中国组织工程研究
中國組織工程研究
중국조직공정연구
Journal of Clinical Rehabilitative Tissue Engineering Research
2013年
35期
6273-6280
,共8页
张延辉%姜宏春%李静%张宝弟
張延輝%薑宏春%李靜%張寶弟
장연휘%강굉춘%리정%장보제
骨关节植入物%脊柱损伤基础实验%生物力学%有限元方法%腰椎融合%小关节融合%融合模型%载荷%矩阵实验室
骨關節植入物%脊柱損傷基礎實驗%生物力學%有限元方法%腰椎融閤%小關節融閤%融閤模型%載荷%矩陣實驗室
골관절식입물%척주손상기출실험%생물역학%유한원방법%요추융합%소관절융합%융합모형%재하%구진실험실
bone and joint implants%basic experiment of spinal cord injury%bone tissue engineering%biomechanics%finite element method%lumbar fusion%facet joint fusion%fusion model%loading%matrix laboratory
背景:MATLAB具有大型数值计算、数学绘图和简单有限元分析的能力,建模速度快,能够识别BMP和JPG格式的灰度图,并可将识别的数据直接转换为ANSYS三维有限元软件可识别的格式,避免了常规在Autocad软件中图像的重新定位和二次处理而产生的人为误差。<br> 目的:寻求一种简便、快捷、准确的方法建立各种腰椎融合模型,对腰椎融合后腰椎活动节段的生物力学进行分析。<br> 方法:利用薄层CT技术,结合Matlab(Matrix Laboratory即矩阵实验室)科学计算软件,辅助Ansys有限元分析软件建立各种腰椎融合模型。对所建立的模型施加各种载荷,分析其生物力学变化。<br> 结果与结论:对所建立的融合模型施加轴向、屈曲及伸展载荷后,生物力学分析得出所有的融合模型中椎体间融合稳定性最好。和关节间融合相结合,椎体间,侧后方,后方融合模型的轴向位移较单独的椎体间,侧后方和后方融合模型分别减少5%、1%和4%。在伸展-屈曲载荷条件下旋转角度分别减少23%、11%和45%。应力向融合部位集中的现象表明融合块可增加载荷的转移。说明薄层CT和Matlab软件的辅助使得Ansys有限元软件建立腰椎融合模型的速度和精度提高。小关节融合和椎体间,侧后方,后方融合相结合,可使腰椎获得更好的稳定性,这种稳定性的增加在后方融合中更为显著。后方融合模型的应力分布更加合理。
揹景:MATLAB具有大型數值計算、數學繪圖和簡單有限元分析的能力,建模速度快,能夠識彆BMP和JPG格式的灰度圖,併可將識彆的數據直接轉換為ANSYS三維有限元軟件可識彆的格式,避免瞭常規在Autocad軟件中圖像的重新定位和二次處理而產生的人為誤差。<br> 目的:尋求一種簡便、快捷、準確的方法建立各種腰椎融閤模型,對腰椎融閤後腰椎活動節段的生物力學進行分析。<br> 方法:利用薄層CT技術,結閤Matlab(Matrix Laboratory即矩陣實驗室)科學計算軟件,輔助Ansys有限元分析軟件建立各種腰椎融閤模型。對所建立的模型施加各種載荷,分析其生物力學變化。<br> 結果與結論:對所建立的融閤模型施加軸嚮、屈麯及伸展載荷後,生物力學分析得齣所有的融閤模型中椎體間融閤穩定性最好。和關節間融閤相結閤,椎體間,側後方,後方融閤模型的軸嚮位移較單獨的椎體間,側後方和後方融閤模型分彆減少5%、1%和4%。在伸展-屈麯載荷條件下鏇轉角度分彆減少23%、11%和45%。應力嚮融閤部位集中的現象錶明融閤塊可增加載荷的轉移。說明薄層CT和Matlab軟件的輔助使得Ansys有限元軟件建立腰椎融閤模型的速度和精度提高。小關節融閤和椎體間,側後方,後方融閤相結閤,可使腰椎穫得更好的穩定性,這種穩定性的增加在後方融閤中更為顯著。後方融閤模型的應力分佈更加閤理。
배경:MATLAB구유대형수치계산、수학회도화간단유한원분석적능력,건모속도쾌,능구식별BMP화JPG격식적회도도,병가장식별적수거직접전환위ANSYS삼유유한원연건가식별적격식,피면료상규재Autocad연건중도상적중신정위화이차처리이산생적인위오차。<br> 목적:심구일충간편、쾌첩、준학적방법건립각충요추융합모형,대요추융합후요추활동절단적생물역학진행분석。<br> 방법:이용박층CT기술,결합Matlab(Matrix Laboratory즉구진실험실)과학계산연건,보조Ansys유한원분석연건건립각충요추융합모형。대소건립적모형시가각충재하,분석기생물역학변화。<br> 결과여결론:대소건립적융합모형시가축향、굴곡급신전재하후,생물역학분석득출소유적융합모형중추체간융합은정성최호。화관절간융합상결합,추체간,측후방,후방융합모형적축향위이교단독적추체간,측후방화후방융합모형분별감소5%、1%화4%。재신전-굴곡재하조건하선전각도분별감소23%、11%화45%。응력향융합부위집중적현상표명융합괴가증가재하적전이。설명박층CT화Matlab연건적보조사득Ansys유한원연건건립요추융합모형적속도화정도제고。소관절융합화추체간,측후방,후방융합상결합,가사요추획득경호적은정성,저충은정성적증가재후방융합중경위현저。후방융합모형적응력분포경가합리。
BACKGROUND:MATLAB has capabilities of large numerical calculation, mathematical drawing and simple finite element analysis. It can establish models rapidly and can be able to identify the grayscale with BMP and JPG <br> format, and it can directly transform the identified data into ANSYS finite element software-readable format, thus avoiding personal error produced by the repositioning and secondary treatment in the Autocad software. <br> OBJECTIVE:To find a simple, convenient and accurate method to construct the model of lumber fusion and to analyze the biomechanics of lumbar motion segment after lumbar fusion. <br> METHODS:Lamel ar CT and Matlab (Matrix Laboratory) scientific computing software combining Ansys finite <br> element software was used to construct the models of lumber fusion. Then the models were loaded to analyze the biomechanical change of the fusion model. <br> RESULTS AND CONCLUSION:The established models were loaded with axial, bending and stretching loads, and the biomechanical analysis showed that interbody fusion had the best stability among al the fusion models. Combined with joint fusion, the axial displacements of interbody, rear side and rear fusion models were <br> decreased by 5%, 1%and 4%than that of simple interbody fusion, posterolateral fusion and posterior fusion models. Under the stretch-buckling load conditions, the rotation angles were reduced by 23%, 11%and 45%. Stress concentration to the fusion parts showed fusion block could increase the load displacement. The <br> technology of lamel ar CT, Matlab software and Ansys finite element software can accelerate the construction of lumber fusion model and make the model more accurate. Facet joint fusion combined with interbody fusion, <br> posterolateral fusion and posterior fusion can get better lumbar stability, and this increased stability is more significant in the rear fusion. Stress distribution of posterior fusion is more reasonable.
