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In the first study, we investigated the impact of femoral geometry, i.e. different neck-shaft angle and anteversion angle, on hip joint contact forces and femoral growth prediction. We uploaded following material:- motion capture data- used OpenSim model- finite element model of the femur- results from the musculoskeletal and femoral growth simulationsThis project and HK was funded by a H2020-MSCA individual fellowship (796120).More details can be found in our publication (please also cite this paper when re-using the data):Kainz H., Killen B.A., Wesseling M., Perez-Boerema F., Pitto L., Garcia Aznar J.M., Shefelbine S., Jonkers I. (2020) A multi-scale modelling framework combining musculoskeletal rigid-body simulations with adaptive finite element analyses, to evaluate the impact of femoral geometry on hip joint contact forces and femoral bone growth. PLoS ONE 15(7): e0235966.https://doi.org/10.1371/journal.pone.0235966In the second study, we investigated reasons for pathological and typical growth in children with cerebral palsy. The paper was published as the ESB Award Paper in the Journal of Clinical Biomechanics.https://doi.org/10.1016/j.clinbiomech.2021.105405 <br/><br/>This project includes the following software/data packages: <br/> <ul> <li> <a href="https://simtk.org/frs?group_id=1865#pack_2194">MSc project_Elien_Sien </a> : The Impact of Subject-Specific Bone Geometry on Femoral Bone Growth Simulations in Children with Cerebral Palsy: Sensitivity Analysis of an Adaptive, Multi-Scale, Image-Based WorkflowThe download package includes the thesis, short paper, Matlab code and results from the MSc thesis project from Elien Vlaeyen and Sien Vingerhoets, who were supervised by Hans Kainz and Ilse Jonkers. </li> <li> <a href="https://simtk.org/frs?group_id=1865#pack_2171">Paper1_InputAndResults </a> : This package includes the (i) motion capture data of our participant, (ii) musculoskeletal models, (iii) finite element model of the femur, and (iv) results from the musculoskeletal and bone growth simulations from our first study (Impact of femoral geometry on hip joint contact forces and femoral growth simulations). </li> </ul>

在首项研究中，我们探讨了股骨几何形状，即不同的颈干角和前倾角，对髋关节接触力和股骨生长预测的影响。我们上传了以下材料：运动捕捉数据、OpenSim模型、股骨有限元模型以及肌肉骨骼和股骨生长模拟的结果。本项目及香港中文大学的研究资金来源于H2020-MSCA个人奖学金（796120）。更多详情可参见我们的出版物（在使用数据时，请亦引用此论文）：Kainz H., Killen B.A., Wesseling M., Perez-Boerema F., Pitto L., Garcia Aznar J.M., Shefelbine S., Jonkers I. (2020) 结合肌肉骨骼刚体模拟与自适应有限元分析的跨尺度建模框架，以评估股骨几何形状对髋关节接触力和股骨骨生长的影响。PLoS ONE 15(7): e0235966. https://doi.org/10.1371/journal.pone.0235966。在第二项研究中，我们探讨了脑瘫儿童病理性及典型生长的原因。该论文作为ESB奖论文发表在《临床生物力学杂志》上。https://doi.org/10.1016/j.clinbiomech.2021.105405。本项目包括以下软件/数据包：<ul><li>《MSc project_Elien_Sien》：该下载包包含Elien Vlaeyen和Sien Vingerhoets的硕士论文、简短论文、Matlab代码以及由Hans Kainz和Ilse Jonkers指导的硕士论文项目结果。</li><li>《Paper1_InputAndResults》：本包包括（i）参与者的运动捕捉数据、（ii）肌肉骨骼模型、（iii）股骨有限元模型以及（iv）来自首项研究（股骨几何形状对髋关节接触力和股骨生长模拟的影响）的肌肉骨骼和骨生长模拟结果。</li></ul>