中华创伤骨科杂志
中華創傷骨科雜誌
중화창상골과잡지
CHINESE JOURNAL OF ORTHOPAEDIC TRAUMA
2010年
5期
459-462
,共4页
李新锋%刘祖德%戴力扬%马涛%胡光宇%钟贵彬%臧危平
李新鋒%劉祖德%戴力颺%馬濤%鬍光宇%鐘貴彬%臧危平
리신봉%류조덕%대력양%마도%호광우%종귀빈%장위평
脊髓损伤%有限元分析%生物力学
脊髓損傷%有限元分析%生物力學
척수손상%유한원분석%생물역학
Spinal cord injuries%Finite element analysis%Biomechanics
目的 利用有限元法研究不同载荷条件下颈脊髓过伸损伤时脊髓内不同区域的应力分布特征. 方法 利用颈脊髓的三维有限元模型(此模型由8484个节点和14 297个单元组成),进入Ansys前处理器,设置边界条件和不同大小的载荷配置:第Ⅰ种载荷配置:后伸载荷0.0015 N,压缩载荷1N;第Ⅱ种载荷配置:后伸载荷0.0030 N,压缩载荷2 N;第Ⅲ种载荷配置:后伸载荷0.0045 N,压缩载荷3N;第Ⅳ种载荷配置:后伸载荷0.0060 N,压缩载荷4 N;第Ⅴ种载荷配置:后伸载荷0.0075 N,压缩载荷5N.模拟不同损伤情况,进入求解模块,进行过伸损伤负载模拟计算,最后进入Ansys后处理器,读取并分析颈脊髓横断面9个不同功能区域(颈脊髓白质前索、侧索外侧部、侧索内侧部、后索外侧部、后索内侧部、灰质前角、前角底部、后角尖和头部及后角颈部)的应力分析结果. 结果 颈脊髓损伤断面应力云图提示应力主要集中于灰质前角、后角和白质前索、侧索内侧和后索外侧内,并且其平均应力依次减小.随着施加载荷的增大,灰白质内各个部位的应力均明显增加,灰质前角内的应力增幅最大.灰质前角和白质侧索的应力增幅值比较差异有统计学意义(P<0.05),后角和白质前索分别与后索应力增幅值比较差异均有统计学意义(P<0.05),后角和白质前索应力增幅值比较差异无统计学意义(P>0.05). 结论 轻度颈脊髓过伸损伤主要造成白质前索和灰质前后角损伤,表现为以上肢为主的运动和感觉异常.随着损伤载荷加大,应力分布向相邻白质扩展,载荷加大后前角支配手内肌的神经元细胞较其他部位损伤更严重.
目的 利用有限元法研究不同載荷條件下頸脊髓過伸損傷時脊髓內不同區域的應力分佈特徵. 方法 利用頸脊髓的三維有限元模型(此模型由8484箇節點和14 297箇單元組成),進入Ansys前處理器,設置邊界條件和不同大小的載荷配置:第Ⅰ種載荷配置:後伸載荷0.0015 N,壓縮載荷1N;第Ⅱ種載荷配置:後伸載荷0.0030 N,壓縮載荷2 N;第Ⅲ種載荷配置:後伸載荷0.0045 N,壓縮載荷3N;第Ⅳ種載荷配置:後伸載荷0.0060 N,壓縮載荷4 N;第Ⅴ種載荷配置:後伸載荷0.0075 N,壓縮載荷5N.模擬不同損傷情況,進入求解模塊,進行過伸損傷負載模擬計算,最後進入Ansys後處理器,讀取併分析頸脊髓橫斷麵9箇不同功能區域(頸脊髓白質前索、側索外側部、側索內側部、後索外側部、後索內側部、灰質前角、前角底部、後角尖和頭部及後角頸部)的應力分析結果. 結果 頸脊髓損傷斷麵應力雲圖提示應力主要集中于灰質前角、後角和白質前索、側索內側和後索外側內,併且其平均應力依次減小.隨著施加載荷的增大,灰白質內各箇部位的應力均明顯增加,灰質前角內的應力增幅最大.灰質前角和白質側索的應力增幅值比較差異有統計學意義(P<0.05),後角和白質前索分彆與後索應力增幅值比較差異均有統計學意義(P<0.05),後角和白質前索應力增幅值比較差異無統計學意義(P>0.05). 結論 輕度頸脊髓過伸損傷主要造成白質前索和灰質前後角損傷,錶現為以上肢為主的運動和感覺異常.隨著損傷載荷加大,應力分佈嚮相鄰白質擴展,載荷加大後前角支配手內肌的神經元細胞較其他部位損傷更嚴重.
목적 이용유한원법연구불동재하조건하경척수과신손상시척수내불동구역적응력분포특정. 방법 이용경척수적삼유유한원모형(차모형유8484개절점화14 297개단원조성),진입Ansys전처리기,설치변계조건화불동대소적재하배치:제Ⅰ충재하배치:후신재하0.0015 N,압축재하1N;제Ⅱ충재하배치:후신재하0.0030 N,압축재하2 N;제Ⅲ충재하배치:후신재하0.0045 N,압축재하3N;제Ⅳ충재하배치:후신재하0.0060 N,압축재하4 N;제Ⅴ충재하배치:후신재하0.0075 N,압축재하5N.모의불동손상정황,진입구해모괴,진행과신손상부재모의계산,최후진입Ansys후처리기,독취병분석경척수횡단면9개불동공능구역(경척수백질전색、측색외측부、측색내측부、후색외측부、후색내측부、회질전각、전각저부、후각첨화두부급후각경부)적응력분석결과. 결과 경척수손상단면응력운도제시응력주요집중우회질전각、후각화백질전색、측색내측화후색외측내,병차기평균응력의차감소.수착시가재하적증대,회백질내각개부위적응력균명현증가,회질전각내적응력증폭최대.회질전각화백질측색적응력증폭치비교차이유통계학의의(P<0.05),후각화백질전색분별여후색응력증폭치비교차이균유통계학의의(P<0.05),후각화백질전색응력증폭치비교차이무통계학의의(P>0.05). 결론 경도경척수과신손상주요조성백질전색화회질전후각손상,표현위이상지위주적운동화감각이상.수착손상재하가대,응력분포향상린백질확전,재하가대후전각지배수내기적신경원세포교기타부위손상경엄중.
Objective To investigate the mechanical responses by the cervical spinal cord to the hyperextension injury under different loading conditions. Methods A three dimensional finite element model of the cervical spinal cord was built and imported into the preprocessor of the Ansys software for assigning boundary and different loading conditions. Then the extension and pinching conditions were simulated after the solution module was entered. The stress results of 9 different anatomical regions in the cross-section of the cervical spinal cord were read and analyzed in the postprocessor of the Ansys software. Results The localized stress mainly occurred at the anterior horn and posterior horn in the gray matter, the anterior funiculus, the medial part of the lateral funiculus, and the lateral part of the posterior funiculus, with the average magnitude decreasing successively. The magnitude of the stress increased with the severity of the cervical spine injury. The maximum stress increment occurrred at the anterior horn. Significant differences in the stress increment were observed between the anterior horn and the lateral funiculus( P<0. 05). Compared with the posterior funiculus, the stress increment at the posterior horn and the anterior funiculus showed a statistical difference( P<0.05) . There was no statistical difference between the posterior horn and the anterior funiculus( P>0. 05). Conclusions The cervical hyperextension injury mainly leads to injury to the motor neuron of the anterior horn. More damage to the motor neuron dominating the intrinsic muscle of hand can lead to poorer prognosis. A greater injury load may cause stress to distribute onto more adjacent white matter.
