Biomechanics of calcaneal fractures: a model for the motor vehicle

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Seipel, Robert C.¹; Pintar, Frank A.²; Yoganandan, Narayan²; Boynton, Melbourne D.³

Biomechanics of calcaneal fractures: a model for the motor vehicle

Clin Orthop Relat Res. July 2001;388:218-224

©2001 Lippincott Williams & Wilkins, Inc.

Affiliations

¹Department of Orthopaedic Surgery, Medical College of Wisconsin, VA Medical Center, Milwaukee WI

²Department of Neurosurgery, Medical College of Wisconsin, VA Medical Center, Milwaukee WI

³Vermont Orthopaedic Clinic, Rutland, VT
Abstract and keywords

Changes in legislation, availability of passive or active restraint systems, or both, together with increased public awareness for safety and the need for use of restraint, have shifted the spectrum of trauma in motor vehicle crashes from the head and torso to other regions. Lower extremity trauma in motor vehicle crashes continues to be a significant problem. The objective of this study was to investigate the biomechanics of the human foot and ankle complex under impact loading and replicate calcaneal fractures routinely seen in motor vehicle crashes. Twenty-two unembalmed cadaver lower extremity specimens were subjected to dynamic loads using a minisled pendulum device. Input and output forces and results of pathologic analysis were obtained using load cell data, radiographs obtained before and after testing, and gross dissection. The intraarticular fracture patterns produced were similar to those seen clinically and described in the literature. Maximum forces ranged from 3.6 to 11.4 kN for the fracture, and 0.5 to 7.3 kN for the nonfracture groups. Logistic regression analysis revealed a 50% probability of calcaneal fracture at 5.5 kN and a 25% probability at 4.0 kN. These studies will lead to an understanding of the tolerance of the lower extremity in sustaining calcaneal fractures under impact. Implications of the work are in the design of crash test dummies, data acquisition, and modifications in motor vehicle design and safety.

Keywords:
Links

DOI: 10.1097/00003086-200107000-00030

PubMed: 11451123

WoS: 000169655000030
History

Received: 1999-06-23

Revised: 2000-02-22

Revised: 2000-07-20

Revised: 2000-08-31

Revised: 2000-10-20

Accepted: 2000-11-03

Cited Works (12)

Year	Entry
1987	Backaitis SH, Roberts JV. Occupant injury patterns in crashes with airbag equipped government sponsored cars. In: Proceedings of the 31st Stapp Car Crash Conference. November 9-11, 1987; New Orleans, LA. Warrendale, PA: Society of Automotive Engineers:251-266. SAE 872216.
1979	Gloyns PF, Hayes HRM, Rattenbury SJ, Thomas PD, Mills HC, Griffiths DK. Lower limb injuries to car occupants in frontal impacts. In: Proceedings of the 1979 International IRCOBI Conference on the Biomechanics of Impact. September 5-7, 1979; Goeteborg, Sweden.105-121.
1994	Dischinger PC, Burgess AR, Cushing BM, O'Quinn TD, Schmidhauser CB, Ho SM, Juliano PJ, Bents FD. Lower extremity trauma in vehicular front-seat occupants: patients admitted to a level 1 trauma center. In: Proceedings of the SAE International Congress & Exposition. February 28–March 3, 1994; Detroit, MI. Warrendale, PA: Society of Automotive Engineers. SAE 940710.
1988	MacKenzie EJ, Siegel JH, Shapiro S, Moody M, Smith RT. Functional recovery and medical costs of trauma: an analysis by type and severity of injury. J Trauma. March 1988;28(3):281-297.
1996	Loo GT, Siegel JH, Dischinger PC, Rixen D, Burgess AR, Addis MD, O'Quinn T, McCammon L, Schmidhauser CB, Marsh P, Hodge PA, Bents F. Airbag protection versus compartment intrusion effect determines the pattern of injuries in multiple trauma motor vehicle crashes. J Trauma. December 1996;41(6):935-951.
1995	Crandall JR, Martin PG, Sieveka EM, Klopp GS, Kuhlmann TP, Pilkey WD, Dischinger PC, Burgess AR, O'Quinn TD, Schmidhauser CB. The influence of footwell intrusion on lower extremity response and injury in frontal crashes. In: 39th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). October 16-18, 1995; Chicago, IL.269-286.
1995	Burgess AR, Dischinger PC, O'Quinn TD, Schmidhauser CB. Lower extremity injuries in drivers of airbag-equipped automobiles: clinical and crash reconstruction correlations. J Trauma. April 1995;38(4):509-516.
1986	States JD. Adult occupant injuries of the lower limb. In: Biomechanics and Medical Aspects of Lower Limb Injuries. Symposium on Biomechanics and Medical Aspects of Lower Limb Injuries; October 29-30, 1986; San Diego, CA. Warrendale, PA: Society of Automotive Engineering:97-107. SAE 861927.
1994	Krüger HJ, Heuser G, Kraemer B, Schmitz A. Foot loads and footwell intrusion in an offset frontal crash. In: Proceedings of the 14th International Technical Conference on the Enhanced Safety of Vehicles (ESV). May 23-26, 1994; Munich, Germany.528-534.
1992	Otte D, von Rheinbaben H, Zwipp H. Biomechanics of injuries to the foot and ankle joint of car drivers and improvements for an optimal car floor development. In: Proceedings of the 36th Stapp Car Crash Conference. November 2-4, 1992; Seattle, WA. Warrendale, PA: Society of Automotive Engineers:43-58. SAE 922514.
1992	Dischinger P, Cushing B, Kerns T. Lower extremity fractures in motor vehicle collisions: influence of direction of impact and seatbelt use. In: 36th Annual Proceedings, Association for the Advancement of Automotive Medicine (AAAM). October 5-7, 1992; Portland, OR.319-325.
1991	Morgan RM, Eppinger RH, Hennessey BC. Ankle joint injury mechanism for adults in frontal automotive impact. In: Proceedings of the 35th Stapp Car Crash Conference. November 18-20, 1991; San Diego, CA. Warrendale, PA: Society of Automotive Engineers:189-198. SAE 912902.

