Predicting longitudinal changes in joint contact forces in a juvenile population: scaled generic versus subject-specific musculoskeletal models

Claude Fiifi Hayford; Erica Montefiori; Emma Pratt; Claudia Mazzà

doi:10.1080/10255842.2020.1783659

Predicting longitudinal changes in joint contact forces in a juvenile population: scaled generic versus subject-specific musculoskeletal models

Claude Fiifi Hayford, Erica Montefiori, Emma Pratt, Claudia Mazzà

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Subject-specific musculoskeletal model use in clinical settings is limited due to development-associated time and effort burdens together with potential medical imaging unavailability. As an alternative, this study investigated consistency in estimating longitudinal changes in joint contact forces (JCF) between scaled generic and subject-specific models. For 11 children, joint kinematics and JCF were calculated using subject-specific and scaled generic models. JCF changes estimated by both models were strongly correlated for the hip and knee although JCF estimates varied between models. Findings suggest that within specified limits of accuracy, scaled generic models are sensitive enough to detect JCF changes consistent with subject-specific models.

Original language	English
Pages (from-to)	1014-1025
Number of pages	12
Journal	Computer Methods in Biomechanics and Biomedical Engineering
DOIs	https://doi.org/10.1080/10255842.2020.1783659
Publication status	Published - 2020
Externally published	Yes

Keywords

Biomechanics
MRI
OpenSim
gait analysis
lower-limb
musculoskeletal modelling

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10.1080/10255842.2020.1783659

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title = "Predicting longitudinal changes in joint contact forces in a juvenile population: scaled generic versus subject-specific musculoskeletal models",

abstract = "Subject-specific musculoskeletal model use in clinical settings is limited due to development-associated time and effort burdens together with potential medical imaging unavailability. As an alternative, this study investigated consistency in estimating longitudinal changes in joint contact forces (JCF) between scaled generic and subject-specific models. For 11 children, joint kinematics and JCF were calculated using subject-specific and scaled generic models. JCF changes estimated by both models were strongly correlated for the hip and knee although JCF estimates varied between models. Findings suggest that within specified limits of accuracy, scaled generic models are sensitive enough to detect JCF changes consistent with subject-specific models.",

keywords = "Biomechanics, MRI, OpenSim, gait analysis, lower-limb, musculoskeletal modelling",

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doi = "10.1080/10255842.2020.1783659",

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AU - Montefiori, Erica

AU - Pratt, Emma

AU - Mazzà, Claudia

PY - 2020

Y1 - 2020

N2 - Subject-specific musculoskeletal model use in clinical settings is limited due to development-associated time and effort burdens together with potential medical imaging unavailability. As an alternative, this study investigated consistency in estimating longitudinal changes in joint contact forces (JCF) between scaled generic and subject-specific models. For 11 children, joint kinematics and JCF were calculated using subject-specific and scaled generic models. JCF changes estimated by both models were strongly correlated for the hip and knee although JCF estimates varied between models. Findings suggest that within specified limits of accuracy, scaled generic models are sensitive enough to detect JCF changes consistent with subject-specific models.

AB - Subject-specific musculoskeletal model use in clinical settings is limited due to development-associated time and effort burdens together with potential medical imaging unavailability. As an alternative, this study investigated consistency in estimating longitudinal changes in joint contact forces (JCF) between scaled generic and subject-specific models. For 11 children, joint kinematics and JCF were calculated using subject-specific and scaled generic models. JCF changes estimated by both models were strongly correlated for the hip and knee although JCF estimates varied between models. Findings suggest that within specified limits of accuracy, scaled generic models are sensitive enough to detect JCF changes consistent with subject-specific models.

KW - Biomechanics

KW - MRI

KW - OpenSim

KW - gait analysis

KW - lower-limb

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ER -

Predicting longitudinal changes in joint contact forces in a juvenile population: scaled generic versus subject-specific musculoskeletal models

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Keywords

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