Improved artificial neural networks for 3D body posture and lumbosacral moment predictions during manual material handling activities

Body posture measurement approaches, required in biomechanical models to assess risk of musculoskeletal injuries, are usually costly and/or impractical for use in real workplaces. Therefore, we recently developed three artificial neural networks (ANNs), based on measured posture data on several individuals, to predict whole body 3D posture (coordinates of 15 markers located on body's main joints), segmental orientations (Euler angles of 14 body segments), and lumbosacral (L5-S1) moments during static manual material handling (MMH) activities (ANN(Posture), ANN(Angle), and ANN(Moment), respectively). These ANNs require worker's body height, body weight (only for ANN(Moment)), hand-load 3D position, and its mass as inputs to accurately predict 3D marker coordinates (RMSE = 7.0 cm), segmental orientations (RMSE = 29.9 degrees) and L5-S1 moments (RMSE = 16.5 N.m) for various static MMH activities. The current work aims to further improve the accuracy of these ANNs by performing outlier elimination and data normalization (as effective tools to improve the accuracy of ANNs) as well as by introducing participant's knee flexion angle (i.e., lifting technique: stoop, semi-squat, and full-squat) and body weight as new inputs into these ANNs. Results indicate that the RMSE of the new ANN(Posture), ANN(Angle), and ANN(Moment) reduced by, respectively, similar to 43%, 10%, and 29% (from 7.0 cm, 29.9 degrees, and 16.5 Nm in the original ANNs to, respectively, 4.0 cm, 27.0 degrees, and 11.8 Nm). Such significant improvements in the predictive power of our ANNs further confirm their effectiveness as alternative posture-prediction approaches requiring minimal in vivo data collection in real workplaces.

Automated summary

This study improved the accuracy of artificial neural networks in predicting body posture by introducing new input data and enhancing the algorithm, effectively predicting joint loads during static manual material handling activities.