Functional and Applied Biomechanics Section/Rehabilitation Medicine Department, National Institutes of Health, Bethesda, MD, USA.
Functional and Applied Biomechanics Section/Rehabilitation Medicine Department, National Institutes of Health, Bethesda, MD, USA.
Osteoarthritis Cartilage. 2013 Dec;21(12):1886-1894. doi: 10.1016/j.joca.2013.08.023. Epub 2013 Sep 3.
To establish an in vivo, normative patellofemoral (PF) cartilage contact mechanics database acquired during voluntary muscle control using a novel, dynamic, magnetic resonance (MR) imaging-based, computational methodology and validate the contact mechanics sensitivity to the known sub-millimeter methodological accuracies.
Dynamic cine phase-contrast and multi-plane cine (MPC) images were acquired while female subjects (n = 20, sample of convenience) performed an open kinetic chain (knee flexion-extension) exercise inside a 3-T MR scanner. Static cartilage models were created from high resolution three-dimensional static MR data and accurately placed in their dynamic pose at each time frame based on the cine-PC (CPC) data. Cartilage contact parameters were calculated based on the surface overlap. Statistical analysis was performed using paired t-test and a one-sample repeated measures ANOVA. The sensitivity of the contact parameters to the known errors in the PF kinematics was determined.
Peak mean PF contact area was 228.7 ± 173.6 mm(2) at 40° knee angle. During extension, contact centroid and peak strain locations tracked medially on the femoral and patellar cartilage and were not significantly different from each other. At 25°, 30°, 35°, and 40° of knee extension, contact area was significantly different. Contact area and centroid locations were insensitive to rotational and translational perturbations.
This study is a first step towards unfolding the biomechanical pathways to anterior PF pain and osteoarthritis (OA) using dynamic, in vivo, and accurate methodologies. The database provides crucial data for future studies and for validation of, or as an input to, computational models.
利用一种新颖的、基于动态磁共振成像的计算方法,在自愿肌肉控制下建立体内正常髌股(PF)软骨接触力学数据库,并验证接触力学对已知亚毫米方法学精度的敏感性。
在 3T 磁共振扫描仪中,女性受试者(n=20,方便样本)进行开链动力学(膝关节屈伸)运动时,采集动态电影相位对比和多平面电影(MPC)图像。从高分辨率三维静态磁共振数据创建静态软骨模型,并根据电影 PC(CPC)数据在每个时间帧上准确放置在其动态姿势中。基于表面重叠计算软骨接触参数。使用配对 t 检验和单样本重复测量方差分析进行统计分析。确定接触参数对 PF 运动学中已知误差的敏感性。
在 40°膝关节角度时,峰值平均 PF 接触面积为 228.7±173.6mm²。在伸展过程中,接触质心和峰值应变位置在股骨和髌骨软骨上向内侧跟踪,彼此之间没有显著差异。在膝关节伸展 25°、30°、35°和 40°时,接触面积有显著差异。接触面积和质心位置对旋转和平移扰动不敏感。
本研究是利用动态、体内和精确方法揭示前 PF 疼痛和骨关节炎(OA)生物力学途径的第一步。该数据库为未来的研究提供了关键数据,并为计算模型的验证或作为输入提供了关键数据。