Biomechanical Assessment of Syndesmotic and Deltoid Ligament Strain in Pronation-External Rotation Type Ankle Injuries by Musculoskeletal Computer Simulation

Ola Saatvedt; Mohammad Amin Shayestehpour; Øystein Bjelland; Martin G Gregersen; Håvard Furunes; Marius Molund

doi:10.1177/24730114261423185

Biomechanical Assessment of Syndesmotic and Deltoid Ligament Strain in Pronation-External Rotation Type Ankle Injuries by Musculoskeletal Computer Simulation

Foot Ankle Orthop. 2026 Mar 6;11(1):24730114261423185. doi: 10.1177/24730114261423185. eCollection 2026 Jan.

Authors

Ola Saatvedt^{1

2}, Mohammad Amin Shayestehpour^{3

4}, Øystein Bjelland^{4

5}, Martin G Gregersen^{2

6}, Håvard Furunes^{2

7}, Marius Molund³

Affiliations

¹ Division of Orthopaedic Surgery, Oslo University Hospital, Norway.
² University of Oslo Faculty of Medicine, Oslo, Norway.
³ Department of Orthopaedic Surgery, Østfold Hospital Trust, Grålum, Norway.
⁴ Department of ICT and Natural Sciences, Norwegian University of Science and Technology, Ålesund, Norway.
⁵ Department of Research and Innovation, Møre and Romsdal Hospital Trust, Ålesund, Norway.
⁶ Department of Physical Medicine and Rehabilitation, Østfold Hospital Trust, Grålum, Norway.
⁷ Department of Orthopedic Surgery, Innlandet Hospital Trust Gjøvik Hospital, Gjovik, Norway.

Abstract

Background: Suprasyndesmotic ankle fractures, commonly resulting from pronation-external rotation (PER) mechanisms, are traditionally associated with disruption of the syndesmotic ligaments, a medial malleolus fracture or complete deltoid ligament rupture. However, recent imaging and clinical studies suggest that key stabilizing ligaments may remain intact in certain cases, potentially affecting talocrural stability. This pilot study aims to evaluate modelled ligament tension patterns in PER injuries using a validated musculoskeletal computer simulation model.

Methods: A musculoskeletal model of the ankle joint was developed using the AnyBody Modeling System (version 7.4), incorporating detailed anatomical structures and ligament biomechanics. The PER mechanism was simulated by applying external rotation (0-50 degrees) with the foot fixed, and ligament tensional forces was recorded for the deltoid and syndesmotic complexes. Because of limitations in the computer model, a fibular fracture was not simulated. Strain patterns were analysed across simulation steps to assess the sequence and magnitude of ligament loading.

Results: The anterior and superficial deltoid ligaments (tibionavicular, deep anterior tibiotalar, tibiospring, and tibiocalcaneal) and the anterior inferior tibiofibular ligament (AITFL) demonstrated early and substantial increases in tension. Conversely, the deep posterior tibiotalar ligament (dPTTL) and posterior inferior tibiofibular ligament (PITFL) showed minimal strain during the majority of the simulation, suggesting they may remain intact in a subset of PER injuries.

Conclusion: In a computer-simulated pronation-external rotation injury mechanism, the observed tensional force acting on the posterior inferior tibiofibular ligament and the deep posterior tibiotalar ligament is substantially lower compared to the remaining ligaments of the syndesmotic and deltoid complex. The study highlights the potential of a of a novel computer-based ankle/foot model as an alternative to traditional in vitro biomechanical studies.

Clinical relevance: This study finds that in a simulated pronation-external rotation injury to the ankle, key stabilizing ligaments show low tensional forces, suggesting they might be spared from complete rupture. These findings challenge traditional views of complete ligament disruption in PER injuries, and may question the injury cascade originally described by Lauge-Hansen. Additionally, it highlights the use of computer simulation as an alternative to traditional biomechanical research and offers new opportunities for hypothesis generation, improving diagnosis, and injury classification.

Keywords: Lauge-Hansen; ankle fracture; biomechanics; deltoid ligament.