Thoracic and lumbar spine responses in high-speed rear sled tests

References

• Begeman PC, Visarius H, Nolte LP, Prasad P. Viscoelastic Shear Responses of the Cadaver and Hybrid III Lumbar Spine. Warrendale, PA: Society of Automotive Engineers; 1994. SAE 942205.
   Google Scholar
• Chance GQ. Note on a type of flexion fracture of the spine. Br J Radiol. 1948;21(249):452–53.
   PubMed Web of Science ®Google Scholar
• Chandler RF. Human Injury Criteria Relative to Civil Aircraft Seat and Restraint Systems. Warrendale, PA: Society of Automotive Engineers; 1985. SAE 851847.
   Google Scholar
• Cotterill PC, Kostuik JP, Wilson JA, Fernie GR, Maki BE. Production of a reproducible spinal burst fracture for use in biomechanical testing. J Orthop Res. 1987;5:462–465.
   PubMed Web of Science ®Google Scholar
• 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. Ann Arbor, MI: The Stapp Association; 1999. SAE 99SC18.
   Google Scholar
• Demetropoulos CK, Yang KH, Grimm MJ, Khalil TB, King AI. Mechanical Properties of the Cadaveric and Hybrid III Lumbar Spines. Warrendale, PA: Society of Automotive Engineers; 1998. SAE 983160.
   Google Scholar
• Department of Defense. Crew Systems Crash Protection Handbook, Joint Services Specification Guide. 1998. JSSG-2010-7.
   Google Scholar
• Freyder DR, Peterman EK, Moor DR, Ratliff AR, Wiechel JF. MADYMO Model to Assess Lumbar Spine Loading during Activities of Daily Living. Warrendale, PA: Society of Automotive Engineers; 2008. SAE 2008-01-1910.
   Google Scholar
• Gallagher S, Marras WS. Tolerance of the lumbar spine to shear: a review and recommended exposure limits. Clin Biomech (Bristol, Avon). 2012;27:973–978.
   PubMed Web of Science ®Google Scholar
• Gates D, Bridges A, Welch TDJ, Lam T, Scher I, Yamaguchi G. Lumbar Loads in Low to Moderate Speed Rear Impacts. Warrendale, PA: Society of Automotive Engineers; 2010. SAE 2010-01-0141.
   Google Scholar
• Insurance Research Council. Auto Injury Insurance Claims: Countrywide Patterns in Treatment, Cost, and Compensation. Malvern, PA: American Institute for Chartered Property Casualty Underwriters; 2014.
   Google Scholar
• Kang YS, Bolte JH IV, Moorhouse K, Donnelly B, Herriott R, Mallory A. Biomechanical responses of PMHS in moderate-speed rear impacts and development of response targets for evaluating the internal and external biofidelity of ATDS. Stapp Car Crash J. 2012;56:105–170.
   PubMedGoogle Scholar
• Lee WE III, Gonzalez-Blohm SA, Doulgeris JJ, et al. Lumbar intervertebral disc injuries in low velocity rear end vehicular collisions: the current evidence. Ann Orthop Rheumatol. 2014;2:1036.
   Google Scholar
• Manoogian SJ, Funk JR, Cormier JM, Bain CE, Guzman H, Bonugli E. Evaluation of Thoracic and Lumbar Accelerations of Volunteers in Vertical and Horizontal Loading Scenarios. Warrendale, PA: Society of Automotive Engineers; 2010. SAE 2010-01-0146.
   Google Scholar
• McGowan JC, Levitt A, Corrigan C, Burnett R, Lucas S. Seatback Strength and Occupant Response in Rear Impact Crash: Observations with Respect to Large Occupant Size and Position. Warrendale, PA: Society of Automotive Engineers; 2010. SAE 2010-01-1029.
   Google Scholar
• Molz FJ, Bidez MW, Zeidler F, Breitner R. Spinal Burst or Compression Fractures within Automotive Crashes Due to Vertical Force Components. Warrendale, PA: Society of Automotive Engineers; 1997. SAE 970498.
   Google Scholar
• Moorhouse K, Donnelly B, Kang YS, Bolte JH IV, Herriott R. Evaluation of the internal and external biofidelity of current rear impact ATDs to response targets developed from moderate-speed rear impacts of PMHS. Stapp Car Crash J. 2012;56:171–229.
   PubMedGoogle Scholar
• Myklebust J, Sances A, Maiman D, Pintar F, Chilbert M. Experimental Spinal Trauma Studies in the Human and Monkey Cadaver. Warrendale, PA: Society of Automotive Engineers; 1983. SAE 831614.
   Google Scholar
• Osvalder AL. Biomechanical Experimental Studies of the Lumbar Spine under Static and Dynamic Loading Conditions. Warrendale, PA: Society of Automotive Engineers; 1995. SAE 950661.
