A comprehensive study of pressure distribution in the ankle joint with inversion and eversion

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Calhoun, Jason H.¹; Li, Fan¹; Ledbetter, Billy R.¹; Viegas, Steven F.¹

A comprehensive study of pressure distribution in the ankle joint with inversion and eversion

Foot Ankle Int. March 1994;15(3):125-133

©1994 American Orthopaedic Foot and Ankle Society, Inc.

Affiliations

¹Division of Orthopaedic Surgery, University of Texas Medical Branch, Galveston, Texas
Abstract

The understanding of load transfer characteristics is the baseline for biomechanics of the ankle joint. Changes in contact patterns of the articular cartilage from the norm may indicate pathologic conditions. Measurement of the contact in human cadaver ankles provides a direct measurement for this understanding.

The force transfer characteristics of the three facets of the ankle joint were investigated. Five fresh-frozen cadaver lower extremities were tested in 12 positions under three axial loads of 490, 686, and 980 N. Fuji film served as the pressure transducer and the prints were analyzed by a computerized video digitizer. The results demonstrated that as the foot was moved into inversion or eversion with the ankle in neutral flexion or dorsiflexion, there was a decrease in total contact area and an increase in the average high pressure. In plantarflexion, the contact area was lower and the average high pressure was higher, indicating a greater force per unit area as compared with dorsiflexion and neutral flexion. In plantarflexion, however, little change was noted with inversion or eversion. In dorsiflexion, the total contact area was higher and the average high pressure slightly lower as compared with neutral flexion. With inversion, the contact area of the medial facet of the ankle increased and with eversion it increased on the lateral facet, especially in dorsiflexion. With an increase in loading, the pressure did not significantly increase but the contact area did increase. The centroid of the contact moved anteriorly to posteriorly on the talus as the joint moved from dorsiflexion to plantarflexion. The talar dome facet sustained 77% to 90% of the load, while the medial facet was loaded more during inversion (up to 22%) and the lateral facet was loaded more during eversion (up to 10.5%).

No previous study has examined the relative contributions of the three main talar joint surfaces in multiple positions. The new information in this study includes the fibular and medial facet contribution and the variation of the load with position changes and loading increase. This study also provides a comprehensive evaluation of the pressure, contact area, and centroid of the ankle joint in its normal ranges of motion.
Links

DOI: 10.1177/107110079401500307

PubMed: 7951940

WoS: A1994PA07100006

Cited Works (6)

Year	Entry
1982	Procter P, Paul P J. Ankle joint biomechanics. J Biomech. 1982;15(9):627-634.
1971	Lambert KL. The weight-bearing function of the fibula: a strain gauge study. J Bone Joint Surg. April 1971;53A(3):507-513.
1950	Lauge-Hansen N. Fractures of the ankle, II: combined experimental-surgical and experimental-roentgenologic investigations. Arch Surg. 1950;60(5):957-985.
1976	Ramsey PL, Hamilton W. Changes in tibiotalar area of contact caused by lateral talar shift. J Bone Joint Surg. April 1976;58A(3):356-357.
1956	Close JR. Some applications of the functional anatomy of the ankle joint. J Bone Joint Surg. July 1956;38A(4):761-781.
1985	Stormont DM, Morrey BF, An K-N, Cass JR. Stability of the loaded ankle: relation between articular restraint and primary and secondary static restraints. Am J Sports Med. 1985;13(5):295-300.

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2016	Lareau CR, Hsu AR, Cohen BE. Acute syndesmotic injuries. In: Valderrabano V, Easley M, eds. Foot and Ankle Sports Orthopaedics. Cham, Switzerland: Springer International Publishing; 2016:265-277.
2003	Funk JR, Rudd RW, Kerrigan JR, Crandall JR. Analysis of tibial curvature, fibular loading, and the tibia index. In: Proceedings of the 2003 International IRCOBI Conference on the Biomechanics of Impact. September 25, 2003; Lisbon, Portugal.135-147.
2017	Butz K, Spurlock C, Roy R, Bell C, Barrett P, Ward A, Xiao X, Shirley A, Welch C, Liste K. Development of the CAVEMAN human body model: validation of lower extremity sub-injurious response to vertical accelerative loading. Stapp Car Crash J. November 2017;61:175-209. SAE 2017-22-0006.
2012	Shin J, Yue N, Untaroiu CD. A finite element model of the foot and ankle for automotive impact applications. Ann Biomed Eng. December 2012;40(12):2519-2531.
1996	Michelson JD, Waldman B. An axially loaded model of the ankle after pronation external rotation injury. Clin Orthop Relat Res. July 1996;328:285-293.
2000	Leardini A, O'Connor JJ, Catani F, Giannini S. The role of the passive structures in the mobility and stability of the human ankle joint: a literature review. Foot Ankle Int. 2000;21(7):602-615.
2007	Funk JR, Rudd RW, Kerrigan JR, Crandall JR. The line of action in the tibia during axial compression of the leg. J Biomech. 2007;40(10):2277-2282.
2007	Sasimontonkul S, Bay BK, Pavol MJ. Bone contact forces on the distal tibia during the stance phase of running. J Biomech. 2007;40(15):3503-3509.
2001	Lakin RC, DeGnore LT, Pienkowski D. Contact mechanics of normal tarsometatarsal joints. J Bone Joint Surg. 2001;83A(4):520-528.
2004	Funk JR, Rudd RW, Kerrigan JR, Crandall JR. The effect of tibial curvature and fibular loading on the tibia index. Traffic Inj Prev. June 2004;5(2):164-172.
2017	Saers JPP. Ontogeny and Functional Adaptation of Trabecular Bone in the Human Foot [PhD thesis]. Cambridge, UK: University of Cambridge; July 2017.
2004	Imhauser CW. The Development and Evaluation of a 3-Dimensional, Image-Based, Patientspecific, Dynamic Model of the Hindfoot [PhD thesis]. Philadelphia, PA: Drexel University; August 2004.
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.
2004	Sasimontonkul S. Do Running and Fatigued Running Relate to Tibial Stress Fractures? [PhD thesis]. Oregon State University; 2004.
2011	Su A. The Functional Morphology of Subchondral and Trabecular Bone in the Hominoid Tibiotalar Joint [PhD thesis]. Stony Brook, NY: Stony Brook University; August 2011.
2005	Valderrabano V. Ankle Osteoarthritis: Biomechanical and Orthopaedic Aspects [PhD thesis]. Calgary, AB: University of Calgary; December 2005.
2006	Monteleone BJ. Effects of Functional Ankle Instability on Ankle Joint Complex Dynamics and Motor Control [PhD thesis]. Calgary, AB: University of Calgary; August 2006.
2016	Bingenheimer HKJ. Analysis of Hindfoot Alignment for Total Ankle Arthroplasties [Master's thesis]. University of Iowa; December 2016.
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.