Axial impact biomechanics of the human foot-ankle complex

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Yoganandan, N.¹; Pintar, F. A.¹; Kumaresan, S.¹; Boynton, M.²

Axial impact biomechanics of the human foot-ankle complex

J Biomech Eng. November 1997;119(4):433-437

©1997 ASME

Affiliations

¹Department of Neurosurgery, Medical College of Wisconsin; Department of Veterans’ Affairs Medical Center, Milwaukee, WI 53226

²Department of Orthopedic Surgery, Medical College of Wisconsin; Department of Veterans’ Affairs Medical Center, Milwaukee, WI 53226
Abstract

Recent epidemiological, clinical, and biomechanical studies have implicated axial impact to the plantar surface of the foot to be a cause of lower extremity trauma in vehicular crashes. The present study was conducted to evaluate the biomechanics of the human foot–ankle complex under axial impact. Nine tests were conducted on human cadaver below knee–foot–ankle complexes. All specimens were oriented in a consistent anatomical position on a mini-sled and the impact load was delivered using a pendulum. Specimens underwent radiography and gross dissection following the test. The pathology included intra-articular fractures of the calcaneus and/or the distal tibia complex with extensions into the anatomic joints. Impactor load cell forces consistently exceeded the tibial loads for all tests. The mean dynamic forces at the plantar surface of the foot were 7.7 kN (SD = 4.3) and 15.1 kN (SD = 2.7) for the nonfracture and fracture tests, respectively. In contrast, the mean dynamic forces at the proximal tibial end of the preparation were 5.2 kN (SD = 3.1) in the nonfracture group, and 10.2 kN (SD = 1.5) in the fracture group. The foot and tibial end forces were statistically significantly different between these two groups (p < 0.01). The present investigation provides fundamental data to the understanding of the biomechanics of human foot–ankle trauma. Quantifying the effects of other factors such as gender and bone quality on the injury thresholds is necessary to understand foot–ankle tolerance fully.
Links

DOI: 10.1115/1.2798290

PubMed: 9407282

WoS: A1997YH79100010
History

Received: 1996-03-13

Revised: 1996-11-25

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Cited By (29)

Year	Entry
2001	Funk JR, Crandall JR, Tourret LJ, MacMahon CB, Bass CR, Khaewpong N, Eppinger RH. The effect of active muscle tension on the axial injury tolerance of the human foot/ankle complex. In: Proceedings of the 17th International Technical Conference on the Enhanced Safety of Vehicles (ESV). June 4-7, 2001; Amsterdam, The Netherlands.
2003	Arndt N, Grzebieta R, Zou R. Validating lower limb injury mechanisms in side impact crashes. In: Proceedings of the 18th International Technical Conference on the Enhanced Safety of Vehicles (ESV). May 19-22, 2003; Nagoya, Japan.
2001	Griffin LV, Harris RM, Hayda RA, Rountree MS. Loading rate and torsional moments predict pilon fractures for antipersonnel blast mine loading. In: Proceedings of the 2001 International IRCOBI Conference on the Biomechanics of Impact. October 10-12, 2001; Isle of Man, UK.
2013	Bailey AM, Christopher JJ, Henderson K, Brozoski F, Salzar RS. Comparison of Hybrid‐III and PMHS response to simulated underbody blast loading conditions. In: Proceedings of the 2013 International IRCOBI Conference on the Biomechanics of Injury. September 11-13, 2013; Gothenburg, Sweden.158-170.
2014	Perry BJ, Gabler L, Bailey A, Henderson K, Brozoski F, Salzar RS. Lower extremity characterization and injury mitigation. In: Proceedings of the 2014 International IRCOBI Conference on the Biomechanics of Injury. September 10-12, 2014; Berlin, Germany.186-197.
2014	Alai AL, Salzar RS. Measurement of force in IED vehicle interactions. In: Proceedings of the 2014 International IRCOBI Conference on the Biomechanics of Injury. September 10-12, 2014; Berlin, Germany.785-795.
2018	Grigoriadis G, Carpanen D, Webster C, Newell N, Masouros SD. The posture of the lower limb alters the mechanism of injury in under‐body blast. In: Proceedings of the 2018 International IRCOBI Conference on the Biomechanics of Injury. September 12-14, 2018; Athens, Greece.758-759.
2021	Hostetler ZS, Aira J, Caffrey J, Gayzik FS. Analyzing the force variation and response of a human body finite element model in the underbody blast environment. In: Proceedings of the 2021 International IRCOBI Conference on the Biomechanics of Injury. September 8-10, 2021; Online.616-625.
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.
2002	Funk JR, Crandall JR, Tourret LJ, MacMahon CB, Bass CR, Patrie JT, Khaewpong N, Eppinger RH. The axial injury tolerance of the human foot/ankle complex and the effect of Achilles tension. J Biomech Eng. 2002;124(6):750-757.
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.
2017	Yoganandan N, Chirvi S, Voo L, DeVogel N, Pintar FA, Banerjee A. Foot-ankle complex injury risk curves using calcaneus bone mineral density data. J Mech Behav Biomed Mater. August 2017;72:246-251.
2008	Bir C, Barbir A, Dosquet F, Wilhelm M, van der Horst M, Wolfe G. Validation of lower limb surrogates as injury assessment tools in floor impacts due to anti-vehicular land mines. Mil Med. December 2008;173(12):1180-1184.
2017	Quenneville CE, Fournier E, Shewchenko N. The effect of anthropomorphic test device lower leg surrogate selection on impact mitigating system evaluation in low- and high-rate loading conditions. Mil Med. September–October 2017;182(9-10):e1981-e1986.
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.
2016	Smolen C, Quenneville CE. The effect of ankle posture on the load pathway through the hindfoot. Proc Inst Mech Eng Part H-J Eng Med. November 2016;230(11):1024-1035.
2005	Smith BR, Begeman PC, Leland R, Meehan R, Levine RS, Yang KH, King AI. A mechanism of injury to the forefoot in car crashes. Traffic Inj Prev. 2005;6(2):156-169.
2013	Newell N. Foot and Ankle Blast Injury and Its Mitigation [PhD thesis]. Imperial College London; June 2013.
2016	Bonner TJ. An Investigation Into Lower Limb Injuries Caused by Improvised Explosive Devices [PhD thesis]. Imperial College London; 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	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.
2002	Beardsley CL. Development of Quantitative Measures for Bone Comminution Severity [PhD thesis]. University of Iowa; May 2002.
2000	Funk JR. The Effect of Active Muscle Tension on the Axial Impact Tolerance of the Human Foot/ankle Complex [PhD thesis]. Charlottesville, VA: University of Virginia; August 2000.
2011	Shin J. Injury and Response of Human Ankle and Subtalar Joints Under Complex Loading [PhD thesis]. Charlottesville, VA: University of Virginia; December 2011.
2016	Bailey AM. Injury Assessment for the Human Leg Exposed to Axial Impact Loading [PhD thesis]. Charlottesville, VA: University of Virginia; September 2016.
2016	Christopher JJ. Biomechanical Response of the Human Pelvis: A High-Rate Vertical Loading Pilot Study [Master's thesis]. Charlottesville, VA: University of Virginia; May 2016.
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]. University of Western Ontario; December 2009.
2013	Reeves JM. Development and Assessment of an Impact Apparatus and High-Speed Camera Motion Tracking System to Quantify the Effect of Static Muscle Loads on Fracture Threshold Measures in the Distal Radius [Master's thesis]. University of Western Ontario; 2013.