AI Article Synopsis
- Magnetic resonance (MR) imaging is being increasingly utilized to study foot biomechanics, with a new device designed to position the foot while the subject lies supine in the scanner.
- Despite controlled conditions for knee flexion and external load, the study found that the subtalar and talo-navicular joint rotations did not match between lying down in the MR scanner and standing positions.
- The research concludes that tarsal kinematics can differ based on posture, highlighting the need to consider muscle activity, hip positioning, and precise loading points in future evaluations.
Article Abstract
Magnetic resonance (MR) imaging is becoming increasingly important in the study of foot biomechanics. Specific devices have been constructed to load and position the foot while the subject is lying supine in the scanner. The present study examines the efficacy of such a newly developed device in replicating tarsal kinematics seen during the more commonly studied standing loading conditions. The results showed that although knee flexion and the externally applied load were carefully controlled, subtalar and talo-navicular joint rotations while lying during MR imaging and when standing (measured opto-electrically with markers attached to intracortical pins) did not match, nor were they systematically shifted. Thus, the proposed MR protocol cannot replicate tarsal kinematics seen during upright standing. It is concluded that specific foot loading conditions have to be considered when tarsal kinematics are evaluated. Improved replication of tarsal kinematics in different postures should comprehensively consider muscle activity, a fixed hip position, and a well-defined point of load application.
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| http://dx.doi.org/10.1515/BMT.2007.049 | DOI Listing |
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