Mechanical properties of the cadaveric and Hybrid III lumbar spines

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Demetropoulos, Constantine K.¹; Yang, King H.¹; Grimm, Michele J.¹; Khalil, Tawfik B.¹; King, Albert I.¹

Mechanical properties of the cadaveric and Hybrid III lumbar spines

Proceedings of the 42nd Stapp Car Crash Conference

Affiliations

¹Wayne State Univ.
Abstract

This study identified the mechanical properties of ten cadaveric lumbar spines and two Hybrid III lumbar spines. Eight tests were performed on each specimen: tension, compression, anterior shear, posterior shear, left lateral shear, flexion, extension and left lateral bending. Each test was run at a displacement rate of 100 mm/sec. The maximum displacements were selected to approximate the loading range of a 50 km/h Hybrid III dummy sled test and to be non-destructive to the specimens. Load, linear displacement and angular displacement data were collected. Bending moment was calculated from force data.

Each mode of loading demonstrated consistent characteristics. The load-displacement curves of the Hybrid III lumbar spine demonstrated an initial region of high stiffness followed by a region of constant stiffness. The exception to this rule was the tension tests, as the steel cables that run the length of the spine appear to dominate the mechanical response of the Hybrid III spine in tensile loading. The loading curves of the cadaveric spines demonstrated an initial region of low stiffness followed by a region of increasing stiffness, as is typical of soft tissue response. Notable findings included the observation that the whole cadaveric lumbar spine specimens are stiffer in posterior shear than in anterior shear. This finding is in contrast to motion segment studies, in which the opposite trend is observed. This difference is believed to be due to the freedom of vertebrae L1 through L5 to rotate in the whole lumbar spine specimens. In functional spinal unit shear tests, both vertebrae are rigidly potted.
Links

DOI: 10.4271/983160

SAE: 983160

Cited Works (8)

Year	Entry
1957	Brown T, Hansen RJ, Yorra AJ. Some mechanical tests on the lumbosacral spine with particular reference to the intervertebral discs: a preliminary report. J Bone Joint Surg. October 1957;39A(5):1135-1164.
1994	Begeman PC, Visarius H, Nolte L-P, Prasad P. Visocelastic shear responses of the cadaver and Hybrid III lumbar spine. In: Proceedings of the 38th Stapp Car Crash Conference. October 31–November 2, 1994; Fort Lauderdale, FL. Warrendale, PA: Society of Automotive Engineers:1-14. SAE 942205.
1979	Berkson MH, Nachemson A, Schultz AB. Mechanical properties of human lumbar spine motion segments, II: responses in compression and shear; influence of gross morphology. J Biomech Eng. February 1979;101(1):53-57.
1989	El-Bohy AA, Yang K-H, King AI. Experimental verification of facet load transmission by direct measurement of facet lamina contact pressure. J Biomech. 1989;22(8-9):931-941.
1951	Virgin WJ. Experimental investigations into the physical properties of the intervertebral disc. J Bone Joint Surg. November 1951;33B(4):607-611.
1984	Yang KH, King AI. Mechanism of facet load transmission as a hypothesis for low-back pain. Spine. September 1984;9(6):557-565.
1972	Markolf KL. Deformation of the thoracolumbar intervertebral joints in response to external loads: a biomechanical study using autopsy material. J Bone Joint Surg. April 1972;54A(3):511-533.
1966	Rolander SD. Motion of the lumbar spine with special reference to the stabilizing effect of posterior fusion: an experimental study on autopsy specimens. Acta Orthop Scand. 1966;37(suppl 90):1-144.

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2007	Kemper A, McNally C, Manoogian S, McNeely D, Duma S. Stiffness properties of human lumbar intervertebral discs in compression and the influence of strain rate. In: Proceedings of the 20th International Technical Conference on the Enhanced Safety of Vehicles (ESV). June 18-21, 2007; Lyon, France.
2013	Zhang N, Zhao J. Study of compression-related lumbar spine fracture criteria using a full body FE human model. In: Proceedings of the 23rd International Technical Conference on the Enhanced Safety of Vehicles (ESV). May 27-30, 2013; Seoul, South Korea.
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2008	Belwadi A, Yang KH. Cadaveric lumbar spine responses to flexion with and without anterior shear displacement. In: Proceedings of the 2008 International IRCOBI Conference on the Biomechanics of Impact. September 17-19, 2008; Bern, Switzerland.397-410.
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2018	Jin X, Kalra A, Hammad A, Khandelwal P, Porwal V, Shen M, Yang KH. Development and validation of whole‐body finite element occupant and pedestrian models of a 70‐year‐old female. In: Proceedings of the 2018 International IRCOBI Conference on the Biomechanics of Injury. September 12-14, 2018; Athens, Greece.261-283.
2020	Östh J, Bohman K, Jakobsson L. Evaluation of kinematics and restraint interaction when repositioning a driver from a reclined to an upright position prior to frontal impact using active human body model simulations. In: Proceedings of the 2020 International IRCOBI Conference on the Biomechanics of Injury. 2020; Munich, Germany.358-380.
2020	Ortiz-Paparoni MA, Pigue M, Bass CR‘. Building a whole spine from segments: lumbar spine response during dynamic compression. In: Proceedings of the 2020 International IRCOBI Conference on the Biomechanics of Injury. 2020; Munich, Germany.770-781.
2023	Iraeus J, Poojary YN, Jaber L, John J, Davidsson J. A new open-source finite element lumbar spine model, its tuning and validation, and development of a tissue-based injury risk function for compression fractures. In: Proceedings of the 2023 International IRCOBI Conference on the Biomechanics of Injury. September 13-165, 2023; Cambridge, United Kingdom.1048-1072.
1999	Demetropoulos CK, Yang KH, Grimm MJ, Artham KK, King AI. High rate mechanical properties of the Hybrid III and cadaveric lumbar spines in flexion and extension. In: Proceedings of the 43rd Stapp Car Crash Conference. October 25-27, 1999; San Diego, CA. Warrendale, PA: Society of Automotive Engineers:279-294. SAE 99SC18.
2017	Arun MWJ, Hadagali P, Driesslein K, Curry W, Yoganandan N, Pintar FA. Biomechanics of lumbar motion-segments in dynamic compression. Stapp Car Crash J. November 2017;61:1-25. SAE 2017-22-0001.
2003	Behr M, Arnoux PJ, Serre T, Bidal S, Kang HS, Thollon L, Cavallero C, Kayvantash K, Brunet C. A human model for road safety: from geometrical acquisition to model validation with Radioss. Comput Methods Biomech Biomed Eng. 2003;6(4):263-273.
2022	Draper D. Validation of Human Body Model Lumbar Spine Performance for Use in New Seating Positions [PhD thesis]. Ludwig Maximilian University of Munich; 2022.
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2012	Beck B. Optimising Protection for Motor Vehicle Rear Seat Occupants [PhD thesis]. University of New South Wales; 2012.