Affiliations: New Jersey Institute of Technology, Newark, NJ, USA
Correspondence:
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Corresponding author: A.K. Sengupta, New Jersey Institute of Technology, Newark, NJ, USA. Tel.: +1 973 642 7073; Fax: +1 973 642 4184; E-mail:sengupta@njit.edu
Abstract: BACKGROUND: Asymmetric and dynamic lifting is known to be one of
the leading causes of occupational lower back disorders (LBDs).
Biomechanical modeling has been utilized to investigate lifting task
characteristics so that the task demands can be kept within a limit, and
internal muscles and joints are not injured. OBJECTIVE: This study implemented AnyBodyTM to analyze
internal torso loading in asymmetric and dynamic lifting tasks. METHODS: A six-camera motion capture (mocap) system collected
dynamic motion data of lifting 30 lb (13.6 kg) weight at 0°, 30°
and 60° asymmetry. The mocap data drove the AnyBodyTM model, and
the study investigated the effect of the asymmetry. RESULTS: Erector spinae was the most activated muscle for both
symmetric and asymmetric lifting. When lifting origin became more asymmetric
toward right, erector spinae activity was reduced, but oblique muscles
increased their share of activity to counter the external moment. Most
muscle tensions peaked at the lift initiation phase except left external
oblique and right internal oblique. Left external oblique played a minor
role in the right asymmetric lifting task, and the difference of activation
for right internal oblique may be due to variance of the motion.
Surprisingly the lift asymmetry decreased both compression and shear forces
at the L5/S1 joint. CONCLUSIONS: This finding contradicted the results obtained from
other research studies. The reduction in spine forces is postulated to have
resulted from the increased oblique muscles' share in the production of back
extensor moment. Since these muscles have longer moment arms, they generated
lesser spine force to counteract the external moment. The subject also
tended to squat as lifting origin became asymmetric, which effectively
reduced the load moment on the spine.