Spinal Modelling to Investigate Postural Loading and Stability

Numerous mathematical models have been developed to investigate the high incidence of low back pain associated with lifting activities. These mainly consider the muscle forces required to support the spine, and few have considered the additional role of curvature.

One previous model which represented the spine as an arch (Aspden 1987) indicated the curvature to have a significant effect on both loading and stability of the spine. However this model included collective loading patterns for body weight and muscle forces, and only partial representation of the spine. On the basis that the level of anatomic detail of a model affects the accuracy of its predictions (McGill and Norman, 1987), this thesis describes the development of a model which provides greater detail for investigating spinal stability in the sagittal plane.

The curvature of the whole spine, a distributed loading pattern for body weight, and the activity of individual spinal muscle groups have been considered. Comparison with the previous arch model has shown these to be necessary features for determining the loading and stability associated with a given posture. In particular, application of individual muscle forces provide greater control of stability at each vertebral level. By considering the force requirements of the individual muscle groups and the consequent loads at each intervertebral joint, possible areas of tissue over load can be identified.

Year	Entry
1993	Kleinberger M. Application of finite element techniques to the study of cervical spine mechanics. In: Proceedings of the 37th Stapp Car Crash Conference. November 7-8, 1993; San Antonio, TX. Warrendale, PA: Society of Automotive Engineers:261-272. SAE 933131.
1992	Mizrahi J, Silva MJ, Hayes WC. Finite element stress analysis of simulated metastatic lesions in the lumbar vertebral body. J Biomed Eng. November 1992;14(6):467-475.
1993	Mizrahi J, Silva MJ, Keaveny TM, Edwards WT, Hayes WC. Finite-element stress analysis of the normal and osteoporotic lumbar vertebral body. Spine. October 15, 1993;18(14):2088-2096.
1985	Chazal J, Tanguy A, Bourges M, Gaurel G, Escande G, Guillot M, Vanneuville G. Biomechanical properties of spinal ligaments and a histological study of the supraspinal ligament in traction. J Biomech. 1985;18(3):167-176.
1988	McGill SM, Patt N, Norman RW. Measurement of the trunk musculature of active males using CT scan radiography: implications for force and moment generating capacity about the L4/L5 joint. J Biomech. 1988;21(4):329-341.
1979	Hakim NS, King AI. A three dimensional finite element dynamic response analysis of a vertebra with experimental verification. J Biomech. 1979;12(4):277-292.
1982	Schultz A, Andersson G, Örtengren R, Haderspeck K, Nachemson A. Loads on the lumbar spine: validation of a biomechanical analysis by measurements of intradiscal pressures and myoelectric signals. J Bone Joint Surg. June 1982;64A(5):713-720.
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Year

Entry

1993

Kleinberger M. Application of finite element techniques to the study of cervical spine mechanics. In: Proceedings of the 37th Stapp Car Crash Conference. November 7-8, 1993; San Antonio, TX. Warrendale, PA: Society of Automotive Engineers:261-272. SAE 933131.

1992

Mizrahi J, Silva MJ, Hayes WC. Finite element stress analysis of simulated metastatic lesions in the lumbar vertebral body. J Biomed Eng. November 1992;14(6):467-475.

1993

Mizrahi J, Silva MJ, Keaveny TM, Edwards WT, Hayes WC. Finite-element stress analysis of the normal and osteoporotic lumbar vertebral body. Spine. October 15, 1993;18(14):2088-2096.

1985

Chazal J, Tanguy A, Bourges M, Gaurel G, Escande G, Guillot M, Vanneuville G. Biomechanical properties of spinal ligaments and a histological study of the supraspinal ligament in traction. J Biomech. 1985;18(3):167-176.

1988

McGill SM, Patt N, Norman RW. Measurement of the trunk musculature of active males using CT scan radiography: implications for force and moment generating capacity about the L4/L5 joint. J Biomech. 1988;21(4):329-341.