摘要
背景:前期研究表明,酸性成纤维细胞因子复合部分脱蛋白骨具有很好的促进早期股骨头缺血坏死动物模型血管化的作用,而X射线也是评价骨愈合很重要的指标。目的:应用X射线评估酸性成纤维细胞因子复合部分脱蛋白骨对兔股骨头缺血性坏死的修复作用,并与单纯生物衍生骨进行比较。设计、时间及地点:随机对照动物实验,于2008-01/2009-01在南华大学生命科学院完成。材料:取健康成年新西兰大白兔肋骨,经脱脂、脱蛋白、部分脱钙和冻干等一系列的物理、化学方法处理后制备部分脱蛋白骨。将酸性成纤维细胞生长因子用无菌蒸馏水稀释后加入部分脱蛋白骨粒,得到复合人工骨。方法:健康成年新西兰大白兔24只,双侧股骨头颈交界处开窗,挖除股骨头内约50%松质骨,加用体积分数为95%乙醇灌注30min,建立双侧股骨头坏死骨缺损模型。按随机数字表法,随机分为空白组,单纯部分脱蛋白骨组,复合人工骨组,并将部分脱蛋白骨、复合人工骨同期手术植入。主要观察指标:分别于术后2,4,8周取材,进行X射线照片观察。结果:空白组整个过程都呈低密度影;8周时缺损区仍呈X射线低密度影,有2只出现股骨头塌陷。单纯部分脱蛋白骨组2周和4周时植骨区与周围正常骨组织清晰可见,8周时1只股骨头X射线表现正常,2只缺损区与周围正常骨组织仔细辨别可区分,但已模糊不清。复合人工骨组4周时移植物与周围正常骨组织界限不清,需仔细辨别才能区分;8周时所有股骨头缺损区与周围正常骨组织融合,与宿主骨界限不清。X射线评分结果显示,复合人工骨组优于空白组(P<0.05),单纯部分脱蛋白骨组和复合人工骨组之间差异无显著性意义(P>0.05)。结论:X射线显示酸性成纤维细胞生长因子与部分脱蛋白骨复合构建组织工程化人工骨对兔早期股骨头缺血坏死具有较好的修复作用,与单纯部分脱蛋白骨表现相似。
BACKGROUND: Prior studies have demonstrated that acidic fibroblast growth factor (aFGF) composited by partially deproteinized bone (PDPB) (aFGF/PDPB) well promotes vascularization in animals with early-stage avascular necrosis of the femoral head (ANFH). OBJECTIVE: To evaluate the repairing effects of aFGF/PDPB on ANFH in rabbits using X-ray examination and to compare the effects with PDPB. DESIGN, TIME AND SETTING: A randomized, controlled, animal experiment was performed in the College of Life Science, Nanhua University between January 2008 and January 2009. MATERIALS: Ribs from healthy, adult, New Zealand rabbits were prepared into PDPB by a series of physico-chemical methods including degreasing, deproteinization, partial decalcification, and freeze drying. aFGF diluted with sterile distilled water was composited by PDPB particles to prepare artificial composite bone. METHODS: A bone window was made at the juncture of femoral head and femoral neck bilaterally in 24 healthy, adult, New Zealand rabbits. Rabbit models of bilateral ANFH were established by removing approximately 50% of cancellous bone and perfusion with 95% ethanol. Successful bilateral ANFH models were randomly divided into 3 groups: blank, PDPB, and aFGF/PDPB. PDPB and artificial composite bone were implanted into the PDPB and aFGF/PDPB groups accordingly. The blank group did not receive any implantation. MAIN OUTCOME MEASURES: At 2, 4, and 8 weeks after surgery, specimen tissue was harvested for X-ray examination. RESULTS: In the blank group, low-density shadow appeared through the whole process and it was present in the defect region at 8 weeks; in addition, 2 rabbits exhibited collapse of the femoral head. In the PDPB group, at 2 and 4 weeks, bone grafting region and adjacent normal bone tissue could be clearly seen, and at 8 weeks, X-ray examination showed normal femoral head in 1 rabbit, and bone defect regions could be distinguished, but unclear, from adjacent normal bone tissue after careful discrimination in 2 rabbits. In the aFGF/PDPB group, at 4 weeks, the borderline between implants and adjacent normal tissue was not clear, and it should be carefully distinguished; at 8 weeks, bone defect regions of all femoral head fused with adjacent normal tissue without borderline. X-ray evaluation results demonstrated that aFGF/PDPB group yielded better effects than blank group (P 〈 0.05), and there was no significant difference between PDPB and aFGF/PDPB groups (P 〉 0.05). CONCLUSION: X-ray results show that tissue-engineered artificial bone composited by aFGF/PDPB exhibits better effects on repairing early-stage ANFH in rabbits, with presentations resembling to PDPB.
出处
《中国组织工程研究与临床康复》
CAS
CSCD
北大核心
2009年第42期8260-8264,共5页
Journal of Clinical Rehabilitative Tissue Engineering Research
基金
a Grant from Shenzhen Bureau of Science and Technology,No.200702043~~