In this study the development of a three-dimensional finite element (FE) model of the human ankle/foot complex is described. This model depicts the primary elements of a 50th percentile human ankle. It includes all the bones of the foot up to the distal tibia/fibula. It also contains the soft tissues of the plantar surface of the foot along with most of the ankle joint ligaments and retinacula. A plate with various initial velocities of 5, 7.5 and 10 mph is impacted at the plantar surface of the foot. The aim is to calibrate the model. The model is strictly stabilized by the intrinsic anatomical geometry and the ligamentous structure. It demonstrates to a great extent its capacity to replicate the dynamic response. Global responses of output acceleration and force time histories are obtained and compared reasonably well with experimental data. The ankle model is viewed as a first step in a complicated process leading towards: (1) the ability to assess hard and soft tissue injury; and (2) towards the development of an enhanced ankle injury criterion. (A)
Abstract