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. 2023 Dec 1;145(12):121008.
doi: 10.1115/1.4063627.

Deciphering the "Art" in Modeling and Simulation of the Knee Joint: Assessing Model Calibration Workflows and Outcomes

Thor E Andreassen  1 Peter J Laz  1 Ahmet Erdemir  2 Thor F Besier  3 Jason P Halloran  4 Carl W Imhauser  5 Snehal Chokhandre  2 Ariel Schwartz  2 Neda Abdollahi Nohouji  2 Nynke B Rooks  3 Marco T Y Schneider  3 Shady Elmasry  5 William Zaylor  6 Donald R Hume  1 Kevin B Shelburne  1
Affiliations

Deciphering the "Art" in Modeling and Simulation of the Knee Joint: Assessing Model Calibration Workflows and Outcomes

Thor E Andreassen et al. J Biomech Eng. .

Abstract

Model reproducibility is a point of emphasis for the National Institutes of Health (NIH) and in science, broadly. As the use of computational modeling in biomechanics and orthopedics grows, so does the need to assess the reproducibility of modeling workflows and simulation predictions. The long-term goal of the KneeHub project is to understand the influence of potentially subjective decisions, thus the modeler's "art", on the reproducibility and predictive uncertainty of computational knee joint models. In this paper, we report on the model calibration phase of this project, during which five teams calibrated computational knee joint models of the same specimens from the same specimen-specific joint mechanics dataset. We investigated model calibration approaches and decisions, and compared calibration workflows and model outcomes among the teams. The selection of the calibration targets used in the calibration workflow differed greatly between the teams and was influenced by modeling decisions related to the representation of structures, and considerations for computational cost and implementation of optimization. While calibration improved model performance, differences in the postcalibration ligament properties and predicted kinematics were quantified and discussed in the context of modeling decisions. Even for teams with demonstrated expertise, model calibration is difficult to foresee and plan in detail, and the results of this study underscore the importance of identification and standardization of best practices for data sharing and calibration.

Keywords: computational modeling; finite element analysis; joint mechanics; knee biomechanics; ligament; reproducibility; tissue mechanics.

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Figures

Phases of the KneeHub project. Adapted from Rooks et al. [6]. DATA A refers to Natural Knee specimen DU02 and DATA B refers to Open Knee(s) specimen OKS003.
Fig. 1
Phases of the KneeHub project. Adapted from Rooks et al. [6]. DATA A refers to Natural Knee specimen DU02 and DATA B refers to Open Knee(s) specimen OKS003.
Models built by each team at the conclusion of the model development phase of the KneeHub project. Adapted from Rooks et al. [6].
Fig. 2
Models built by each team at the conclusion of the model development phase of the KneeHub project. Adapted from Rooks et al. [6].
Calibration targets derived from experimental knee laxity data and selected by each team for model calibration
Fig. 3
Calibration targets derived from experimental knee laxity data and selected by each team for model calibration
Calibrated reference strains for primary knee ligaments. Graphs represent mean reference strain, with error bars representing the maximum and minimum reference strains for teams using multiple fiber bundles for the same ligament. Values of the reference strain of less than 1 correspond to initially slack, and greater than 1 represent initially taught.
Fig. 4
Calibrated reference strains for primary knee ligaments. Graphs represent mean reference strain, with error bars representing the maximum and minimum reference strains for teams using multiple fiber bundles for the same ligament. Values of the reference strain of less than 1 correspond to initially slack, and greater than 1 represent initially taught.
Passive flexion kinematics as a function of knee flexion angle. The black line represents the original experimental kinematics, solid lines show the predicted kinematics after calibration, and dashed lines represent predicted kinematics from the end of the model development phase from Rooks et al. [6]. Kinematics from each team have been converted to a consistent coordinate system matching the experimental data for the given model.
Fig. 5
Passive flexion kinematics as a function of knee flexion angle. The black line represents the original experimental kinematics, solid lines show the predicted kinematics after calibration, and dashed lines represent predicted kinematics from the end of the model development phase from Rooks et al. [6]. Kinematics from each team have been converted to a consistent coordinate system matching the experimental data for the given model.
See this image and copyright information in PMC

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