Navid Arjmand scite author profile

Despite the well-recognized role of lifting in back injuries, the relative biomechanical merits of squat versus stoop lifting remain controversial. In vivo kinematics measurements and model studies are combined to estimate trunk muscle forces and internal spinal loads under dynamic squat and stoop lifts with and without load in hands. Measurements were performed on healthy subjects to collect segmental rotations during lifts needed as input data in subsequent model studies. The model accounted for nonlinear properties of the ligamentous spine, wrapping of thoracic extensor muscles to take curved paths in flexion and trunk dynamic characteristics (inertia and damping) while subject to measured kinematics and gravity/ external loads. A dynamic kinematics-driven approach was employed accounting for the spinal synergy by simultaneous consideration of passive structures and muscle forces under given posture and loads. Results satisfied kinematics and dynamic equilibrium conditions at all levels and directions. Net moments, muscle forces at different levels, passive (muscle or ligamentous) forces and internal compression/shear forces were larger in stoop lifts than in squat ones. These were due to significantly larger thorax, lumbar and pelvis rotations in stoop lifts. For the relatively slow lifting tasks performed in this study with the lowering and lifting phases each lasting~2 s, the effect of inertia and damping was not, in general, important. Moreover, posterior shift in the position of the external load in stoop lift reaching the same lever arm with respect to the S1 as that in squat lift did not influence the conclusion of this study on the merits of squat lifts over stoop ones. Results, for the tasks considered, advocate squat lifting over stoop lifting as the technique of choice in reducing net moments, muscle forces and internal spinal loads (i.e., moment, compression and shear force).

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Model and in vivo studies on human trunk load partitioning and stability in isometric forward flexions

Arjmand

Shirazi‐Adl

2006

Journal of Biomechanics

162

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Comparison of trunk muscle forces and spinal loads estimated by two biomechanical models

Arjmand

Gagnon

Plamondon

et al. 2009

Clinical Biomechanics

117

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Biomechanics of Changes in Lumbar Posture in Static Lifting

Arjmand

Shirazi‐Adl

2005

Spine

141

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Alterations in the lumbar lordosis in lifting resulted in significant changes in the muscle forces and internal spinal loads. Spinal shear forces at different segmental levels were influenced by changes in both the disc inclinations and extensor muscle lines of action as the posture altered. Considering internal spinal loads and active-passive muscle forces, the current study supports the freestyle posture or a posture with moderate flexion as the posture of choice in static lifting tasks.

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Navid Arjmand

Estimation of loads on human lumbar spine: A review of in vivo and computational model studies

Analysis of squat and stoop dynamic liftings: muscle forces and internal spinal loads

Model and in vivo studies on human trunk load partitioning and stability in isometric forward flexions

Comparison of trunk muscle forces and spinal loads estimated by two biomechanical models

Biomechanics of Changes in Lumbar Posture in Static Lifting

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