Division of Applied Mechanics, Department of Mechanical Engineering, Polytechnique, Montréal, Québec, Canada.
Division of Applied Mechanics, Department of Mechanical Engineering, Polytechnique, Montréal, Québec, Canada.
Knee. 2021 Mar;29:530-540. doi: 10.1016/j.knee.2021.03.004. Epub 2021 Mar 21.
We aimed to quantify the sensitivity in biomechanical response and stability of the intact and anterior cruciate ligament deficient (ACL-D) joints at mid-to-late stance periods of gait to the alterations in activation of gastrocnemii (Gas) muscles.
A validated kinematics-driven musculoskeletal finite-element model of the lower extremity is used to compute knee joint response and stability under reported kinetics-kinematics of healthy subjects. Activation in Gas is altered under prescribed gait data at the mid-to-late stance of gait and associated changes in remaining muscle forces/contact forces/areas/ACL force and joint stability are computed in both intact and ACL-D joints.
In the intact joint, the anterior-tibial-translation (ATT) as well as ACL and joint contact forces follow variations in Gas forces. Both the stability and ATT of an ACL-D joint are restored to the near-intact levels when the activity in Gas is reduced. Knee joint instability, excessive ATT as well as larger peak articular contact stresses with a posterior shift in contact areas are estimated under greater Gas forces.
ACL-D joint is unstable with ATT > 10 mm under larger activities in Gas. Gas is an ACL-antagonist while hamstrings and soleus are ACL-agonists. The near-intact joint stability and ATT of an ACL-D joint can be restored at a lower activation in Gas; or in other words, when activation in ACL-antagonist muscles drops compared with that in ACL-agonist muscles. Results could help analyze the gait of ACL-D copers and non-copers and provide better understanding towards improved preventive, diagnostic, and treatment approaches.
我们旨在量化在步态的中晚期支撑期,完整和前交叉韧带缺失(ACL-D)关节对腓肠肌(Gas)肌肉激活变化的生物力学响应和稳定性的敏感性。
使用经过验证的运动学驱动的下肢运动生物力学有限元模型,根据健康受试者的报告动力学-运动学来计算膝关节的反应和稳定性。在步态的中晚期,根据规定的步态数据改变 Gas 的激活,计算完整和 ACL-D 关节中剩余肌肉力/接触力/面积/ACL 力和关节稳定性的变化。
在完整的关节中,前胫骨平移(ATT)以及 ACL 和关节接触力都遵循 Gas 力的变化。当 Gas 的活性降低时,ACL-D 关节的稳定性和 ATT 都恢复到接近完整的水平。当 Gas 力更大时,膝关节不稳定、ATT 过大以及关节接触应力峰值更大且向后移,接触面积增大。
在 Gas 活性较大的情况下,ACL-D 关节不稳定,ATT>10mm。Gas 是 ACL 的拮抗剂,而腘绳肌和比目鱼肌是 ACL 的激动剂。在 Gas 活性较低的情况下,ACL-D 关节的接近完整的关节稳定性和 ATT 可以恢复;换句话说,当 ACL 拮抗剂肌肉的活性相对于 ACL 激动剂肌肉的活性下降时。结果可以帮助分析 ACL-D 适应者和非适应者的步态,并提供对改进预防性、诊断性和治疗方法的更好理解。
