Strain and loading of the second metatarsal during heel-lift

Sharkey, N. A.; Ferris, L.; Smith, T. S.; Matthews, D. K.

Affiliations

¹Orthopaedic Research Laboratories. University of California, Davis, Research Facility, Room 2000, 4815 Second Avenue, Sacramento, California 95817

²Department of Orthopaedic Surgery, University of California, Davis, 2230 Stockton Boulevard, Sacramento, California 95817

Abstract

Metatarsal stress fractures occur in military recruits after long marches and in athletes after episodes of overtraining involving running or jumping. It has been demonstrated that contraction of the plantar flexors of the toes helps to counteract the moments placed on the metatarsals by body weight. It is possible that physiological fatigue due to strenuous or repetitive exercise reduces the rate and force of contraction of the plantar flexors, thereby increasing metatarsal strain per cycle, and that this mechanism is the primary cause of stress fractures of these bones.

To test the hypothesis that fatigue of the plantar flexors causes increased metatarsal loading, thereby predisposing these bones to stress fracture, we measured metatarsal strains in nine fresh cadaveric feet with use of an apparatus that simulated physiological loading due to body weight as well as contraction of the plantar flexors. Each foot was loaded to 750 newtons of ground-reaction force by simulated contraction of the triceps surae, and strains were recorded in the mid-part of the shaft of the second metatarsal. Tests were repeated with use of simulated activity of different combinations of the flexor digitorum longus, flexor hallucis longus, peroneus brevis, peroneus longus, and tibialis posterior muscles. In situ bending moments and axial loads subsequently were derived for each configuration. Dorsal strain was significantly reduced by simulated contraction of the flexor hallucis longus. Plantar-dorsal bending was significantly reduced by simulated contraction of the flexor digitorum longus.

CLINICAL RELEVANCE: Metatarsal stress fractures, traditionally associated with intense military training, are being seen with increasing frequency in civilian athletes. The results of the present study suggest that muscular fatigue plays a role in the etiology of such injuries. Training regimens for soldiers or athletes that involve continued exertion in the presence of fatigue of the muscles of the leg should be considered risk factors for metatarsal stress fracture.

Links

DOI: 10.2106/00004623-199507000-00011

PubMed: 7608227

WoS: A1995RJ67100011

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Cited By (16)

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2012	Chen W, Lee PVS. Three-dimensional finite element analysis of human foot during heel rise: role of the gastrocnemius-soleus (G-S) muscle. In: Bradshaw EJ, Burnett A, Hume PA, eds. Proceedings of the 30th International Conference on Biomechanics in Sports. July 2-6, 2012; Melbourne, Austalia.393-396.
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1999	Sharkey NA, Donahue SW, Ferris L. Biomechanical consequences of plantar fascia release or rupture during gait, II: alterations in forefoor loading. Foot Ankle Int. February 1999;20(2):86-96.
2016	Stefanyshyn DJ, Wannop JW. The influence of forefoot bending stiffness of footwear on athletic injury and performance. Footwear Sci. 2016;8(2):51-63.
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