUND:Currently, the mechanism by which calcium phosphate ceramics induces osteogenesis is not fuly understood, and many scholars have tried to expound the mechanism from the perspective of the structural properties. OBJECTIVE:To review how the structural properties of calcium phosphate ceramics affect their osteoinductive activity. METHODS: The PubMed database and Google academic database (1997-01/2015-03) were searched to retrieve the related articles about the structural properties of calcium phosphate ceramics affecting their osteoinductive activity. After the articles with outdated reviews or repetitive contents were ruled out, 60 articles were suitable for further analysis and review. RESULTS AND CONCLUSION:The structural properties of calcium phosphate ceramics are displayed by macrostructure, such as macropores, holes, pipes and space between particles, and microstructure, such as micropore, particle size, surface roughness, specific surface area. Each parameter of the structural properties affects the bioactivities of calcium phosphate ceramics in some way, which renders their abilities of inducing osteogenesis to arise from nothing or change from weakly to strongly. Apart from structure design, physical and chemical properties of calcium phosphate ceramics wil also affect its biological activityin vivo. Therefore, the physicochemical properties of calcium phosphate ceramics should be considered in the structure design in order to achieve an optimal osteoinductive activity.
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BACKGROUND:The methods to treat intertrochanteric fracture are controversial. A large number of clinical studies concern the therapeutic effects of several popular methods to repair intertrochanteric fracture, but these results lack of independence, and may have bias that cannot be measured in the variable and observational studies. Thus, relevant studies have been limited. OBJECTIVE:To compare the repair effects of proximal femoral nail anti-rotation, dynamic hip screw and total hip arthroplasty on intertrochanteric fracture in aged patients by meta-analysis. METHODS: Four electronic databases were searched, including Cochrane library, PubMed, Web of Science and Chinese BioMedical Literature Database, to colect al randomized controled trials concerning the treatment of intertrochanteric fractures in the elderly with proximal femoral nail anti-rotation, dynamic hip screw and total hip arthroplasty. Using meta-analysis of evidence-based medicine, X-ray exposure time, postoperative complication rate, postoperative bed time, postoperative wound infection rate, Harris hip scores, mean operation time, intraoperative blood loss, length of hospital stays and length of the incision were compared and evaluated. Standard and methodology quality of the trials were criticaly assessed and relative data were extracted. This study used the Review Manager 5.0 software provided by Cochrane colaboration network. RESULTS AND CONCLUSION:Twelve randomized controled trials with 1 454 patients were included. Significant differences in mean operation time, intraoperative blood loss, X-ray exposure time, postoperative complication rate, and postoperative bed time were detected between the proximal femoral nail anti-rotation and dynamic hip screw groups (P < 0.05). Significant differences in length of hospital stays, postoperative complication rate, and postoperative bed time were observed between the proximal femoral nail anti-rotation and total hip arthroplasty groups (P < 0.05). Significant differences in postoperative complication rate, postoperative bed time, and Harris hip scores were detectable between the dynamic hip screw and total hip arthroplasty groups (P < 0.05). These data confirm that proximal femoral nail anti-rotation was apparently better than dynamic hip screw and total hip arthroplasty in operation time, intraoperative blood loss, length of hospital stays, postoperative complication rate, and postoperative bed time. Dynamic hip screw was better than proximal femoral nail anti-rotation in X-ray exposure time. Total hip arthroplasty was better than dynamic hip screw and proximal femoral nail anti-rotation in length of hospital stays, postoperative complication rate and postoperative bed time.
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BACKGROUND:Although bone tissue engineering scaffolds made of traditional methods have made certain achievements, the three-dimensional structure, mechanical strength and personalized property of the scaffolds are unsatisfied. 3D printing technology is expected to change these shortcomings. OBJECTIVE:To review the 3D printing of bone tissue engineering scaffolds and to prospect the optimization of the scaffolds. METHODS:A computer-based search of PubMed and Google academic database was performed for articles addressing the 3D printing of bone tissue engineering scaffolds published from 2008 to 2015. Articles concerning the structure design and materials of bone tissue engineering scaffolds and different 3D printing technologies for scaffold preparation were included, and repetitive and old articles were excluded. Final y, 37 articles were summarized. RESULTS AND CONCLUSION:Currently, 3D printing technologies used for preparation of bone tissue engineering scaffolds include melt laminated molding, stereolithography, selective laser sintering and 3DP technology. 3D printing technologies have unique advantages in mechanics, structure and personalized aspects, but there are stil many problems to be solved, such as raw materials, insufficiency of different 3D technologies, and improvement of 3D printer. Under the multi-disciplinary co-operation, 3D printing technology is expected to prepare suitable bone tissue engineering scaffolds and bring benefit to the mankind.