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Searching for the 'sweet spot': the foot rotation and parallel engagement of ankle ligaments in maximizing injury tolerance.

Authors :
Nie, Bingbing
Forman, Jason
Mait, Alexander
Donlon, John-Paul
Panzer, Matthew
Kent, Richard
Source :
Biomechanics & Modeling in Mechanobiology. Dec2017, Vol. 16 Issue 6, p1937-1945. 9p.
Publication Year :
2017

Abstract

Ligament sprains, defined as tearing of bands of fibrous tissues within ligaments, account for a majority of injuries to the foot and ankle complex in field-based sports. External rotation of the foot is considered the primary injury mechanism of syndesmotic ankle sprains with concomitant flexion and inversion/eversion associated with particular patterns of ligament trauma. However, the influence of the magnitude and direction of loading vectors to the ankle on the in situ stress state of the ligaments has not been quantified in the literature. The objective of the present study was to search for the maximum injury tolerance of a human foot with an acceptable subfailure distribution of individual ligaments. We used a previously developed and comprehensively validated foot and ankle model to reproduce a range of combined foot rotation experienced during high-risk sports activities. Biomechanical computational investigation was performed on initial foot rotation from $$20{^{\circ }}$$ of plantar flexion to $$15{^{\circ }}$$ of dorsiflexion, and from $$15{^{\circ }}$$ of inversion to $$15{^{\circ }}$$ of eversion prior to external rotation. Change in initial foot rotation shifted injury initiation among different ligaments and resulted in a wide range of injury tolerances at the structural level (e.g., 36-125 Nm of rotational moment). The observed trend was in agreement with a parallel experimental study that initial plantar flexion decreased the incidence of syndesmotic injury compared to a neutral foot. A mechanism of distributing even loads across ligaments subjected to combined foot rotations was identified. This mechanism is potential to obtain the maximum load-bearing capability of a foot and ankle while minimizing the injury severity of ligaments. Such improved understanding of ligament injuries in athletes is necessary to facilitate injury management by clinicians and countermeasure development by biomechanists. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
16177959
Volume :
16
Issue :
6
Database :
Academic Search Index
Journal :
Biomechanics & Modeling in Mechanobiology
Publication Type :
Academic Journal
Accession number :
126056451
Full Text :
https://doi.org/10.1007/s10237-017-0929-z