Susanne Rein1, Elisabet Hagert2, Wolfgang Schneiders3, Armin Fieguth4, Hans Zwipp3. 1. Department of Orthopaedic and Trauma Surgery, University Hospital "Carl Gustav Carus," Dresden, Germany Department for Hand Surgery, Rhön-Klinikum, Germany susanne.rein@web.de. 2. Department of Clinical Science and Education, Karolinska Institutet, Hand & Foot Surgery Center, Stockholm, Sweden. 3. Department of Orthopaedic and Trauma Surgery, University Hospital "Carl Gustav Carus," Dresden, Germany. 4. Institute of Legal Medicine, University of Hannover, Hannover, Germany.
Abstract
BACKGROUND: Various ankle ligaments have different structural composition. The aim of this study was to analyze the morphological structure of ankle ligaments to further understand their function in ankle stability. METHODS: One hundred forty ligaments from 10 fresh-frozen cadaver ankle joints were dissected: the calcaneofibular, anterior, and posterior talofibular ligaments; the inferior extensor retinaculum, the talocalcaneal oblique ligament, the canalis tarsi ligament; the deltoid ligament; and the anterior tibiofibular ligament. Hematoxylin-eosin and Elastica van Gieson stains were used for determination of tissue morphology. RESULTS: Three different morphological compositions were identified: dense, mixed, and interlaced compositions. Densely packed ligaments, characterized by parallel bundles of collagen, were primarily seen in the lateral region, the canalis tarsi, and the anterior tibiofibular ligaments. Ligaments with mixed tight and loose parallel bundles of collagenous connective tissue were mainly found in the inferior extensor retinaculum and talocalcaneal oblique ligament. Densely packed and fiber-rich interlacing collagen was primarily seen in the areas of ligament insertion into bone of the deltoid ligament. CONCLUSIONS: Ligaments of the lateral region, the canalis tarsi, and the anterior tibiofibular ligaments have tightly packed, parallel collagen bundles and thus can resist high tensile forces. The mixed tight and loose, parallel oriented collagenous connective tissue of the inferior extensor retinaculum and the talocalcaneal oblique ligament support the dynamic positioning of the foot on the ground. The interlacing collagen bundles seen at the insertion of the deltoid ligament suggest that these insertion areas are susceptible to tension in a multitude of directions. CLINICAL RELEVANCE: The morphology and mechanical properties of ankle ligaments may provide an understanding of their response to the loads to which they are subjected.
BACKGROUND: Various ankle ligaments have different structural composition. The aim of this study was to analyze the morphological structure of ankle ligaments to further understand their function in ankle stability. METHODS: One hundred forty ligaments from 10 fresh-frozen cadaver ankle joints were dissected: the calcaneofibular, anterior, and posterior talofibular ligaments; the inferior extensor retinaculum, the talocalcaneal oblique ligament, the canalis tarsi ligament; the deltoid ligament; and the anterior tibiofibular ligament. Hematoxylin-eosin and Elastica van Gieson stains were used for determination of tissue morphology. RESULTS: Three different morphological compositions were identified: dense, mixed, and interlaced compositions. Densely packed ligaments, characterized by parallel bundles of collagen, were primarily seen in the lateral region, the canalis tarsi, and the anterior tibiofibular ligaments. Ligaments with mixed tight and loose parallel bundles of collagenous connective tissue were mainly found in the inferior extensor retinaculum and talocalcaneal oblique ligament. Densely packed and fiber-rich interlacing collagen was primarily seen in the areas of ligament insertion into bone of the deltoid ligament. CONCLUSIONS: Ligaments of the lateral region, the canalis tarsi, and the anterior tibiofibular ligaments have tightly packed, parallel collagen bundles and thus can resist high tensile forces. The mixed tight and loose, parallel oriented collagenous connective tissue of the inferior extensor retinaculum and the talocalcaneal oblique ligament support the dynamic positioning of the foot on the ground. The interlacing collagen bundles seen at the insertion of the deltoid ligament suggest that these insertion areas are susceptible to tension in a multitude of directions. CLINICAL RELEVANCE: The morphology and mechanical properties of ankle ligaments may provide an understanding of their response to the loads to which they are subjected.
Authors: Miriam De Dea; Constantinos L Loizou; Georgina M Allen; David J Wilson; Nick Athanasou; Yoshinobu Uchihara; Paul Cooke; Thomas Cosker Journal: Br J Radiol Date: 2016-12-20 Impact factor: 3.039
Authors: Joe A I Prinold; Claudia Mazzà; Roberto Di Marco; Iain Hannah; Clara Malattia; Silvia Magni-Manzoni; Maurizio Petrarca; Anna B Ronchetti; Laura Tanturri de Horatio; E H Pieter van Dijkhuizen; Stefan Wesarg; Marco Viceconti Journal: Ann Biomed Eng Date: 2015-09-15 Impact factor: 3.934