Effects of ligament sectioning on the kinematics of the distal tibiofibular syndesmosis: A radiostereometric study of 10 cadaveric specimens based on presumed trauma mechanisms with suggestions for treatment

Background Syndesmotic injuries of the ankle without fractures can result from external rotation, abduction and dorsiflexion injuries. Kinematic studies of these trauma mechanisms have not been performed. We attempted to describe the kinematics of the tibiofibular joint in cadaveric specimens using...

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Bibliographic Details
Published in:Acta orthopaedica 2006, Vol.77 (3), p.531-540
Main Authors: Beumer, Annechien, Valstar, Edward R, Garling, Eric H, Niesing, Ruud, Ginai, Abida Z, Ranstam, Jonas, Swierstra, Bart A
Format: Article
Language:English
Subjects:
Aged
Aged, 80 and over
Ankle Injuries - physiopathology
Ankle Injuries - surgery
Biomechanical Phenomena
Bone Screws
Cadaver
Clinical Medicine
Fibula - physiopathology
Humans
Joint Dislocations - physiopathology
Joint Instability - physiopathology
Klinisk medicin
Ligaments, Articular - physiopathology
Medical and Health Sciences
Medicin och hälsovetenskap
Models, Biological
Orthopedics
Ortopedi
Range of Motion, Articular - physiology
Rotation
Tibia - physiopathology
Weight-Bearing - physiology
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Summary:Background Syndesmotic injuries of the ankle without fractures can result from external rotation, abduction and dorsiflexion injuries. Kinematic studies of these trauma mechanisms have not been performed. We attempted to describe the kinematics of the tibiofibular joint in cadaveric specimens using radiostereometry after sequential ligament sectioning, and resulting from different trauma mechanisms and axial loading, in order to put forward treatment guidelines for the different types of syndesmotic injuries. Methods We assessed the kinematics of the distal tibiofibular joint in fresh-frozen cadaveric specimens using radiostereometry in the intact situation, and after alternating and sequential sectioning of the distal tibiofibular and anterior deltoid ligaments. To assess which of the known trauma mechanisms would create the largest displacements at the syndesmosis, the ankle was brought into the following positions under an axial load that was comparable to body weight (750 N): neutral, dorsiflexion, external rotation, abduction, and a combination of external rotation and abduction. Results In the neutral position, the largest displacements of the fibula consisted of external rotation and posterior translation. Loading of the ankle with 750 N did not apparently increase or decrease the displacements of the fibula, but gave a larger variety of displacements. In every position, sectioning of a ligament resulted in some fibular displacement. Sectioning of the anterior tibiofibular ligament (ATiFL) invariably resulted in external rotation of the fibula. Additional sectioning of the anterior part of the deltoid ligament (AD) gave a larger variety of displacements. In general, sectioning of the posterior tibiofibular ligament (PTiFL) gave the smallest displacements. Combined sectioning of the ATiFL and the PTiFL resulted in a larger variety of displacements in the neutral position. Sectioning of the AD together with the ATiFL and PTiFL resulted in tibiofibular displacements in the neutral situation exceeding the maximum values found in the intact situation, the most important being fibular external rotation. Interpretation Sectioning of the ATiFL results in mechanical instability of the syndesmosis. Of all trauma mechanisms, external rotation of the ankle resulted in the largest and most consistent displacements of the fibula relative to the tibia found at the syndesmosis. Based on our findings and the current literature, we recommend that patients with isolat
ISSN:1745-3674
1745-3682
1745-3682
DOI:10.1080/17453670610012557