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Year	Entry
2005	van der Horst MJ, Simms CK, van Maasdam R, Leerdam PJC. Occupant lower leg injury assessment in landmine detonations under a vehicle. In: Gilchrist MD, ed. IUTAM Symposium on Impact Biomechanics: From Fundamental Insights to Applications. Dordrecht, The Netherlands: Springer; 2005:41-49. Solid Mechanics and Its Applications; vol 124.
2005	Manseau J, Keown M. Evaluation of the complex lower leg (CLL) for its use in anti-vehicular mine testing applications. In: Proceedings of the 2005 International IRCOBI Conference on the Biomechanics of Impact. September 21-23, 2005; Prague, Czech Republic.299-310.
2016	Martinez A, Chakravarty A, Quenneville CE. The effect of impulse on the axial fracture tolerance of the isolated tibia during automotive and military impacts. In: Proceedings of the 12th Ohio State University Injury Biomechanics Symposium. June 5-7, 2016; Columbus, OH.
2016	Yoganandan N, Chirvi S, Pintar FA, Uppal H, Schlick M, Banerjee A, Voo L, Merkle A, Kleinberger M. Foot–ankle fractures and injury probability curves from post-mortem human surrogate tests. Ann Biomed Eng. October 2016;44(10):2937-2947.
2017	Chakravarty AB, Martinez AA, Quenneville CE. The injury tolerance of the tibia under off-axis impact loading. Ann Biomed Eng. June 2017;45(6):1534-1542.
2004	Hardin EC, Su A, van den Bogert AJ. Foot and ankle forces during an automobile collision: the influence of muscles. J Biomech. 2004;37(5):637-644.
2016	Yoganandan N, Banerjee A, Hsu F-C, Bass CR, Voo L, Pintar FA, Gayzik FS. Deriving injury risk curves using survival analysis from biomechanical experiments. J Biomech. October 3, 2016;49(14):3260-3267.
2010	Quenneville CE, Fraser GS, Dunning CE. Development of an apparatus to produce fractures from short-duration high-impulse loading with an application in the lower leg. J Biomech Eng. January 2010;132(1):014502.
2018	Martinez AA, Chakravarty AB, Quenneville CE. The effect of impact duration on the axial fracture tolerance of the isolated tibia during automotive and military impacts. J Mech Behav Biomed Mater. February 2018;78:315.
2011	Quenneville CE, McLachlin SD, Greeley GS, Dunning CE. Injury tolerance criteria for short-duration axial impulse loading of the isolated tibia. J Trauma. January 2011;70(1):E13-E18.
2011	Ramasamy A, Masouros SD, Newell N, Hill AM, Proud WG, Brown KA, Bull AMJ, Clasper JC. In-vehicle extremity injuries from improvised explosive devices: current and future foci. Philos Trans R Soc B. January 27, 2011;366(1562):160-170.
2013	Newell N. Foot and Ankle Blast Injury and Its Mitigation [PhD thesis]. Imperial College London; June 2013.
2016	Grigoriadis G. Heel Biomechanics Under Blast Conditions [PhD thesis]. Imperial College London; June 2016.
2015	Smolen C. Evaluation of the Load Path Through the Foot/ankle Complex in Various Postures Through Cadaveric and Finite Element Model Testing [Master's thesis]. Hamilton, ON: McMaster University; September 2015.
2016	Chakravarty AB. The Effects of Off-Axis Loading on Fracture Risk in the Human Tibia [Master's thesis]. Hamilton, ON: McMaster University; September 2016.
2016	Martinez AA. The Effect of Load Rate on the Axial Fracture Tolerance of the Isolated Tibia During Automotive and Military Impacts [Master's thesis]. Hamilton, ON: McMaster University; 2016.
2019	de Lange J. Biomechanical Tools for Assessing Foot and Ankle Injury Risk in Frontal Automotive Collisions [Master's thesis]. Hamilton, ON: McMaster University; 2019.
2018	Cristino DM. Lower Extremity Biomechanical Response of Female and Male Post-Mortem Human Surrogates to High-Rate Vertical Loading During Simulated Under-Body Blast Events [PhD thesis]. Virginia Polytechnic Institute and State University; December 13, 2018.
2020	Ceritano DW. Sex-Based Differences in Calcaneal Injury Tolerances Under High-Rate Loading [Master's thesis]. Virginia Polytechnic Institute and State University; May 22, 2020.
2009	Quenneville CE. Experimental and Numerical Assessments of Injury Criteria for Short-Duration, High-Force Impact Loading of the Tibia [PhD thesis]. London, ON: University of Western Ontario; December 2009.