   Google Scholar
• Parenteau CS, Viano DC. Spinal fracture–dislocations and spinal cord injuries in motor vehicle crashes. Traffic Inj Prev. 2014;15:694–700.
   PubMed Web of Science ®Google Scholar
• Patrick LM. Caudo-cephalad static and dynamic injuries to the vertebrae. Paper presented at: AAAM Conference; 1987.
   Google Scholar
• Pellettiere JA, Moorcroft D, Olivares G. Anthropomorphic test dummy lumbar load variation. Paper presented at: 22nd ESV Conference; Washington, DC; 2011.
   Google Scholar
• Prasad P, Kim AS, Weerappuli DVP. Biofidelity of Anthropomorphic Test Devices for Rear Impact. Warrendale, PA: Society of Automotive Engineers; 1997. SAE 973342.
   Google Scholar
• Prasad P, Kim AS, Weerappuli DVP, Roberts VL. Relationships between Passenger-Car Seat Back Strength and Occupant Injury Severity in Rear-end Collisions: Field and Laboratory Studies. Warrendale, PA: Society of Automotive Engineers; 1997. SAE 973343.
   Google Scholar
• Ripple GR, Mundie TG. Medical Evaluation of Nonfragment Injury Effects in Armored Vehicle Live Fire Tests. Washington, DC: Walter Reed Army Institute of Research; 1989. AD-A233 058.
   Google Scholar
• Schoenbeck A, Forster E, Rapaport M, Domzalski L. Impact Response of Hybrid III Lumbar Spine to + Gz Loads. Warrendale, PA: Society of Automotive Engineers; 1998. SAE 981215.
   Google Scholar
• Society of Automotive Engineers. Instrumentation for Impact Tests—Electronic Instrumentation. Warrendale, PA: Society of Automotive Engineers; 1995. SAE Recommended Practice J211-1.
   Google Scholar
• Tremblay J, Bergeron DM, Gonzalez R. Protection of Soft-Skinned Vehicle Occupants from Landmine Effects. Technical Cooperation Program (TCP), WPN/TP-1, KTA 1-29, Technical Report, August 1998.
   Google Scholar
• Viano DC. Role of the Seat in Rear Crash Safety. Warrendale, PA: Society of Automotive Engineers; 2002.
   Google Scholar
• Viano DC. ed. The Debate between Stiff and Yielding Seats: A New Generation of Yielding Seats with High Retention in Rear Crashes. Warrendale, PA: Society of Automotive Engineers; 2003.
   Google Scholar
• Viano DC. Seat design principles to reduce neck injuries in rear impacts. Traffic Inj Prev. 2008;9:552–560.
   PubMed Web of Science ®Google Scholar
• Viano DC, Olsen S. The effectiveness of active heads restraint in preventing whiplash. J Trauma. 2001;51:959–969.
   PubMed Web of Science ®Google Scholar
• Viano DC, Parenteau CS. BioRID dummy responses in matched ABTS and conventional seat tests on the IIHS rear sled. Traffic Inj Prev. 2011;12:339–346.
   PubMed Web of Science ®Google Scholar
• Viano DC, Parenteau CS, Burnett R, Prasad P. Occupant responses in conventional and ABTS seats in high-speed rear sled tests. Traffic Inj Prev. 2018;19:54–59.
   PubMed Web of Science ®Google Scholar
• Viano DC, White S. Seat strength in rear body block tests. Traffic Inj Prev. 2016;17:502–507.
   PubMed Web of Science ®Google Scholar
• Welch TDJ, Bridges AW, Gates DH, et al. An Evaluation of the BioRID II and Hybrid III during Low- and Moderate-Speed Rear Impact. Warrendale, PA: Society of Automotive Engineers; 2010. SAE 2010-01-1031.
   Google Scholar
• Yang N, Lam T, Dainty D, Lau E. Lumbar Spine Injuries in Rear Impacts of Different Severities. Warrendale, PA: Society of Automotive Engineers; 2013. SAE 2013-01-0221.
   Google Scholar
• Yoganandan N, Pintar FA, Haffner M, Jenizen J, Malman DJ. Epidemiology and Injury Biomechanics of Motor Vehicle Related Trauma to the Human Spine. Warrendale, PA: Society of Automotive Engineers; 1989. SAE 892438.
   Google Scholar
• Yoganandan N, Pintar F, Sances A, et al. Biomechanical Investigations of the Human Lumbar Spine. Warrendale, PA: Society of Automotive Engineers; 1988. SAE 881331.
   Google Scholar
• Zhang N, Zhao J. Study of Compression-Related Lumbar Spine Fracture Criteria Using a Full Body FE Human Model. Washington, DC: NHTSA; 2013.
   Google Scholar