Dynamically and statically determined low back moments during lifting

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McGill, Stuart M.¹; Norman, Robert W.¹

Dynamically and statically determined low back moments during lifting

J Biomech. 1985;18(12):877-885

©1985 Pergamon Press Ltd.

Affiliations

¹Biomechanics Laboratories, Department of Kinesiology, University of Waterloo, Waterloo, Ontario, Canada, N2L 3G 1
Abstract

Assessment of the effects of lifting on the low back has most frequently been done with the aid of static models. Many lifting movements appear to have substantial inertial components. It was of interest, therefore, to determine the size of the difference between statically and dynamically calculated lumbar moments during a demanding but not unusual manual lift observed in a metal fabrication industry.

The results of several trials by four young men showed that the dynamic model resulted in peak L4/L5 moments 19% higher on average, with a maximum difference of 52%, than those determined from the static model. The technique adopted in the lift could minimize the difference. When the inertial forces of the load itself and the load weight were incorporated into an otherwise static model (quasi-dynamic) then the resulting L4/L5 moments exceeded those of the fully dynamic model by 25%.

In many industrial tasks static analyses may severely underestimate the demands of dynamic lifts. These results show that a reasonably inexpensive approach in lifting task analysis is to measure the dynamic forces of the load on the hands and to use these in an otherwise static model. This results in a conservative assessment of the injury risk of lifts at least of the type reported in this study.
Links

DOI: 10.1016/0021-9290(85)90032-6

PubMed: 4077856

WoS: A1985AWZ5600002
History

Received: 1984-10-11

Revised: 1985-04-17

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Cited By (28)

Year	Entry
1996	Cholewicki J, McGill SM. Mechanical stability of the in vivo lumbar spine: implications for injury and chronic low back pain. Clin Biomech (Bristol, Avon). January 1996;11(1):1-15.
1998	Norman R, Wells R, Neumann P, Frank J, Shannon H, Kerr M; Ontario Universities Back Pain Study (OUBPS) Group. A comparison of peak vs cumulative physical work exposure risk factors for the reporting of low back pain in the automotive industry. Clin Biomech (Bristol, Avon). December 1998;13(8):561-573.
1993	Waters TR, Putz-Anderson V, Garg A, Fine LJ. Revised NIOSH equation for the design and evaluation of manual lifting tasks. Ergonomics. July 1993;36(7):749-776.
1987	McGill SM, Norman RW. Effects of an anatomically detailed erector spinae model on L4/L5 disc compression and shear. J Biomech. 1987;20(6):591-600.
1992	McGill SM. A myoelectrically based dynamic three-dimensional model to predict loads on lumbar spine tissues during lateral bending. J Biomech. April 1992;25(4):395-414.
1995	Cholewicki J, McGill SM, Norman RW. Comparison of muscle forces and joint load from an optimization and EMG assisted lumbar spine model: towards development of a hybrid approach. J Biomech. March 1995;28(3):321-331.
2006	Bouxsein ML, Melton LJ III, Riggs BL, Muller J, Atkinson EJ, Oberg AL, Robb RA, Camp JJ, Rouleau PA, McCollough CH, Khosla S. Age‐ and sex‐specific differences in the factor of risk for vertebral fracture: a population‐based study using QCT. J Bone Miner Res. September 2006;21(9):1475-1482.
2021	Mokhtarzadeh H, Anderson DE, Allaire BT, Bouxsein ML. Patterns of load‐to‐strength ratios along the spine in a population‐based cohort to evaluate the contribution of spinal loading to vertebral fractures. J Bone Miner Res. April 2021;36(4):704-711.
1986	McGill SM, Norman RW. Partitioning of the L4-L5 dynamic moment into disc, ligamentous, and muscular components during lifting. Spine. September 1986;11(7):666-678.
2019	Beaucage-Gauvreau E. Brace for it: Assessing Lumbar Spinal Loads for a Braced Arm-to-Thigh Lifting and Bending Technique Using a Musculoskeletal Modelling Approach [PhD thesis]. University of Adelaide; June 2019.
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1998	Eger TR. Load Transfer Hand Forces During a Two-Dimensional Sagittal Plane Box Lift [Master's thesis]. Queen's University; September 1998.
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2006	Abdoli-Eramaki M. Design and Instrumentation of a Mechanical Personal Lift Augmentation Device (PLAD) for Manual Lifting Tasks [PhD thesis]. Queen's University; January 2006.
2009	Godwin AA. Investigating the Feasibility of New Methods for Analysis and Collection of Human Motion in Field Applications [PhD thesis]. Queen's University; April 2009.
1992	Bouxsein ML. Physical Activity and Bone Density [PhD thesis]. Stanford University; August 1992.
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1993	Cholewicki J. Mechanical Stability of the in Vivo Lumbar Spine [PhD thesis]. University of Waterloo; 1993.
1999	Callaghan JP. Low-Magnitude Loading of the Spine: In Vivo and in Vitro Studies [PhD thesis]. University of Waterloo; 1999.
2002	Grenier SG. Stabilization Strategies of the Lumbar Spine in Vivo [PhD thesis]. University of Waterloo; 2002.
2007	Scannell JP. In Vitro and in Vivo Biomechanical Investigation of the Clinical Practice of Disc Prolapse Prevention and Rehabilitation [PhD thesis]. University of Waterloo; 2007.
2008	Parkinson RJ. Refining the Relationship Between the Mechanical Demands on the Spine and Injury Mechanisms Through Improved Estimates of Load Exposure and Tissue Tolerance [PhD thesis]. University of Waterloo; 2008.
2011	Ikeda DM. Quantification of Spine Stability: Assessing the Role of Muscles and Their Links to Eigenvalues and Stability [Master's thesis]. University of Waterloo; 2011.
1996	Choi H. Muscle Forces and Spinal Loads in the Human Neck: An EMG Experiment and a Comparison of Three Modeling Methods [PhD thesis]. University of Wisconsin – Madison; 1996.
2007	Reeves NP. Tuning-Out Instability: The Importance of Feedback Control in the Spine [PhD thesis]. Yale University; December 2007.