Estimating Compressive and Shear Forces at L5-S1: Exploring the Effects of Load Weight, Asymmetry, and Height Using Optical and Inertial Motion Capture Systems

Nail-Ulloa, Iván; Zabala, Michael; Sesek, Richard; Chen, Howard; Schall, Mark C.; Gallagher, Sean

doi:10.3390/s24061941

Sensors

2024

DOI: 10.3390/s24061941

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Estimating Compressive and Shear Forces at L5-S1: Exploring the Effects of Load Weight, Asymmetry, and Height Using Optical and Inertial Motion Capture Systems

Iván Nail-Ulloa,

Michael Zabala,

Richard Sesek

et al.

Abstract: This study assesses the agreement of compressive and shear force estimates at the L5-S1 joint using inertial motion capture (IMC) within a musculoskeletal simulation model during manual lifting tasks, compared against a top-down optical motion capture (OMC)-based model. Thirty-six participants completed lifting and lowering tasks while wearing a modified Plug-in Gait marker set for the OMC and a full-body IMC set-up consisting of 17 sensors. The study focused on tasks with variable load weights, lifting height… Show more

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Cited by 3 publications

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Predicting Human Postures for Manual Material Handling Tasks Using a Conditional Diffusion Model

Qing,

Su,

Jung

et al. 2024

IEEE Trans. Human-Mach. Syst.

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Predicting Human Postures for Manual Material Handling Tasks Using a Conditional Diffusion Model

Qing,

Su,

Jung

et al. 2024

IEEE Trans. Human-Mach. Syst.

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Estimation of Joint Kinetics During Manual Material Handling Using Inertial Motion Capture: A Follow-Up Study

Skals,

de Zee,

Skipper Andersen

2024

Journal of Biomechanical Engineering

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Musculoskeletal models based on inertial motion capture and ground reaction force (GRF) prediction hold great potential for field-based risk assessment of manual material handling. However, previous evaluations have identified inaccuracies in the methodology?s estimation of spinal forces, while the accuracy of other key outcome variables is currently unclear. This study evaluated knee, shoulder, and L5-S1 joint reaction forces (JRFs) derived from a musculoskeletal model based on inertial motion capture and GRF prediction against a model based on simultaneously collected optical motion capture and force plate measurements. Data from 19 healthy subjects performing lifts with various horizontal locations, deposit heights and asymmetry angles were analyzed, and the consistency and absolute agreement of the model estimates statistically compared. Despite varying levels of agreement across tasks and variables, considerable absolute differences were identified for the L5-S1 axial compression (RMSE = 63.0-94.2%BW) and anteroposterior shear forces (RMSE = 40.9-80.6%BW) as well as the bilateral knee JRFs (RMSE = 78.9-117%BW). Glenohumeral JRFs and vertical GRFs exhibited the highest overall consistency (r = 0.33-0.91, median 0.78) and absolute agreement (RMSE = 7.63-34.9%BW), while the L5-S1 axial compression forces also showed decent consistency (r = 0.04-0.89, median 0.80). The findings generally align with prior evaluations, indicating persistent challenges with the accuracy of key outcome variables. While the modelling framework shows promise, further development of the methodology is encouraged to enhance its applicability in ergonomic evaluations.

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A Battery-Powered Tool to Move Utility Manhole Covers: Field Data and Proof of Concept

Marklin,

Schabelski,

Gallagher

et al. 2024

Ergonomics in Design: The Quarterly of Human Factors Applicatio

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A new tool was designed and fabricated for workers to remove and replace electric utility manhole and vault covers. This tool, which is portable and weighs 7.26 kg (16 lb.), employs a battery-powered electric motor to raise and lower the cover, reducing the manual force. The design was based on field observations and biomechanical measurements of utility workers who moved manhole covers. Biomechanical data from the pilot study reveal the tool’s potential to reduce risk of a back injury. Field observations and data demonstrate the proof of concept, and the design will be further developed.

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Estimating Compressive and Shear Forces at L5-S1: Exploring the Effects of Load Weight, Asymmetry, and Height Using Optical and Inertial Motion Capture Systems

Cited by 3 publications

References 55 publications

Predicting Human Postures for Manual Material Handling Tasks Using a Conditional Diffusion Model

Predicting Human Postures for Manual Material Handling Tasks Using a Conditional Diffusion Model

Estimation of Joint Kinetics During Manual Material Handling Using Inertial Motion Capture: A Follow-Up Study

A Battery-Powered Tool to Move Utility Manhole Covers: Field Data and Proof of Concept

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