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Predicting net joint moments during a weightlifting exercise with a neural network model.
J Biomech. 2018 06 06; 74:225-229.JB

Abstract

The purpose of this study was to develop and train a Neural Network (NN) that uses barbell mass and motions to predict hip, knee, and ankle Net Joint Moments (NJM) during a weightlifting exercise. Seven weightlifters performed two cleans at 85% of their competition maximum while ground reaction forces and 3-D motion data were recorded. An inverse dynamics procedure was used to calculate hip, knee, and ankle NJM. Vertical and horizontal barbell motion data were extracted and, along with barbell mass, used as inputs to a NN. The NN was then trained to model the association between the mass and kinematics of the barbell and the calculated NJM for six weightlifters, the data from the remaining weightlifter was then used to test the performance of the NN - this was repeated 7 times with a k-fold cross-validation procedure to assess the NN accuracy. Joint-specific predictions of NJM produced coefficients of determination (r2) that ranged from 0.79 to 0.95, and the percent difference between NN-predicted and inverse dynamics calculated peak NJM ranged between 5% and 16%. The NN was thus able to predict the spatiotemporal patterns and discrete peaks of the three NJM with reasonable accuracy, which suggests that it is feasible to predict lower extremity NJM from the mass and kinematics of the barbell. Future work is needed to determine whether combining a NN model with low cost technology (e.g., digital video and free digitising software) can also be used to predict NJM of weightlifters during field-testing situations, such as practice and competition, with comparable accuracy.

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Publisher Full Text (DOI)

Authors+Show Affiliations

Kipp K
Department of Physical Therapy - Program in Exercise Science, Marquette University, Milwaukee, WI, USA. Electronic address: kristof.kipp@marquette.edu.
Giordanelli M
Department of Physical Therapy - Program in Exercise Science, Marquette University, Milwaukee, WI, USA.
Geiser C
Department of Physical Therapy - Program in Exercise Science, Marquette University, Milwaukee, WI, USA.

MeSH

Ankle JointBiomechanical PhenomenaHip JointHumansKnee JointNeural Networks, ComputerWeight Lifting

Pub Type(s)

Journal Article

Language

eng

PubMed ID

29706383

Citation

Kipp, Kristof, et al. "Predicting Net Joint Moments During a Weightlifting Exercise With a Neural Network Model." Journal of Biomechanics, vol. 74, 2018, pp. 225-229.
Kipp K, Giordanelli M, Geiser C. Predicting net joint moments during a weightlifting exercise with a neural network model. J Biomech. 2018;74:225-229.
Kipp, K., Giordanelli, M., & Geiser, C. (2018). Predicting net joint moments during a weightlifting exercise with a neural network model. Journal of Biomechanics, 74, 225-229. https://doi.org/10.1016/j.jbiomech.2018.04.021
Kipp K, Giordanelli M, Geiser C. Predicting Net Joint Moments During a Weightlifting Exercise With a Neural Network Model. J Biomech. 2018 06 6;74:225-229. PubMed PMID: 29706383.
* Article titles in AMA citation format should be in sentence-case
TY - JOUR T1 - Predicting net joint moments during a weightlifting exercise with a neural network model. AU - Kipp,Kristof, AU - Giordanelli,Matthew, AU - Geiser,Christopher, Y1 - 2018/04/25/ PY - 2017/12/07/received PY - 2018/03/19/revised PY - 2018/04/14/accepted PY - 2018/5/1/pubmed PY - 2019/4/9/medline PY - 2018/5/1/entrez KW - Biomechanics KW - Machine learning KW - Neural network KW - Sports SP - 225 EP - 229 JF - Journal of biomechanics JO - J Biomech VL - 74 N2 - The purpose of this study was to develop and train a Neural Network (NN) that uses barbell mass and motions to predict hip, knee, and ankle Net Joint Moments (NJM) during a weightlifting exercise. Seven weightlifters performed two cleans at 85% of their competition maximum while ground reaction forces and 3-D motion data were recorded. An inverse dynamics procedure was used to calculate hip, knee, and ankle NJM. Vertical and horizontal barbell motion data were extracted and, along with barbell mass, used as inputs to a NN. The NN was then trained to model the association between the mass and kinematics of the barbell and the calculated NJM for six weightlifters, the data from the remaining weightlifter was then used to test the performance of the NN - this was repeated 7 times with a k-fold cross-validation procedure to assess the NN accuracy. Joint-specific predictions of NJM produced coefficients of determination (r2) that ranged from 0.79 to 0.95, and the percent difference between NN-predicted and inverse dynamics calculated peak NJM ranged between 5% and 16%. The NN was thus able to predict the spatiotemporal patterns and discrete peaks of the three NJM with reasonable accuracy, which suggests that it is feasible to predict lower extremity NJM from the mass and kinematics of the barbell. Future work is needed to determine whether combining a NN model with low cost technology (e.g., digital video and free digitising software) can also be used to predict NJM of weightlifters during field-testing situations, such as practice and competition, with comparable accuracy. SN - 1873-2380 UR - https://www.unboundmedicine.com/medline/citation/29706383/Predicting_net_joint_moments_during_a_weightlifting_exercise_with_a_neural_network_model_ DB - PRIME DP - Unbound Medicine ER -