An anatomically based protocol for the description of foot segment kinematics during gait

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Leardini, A.¹; Benedetti, M. G.¹; Catani, F.¹; Simoncini, L.¹; Giannini, S.¹

An anatomically based protocol for the description of foot segment kinematics during gait

Clin Biomech (Bristol, Avon). 1999;14(8):528-536

©1999 Elsevier Science Ltd. All rights reserved.

Affiliations

¹Movement Analysis Laboratory, Istituti Ortopedici Rizzoli, Via di Barbiano 1/10, 40136, Bologna, Italy
Abstract and keywords

Objective: To design a technique for the in vivo description of ankle and other foot joint rotations to be applied in routine functional evaluation using non-invasive stereophotogrammetry.

Design: Position and orientation of tibia/fibula, calcaneus, mid-foot, 1st metatarsal and hallux segments were tracked during the stance phase of walking in nine asymptomatic subjects. Rigid clusters of reflective markers were used for foot segment pose estimation. Anatomical landmark calibration was applied for the reconstruction of anatomical landmarks.

Background: Previous studies have analysed only a limited number of joints or have proposed invasive techniques.

Methods: Anatomical landmark trajectories were reconstructed in the laboratory frame using data from the anatomical calibration procedure. Anatomical co-ordinate frames were defined using the obtained landmark trajectories. Joint co-ordinate systems were used to calculate corresponding joint rotations in all three anatomical planes.

Results: The patterns of the joint rotations were highly repeatable within subjects. Consistent patterns between subjects were also exhibited at most of the joints.

Conclusion: The method proposed enables a detailed description of ankle and other foot joint rotations on an anatomical base. Joint rotations can therefore be expressed in the well-established terminology necessary for their clinical interpretation.

Relevance: Functional evaluation of patients affected by foot diseases has recently called for more detailed and non-invasive protocols for the description of foot joint rotations during gait. The proposed method can help clinicians to distinguish between normal and pathological pattern of foot joint rotations, and to quantitatively assess the restoration of normal function after treatment.

Keywords: Foot joints; Ankle complex; Metatarsophalangeal; Kinematics; Gait analysis; Anatomical co-ordinate systems
Links

DOI: 10.1016/S0268-0033(99)00008-X

PubMed: 10521637

WoS: 000082077700004
History

Received: 1998-05-5

Accepted: 1999-01-21

Online: 1999-08-13

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2008	Glasoe W, Pena F, Phadke V, Ludewig PM. Arch height and first metatarsal joint axis orientation as related variables in foot structure and function. Foot Ankle Int. 2008;29(6):647-654.
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2010	Levinger P, Murley GS, Barton CJ, Cotchett MP, McSweeney SR, Menz HB. A comparison of foot kinematics in people with normal- and flat-arched feet using the Oxford Foot Model. Gait Post. October 2010;32(4):519-523.
2001	Carson MC, Harrington ME, Thompson N, O’Connor JJ, Theologis TN. Kinematic analysis of a multi-segment foot model for research and clinical applications: a repeatability analysis. J Biomech. October 2001;34(10):1299-1307.
2007	Arndt A, Wolf P, Liu A, Nester C, Stacoff A, Jones R, Lundgren P, Lundberg A. Intrinsic foot kinematics measured in vivo during the stance phase of slow running. J Biomech. 2007;40(12):2672-2678.
2007	Jenkyn TR, Nicol AC. A multi-segment kinematic model of the foot with a novel definition of forefoot motion for use in clinical gait analysis during walking. J Biomech. 2007;40(14):3271-3278.
2008	Kirane YM, Michelson JD, Sharkey NA. Evidence of isometric function of the flexor hallucis longus muscle in normal gait. J Biomech. 2008;41(9):1919-1928.
2010	Saraswat P, Andersen MS, MacWilliams BA. A musculoskeletal foot model for clinical gait analysis. J Biomech. 2010;43(9):1645-1652.
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2011	Fassbind MJ, Rohr ES, Hu Y, Haynor DR, Siegler S, Sangeorzan BJ, Ledoux WR. Evaluating foot kinematics using magnetic resonance imaging: from maximum plantar flexion, inversion, and internal rotation to maximum dorsiflexion, eversion, and external rotation. J Biomech Eng. October 2011;133(10):104502.
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