Biomechanical effects of medial meniscus radial tears on the knee joint during gait: A concurrent finite element musculoskeletal framework investigation

Sentong Wang; Kazunori Hase; Shunsuke Kita; Shinya Ogaya

doi:10.3389/fbioe.2022.957435

Biomechanical effects of medial meniscus radial tears on the knee joint during gait: A concurrent finite element musculoskeletal framework investigation

Front Bioeng Biotechnol. 2022 Oct 10:10:957435. doi: 10.3389/fbioe.2022.957435. eCollection 2022.

Authors

Sentong Wang¹, Kazunori Hase², Shunsuke Kita^{3

4}, Shinya Ogaya⁵

Affiliations

¹ Human-Mechanical System Laboratory, Graduate School of Systems Design, Tokyo Metropolitan University, Hachioji, Japan.
² Human-Mechanical System Laboratory, Faculty of Systems Design, Tokyo Metropolitan University, Hachioji, Japan.
³ Biomechanics of Exercise and Sports in Physical Therapy Laboratory, Graduate Course of Health and Social Services, Saitama Prefectural University, Koshigaya, Japan.
⁴ Department of Rehabilitation, Soka Orthopedics Internal Medicine, Saitama, Japan.
⁵ Biomechanics of Exercise and Sports in Physical Therapy Laboratory, Department of Physical Therapy, Saitama Prefectural University, Koshigaya, Japan.

Abstract

The biomechanical variation in the knee during walking that accompanies medial meniscal radial tears stemming from knee osteoarthritis (OA) has not been explored. This study introduced a finite element musculoskeletal model using concurrent lower limb musculoskeletal dynamics and knee joint finite element analysis in a single framework and expanded the models to include knees with medial meniscal radial tears and total medial meniscectomy. The radial tears involved three locations: anterior horn, midbody, and posterior horn with grades of 33%, 50%, and 83% of the meniscus width. The shear and hoop stresses of the tear meniscus and tibial cartilage contact load, accompanying tears, and postmeniscectomy were evaluated during the stance phase of the gait cycle using the models. In the 83% width midbody tear group, shear stress at the end of the tear was significantly greater than in the intact meniscus and other tear groups, and the maximum shear stress was increased by 310% compared to the intact meniscus. A medial meniscus radial tear has a much smaller effect on the tibial cartilage load (even though in the 83% width tear, the cartilage/total load ratio increased by only 9%). However, the contact force on the tibial cartilage with total postmeniscectomy was increased by 178.93% compared with a healthy intact meniscus, and the peak contact pressure after meniscectomy increased from 11.94 to 12.45 MPa to 17.64 and 13.76 MPa, at the maximum weight acceptance and push-off, respectively. Our study shows that radial tears with larger medial meniscus widths are prone to high stress concentrations at the end of the tears, leading to the potential risk of complete meniscal rupture. Furthermore, although the tears did not change the cartilage load distribution, they disrupted the circumferential stress-transmitting function of the meniscus, thus greatly increasing the likelihood of the onset of knee OA. The significant increase in the tibial cartilage load with total postmeniscectomy indicates a potential risk of OA flare-ups. This study contributes to a better understanding of meniscal tear-induced OA biomechanical changes during human activities and offers some potential directions for surgical guidance of meniscectomies and the prophylaxis and treatment of OA.

Keywords: finite element; gait; knee; meniscus tear; musculoskeletal model; osteoarthritis.