Development of a Full Flexion 3D Musculoskeletal Model of the Knee Considering Intersegmental Contact During High Knee Flexion Movements

in Journal of Applied Biomechanics

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David C. KingstonUniversity of Saskatchewan
University of Waterloo

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Stacey M. AckerUniversity of Waterloo

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DOI:
https://doi.org/10.1123/jab.2019-0335
Keywords:
kneeling; squatting; shear; compression
First Published Online:
26 Aug 2020
In Print:
Volume 36: Issue 6
Page Range:
444–456
Restricted access

A musculoskeletal model of the right lower limb was developed to estimate 3D tibial contact forces in high knee flexion postures. This model determined the effect of intersegmental contact between thigh–calf and heel–gluteal structures on tibial contact forces. This model includes direct tracking and 3D orientation of intersegmental contact force, femoral translations from in vivo studies, wrapping of knee extensor musculature, and a novel optimization constraint for multielement muscle groups. Model verification consisted of calculating the error between estimated tibial compressive forces and direct measurements from the Grand Knee Challenge during movements to ∼120° of knee flexion as no high knee flexion data are available. Tibial compression estimates strongly fit implant data during walking (R2 = .83) and squatting (R2 = .93) with a root mean squared difference of .47 and .16 body weight, respectively. Incorporating intersegmental contact significantly reduced model estimates of peak tibial anterior–posterior shear and increased peak medial–lateral shear during the static phase of high knee flexion movements by an average of .33 and .07 body weight, respectively. This model supports prior work in that intersegmental contact is a critical parameter when estimating tibial contact forces in high knee flexion movements across a range of culturally and occupationally relevant postures.

Kingston is with the Canadian Centre for Health and Safety in Agriculture, University of Saskatchewan, Saskatoon, SK, Canada. Kingston and Acker are with the Department of Kinesiology, University of Waterloo, Waterloo, ON, Canada.

Acker (stacey.acker@uwaterloo.ca) is corresponding author.
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