[犬真实颈椎运动范围与数值模拟-计算机模型验证的比较]。

IF 0.4 4区 医学 Q4 ORTHOPEDICS
R Srnec, Z Horák, R Sedláček, M Sedlinská, M Krbec, A Nečas
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引用次数: 0

摘要

在开发新的或修改现有脊柱疾病的手术治疗方法时,体外实验的一个组成部分是评估所创建结构的力学、运动学和动力学特性。本研究的目的是建立一个经过适当验证的犬颈椎数值模型,为颈椎手术的基础研究提供一个工具。出于这个目的,犬类是一个合适的模型,因为在某些品种的狗和人类中发生类似的颈椎疾病。所获得的模型也可用于研究和临床兽医实践。材料和方法为了建立三维脊柱模型,使用LightSpeed 16 (GE, Milwaukee, USA)多探测器计算机断层扫描杜宾犬颈椎。数据被传输到Mimics 12软件(Materialise HQ, Belgium),在该软件中,个体椎骨通过阈值分割在CT扫描上进行分割。将椎体几何形状导出到Rhinoceros软件(McNeel North America, USA)进行建模,随后使用专用软件Abaqus (Dassault Systemes, France)通过有限元法(FEM)分析生理脊柱模型对外部负载的响应。所有基于有限元法的数值模拟都被视为非线性接触统计任务。在有限元分析中,监测各个脊柱节段之间的角度取决于腹屈/背屈。这些数据是通过对没有明显颈椎症状的大型犬的颈椎侧位片进行验证的。在颈椎活动范围内的三个不同位置拍摄x线片:中立位,最大腹屈位和最大背屈位。在x射线上,测量了监测脊柱位置的椎体倾角,并与数值模型的有限元分析结果进行了比较。结果用有限元法测试的生理脊柱模型与犬生理脊柱的力学行为非常相似。结果值差异最大的是背屈时的C6-C7节段(Δφ = 5.95%),腹屈时的C4-C5节段(Δφ = -3.09%)。结论用有限元法模拟的数值模型与真实模型的颈椎腹屈/背屈x线片上的活动度比较,结果吻合度高,差异极小。因此,验证后的数值模型可以作为基础研究的工具,在有限元分析结果不受误差影响的情况下进行后续实验。另一方面,计算机模型只是一个简化的系统,与实际情况相比,不能充分评估力的作用在时间上的动态,它们的变异性,以及支撑骨组织的个体效应。基于以上所述,在解释已获得的结果时显然有必要保持克制。关键词:颈椎;运动学;数值模拟;
本文章由计算机程序翻译,如有差异,请以英文原文为准。
[Comparison between the Range of Movement Canine Real Cervical Spine and Numerical Simulation - Computer Model Validation].

PURPOSE OF THE STUDY In developing new or modifying the existing surgical treatment methods of spine conditions an integral part of ex vivo experiments is the assessment of mechanical, kinematic and dynamic properties of created constructions. The aim of the study is to create an appropriately validated numerical model of canine cervical spine in order to obtain a tool for basic research to be applied in cervical spine surgeries. For this purpose, canine is a suitable model due to the occurrence of similar cervical spine conditions in some breeds of dogs and in humans. The obtained model can also be used in research and in clinical veterinary practice. MATERIAL AND METHODS In order to create a 3D spine model, the LightSpeed 16 (GE, Milwaukee, USA) multidetector computed tomography was used to scan the cervical spine of Doberman Pinscher. The data were transmitted to Mimics 12 software (Materialise HQ, Belgium), in which the individual vertebrae were segmented on CT scans by thresholding. The vertebral geometry was exported to Rhinoceros software (McNeel North America, USA) for modelling, and subsequently the specialised software Abaqus (Dassault Systemes, France) was used to analyse the response of the physiological spine model to external load by the finite element method (FEM). All the FEM based numerical simulations were considered as nonlinear contact statistic tasks. In FEM analyses, angles between individual spinal segments were monitored in dependence on ventroflexion/ /dorziflexion. The data were validated using the latero-lateral radiographs of cervical spine of large breed dogs with no evident clinical signs of cervical spine conditions. The radiographs within the cervical spine range of motion were taken at three different positions: in neutral position, in maximal ventroflexion and in maximal dorziflexion. On X-rays, vertebral inclination angles in monitored spine positions were measured and compared with the results obtain0ed from FEM analyses of the numerical model. RESULTS It is obvious from the results that the physiological spine model tested by the finite element method shows a very similar mechanical behaviour as the physiological canine spine. The biggest difference identified between the resulting values was reported in C6-C7 segment in dorsiflexion (Δφ = 5.95%), or in C4-C5 segment in ventroflexion (Δφ = -3.09%). CONCLUSIONS The comparisons between the mobility of cervical spine in ventroflexion/dorsiflexion on radiographs of the real models and the simulated numerical model by finite element method showed a high degree of results conformity with a minimal difference. Therefore, for future experiments the validated numerical model can be used as a tool of basic research on condition that the results of analyses carried out by finite element method will be affected only by an insignificant error. The computer model, on the other hand, is merely a simplified system and in comparison with the real situation cannot fully evaluate the dynamics of the action of forces in time, their variability, and also the individual effects of supportive skeletal tissues. Based on what has been said above, it is obvious that there is a need to exercise restraint in interpreting the obtained results. Key words: cervical spine, kinematics, numerical modelling, finite element method, canine.

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来源期刊
CiteScore
0.70
自引率
25.00%
发文量
53
期刊介绍: Editorial Board accepts for publication articles, reports from congresses, fellowships, book reviews, reports concerning activities of orthopaedic and other relating specialised societies, reports on anniversaries of outstanding personalities in orthopaedics and announcements of congresses and symposia being prepared. Articles include original papers, case reports and current concepts reviews and recently also instructional lectures.
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