Survival rates of recent total ankle replacement (TAR) designs are lower than those of other arthroplasty prostheses. Loosening is the primary indication for TAR revisions [NJR, 2014], leading to a complex arthrodesis often involving both the talocrural and subtalar joints. Loosening is often attributed to early implant micromotion, which impedes osseointegration at the bone-implant interface, thereby hampering fixation [Soballe, 1993]. Micromotion of TAR prostheses has been assessed to evaluate the stability of the bone-implant interface by means of biomechanical testing [McInnes The geometry of the tibial and talar components of three TAR designs widely used in Europe (BOX®, Mobility® and SALTO®; NJR, 2014) was reverse-engineered, and models of the tibia and talus were generated from CT data. Virtual implantations were performed and verified by a surgeon specialised in ankle surgery. In addition to the aligned case, misalignment was simulated by positioning the talar components in 5° of dorsi- or plantar-flexion, and the tibial components in ± 5° and 10° varus/valgus and 5° and 10° dorsiflexion; tibial dorsiflexed misalignement was combined with 5° posterior gap to simulate this misalignment case. Finite element models were then developed to explore bone-implant micromotion and loads occurring in the bone in the implant vicinity.Introduction
Methods
Lateral ligament injuries of the ankle are common. They account for up to 50% of all sporting injuries. Recovery times vary, leading to time away from sport and training for the professional athlete. Predicting this time is important for the treating surgeon, the athlete and the rehabilitation team. This can be difficult as associated ankle injuries occurring at the time of the trauma may alter recovery and rehabilitation. To compare the time to return to training and sports of isolated lateral ligament injuries with more complex injuries of the ankle treated surgically and to evaluate if lateral ligament repair is safe and effective in the professional athlete. Study design: Case series; level of evidence 4Background
Aim
Surgical approaches to the dorsum of the foot are common for management of midfoot fracture dislocations and arthritis. The anatomy can be difficult to identify and neurovascular injury can be a serious complication. Extensor hallucis brevis (EHB) is a consistent and easily identifiable structure encountered in these approaches. This study assesses the close relationship of the EHB musculotendinous junction to the neurovascular bundle for use as a reliable landmark. The relationship of the medial branch of the deep peroneal nerve (DPN) in the dorsum of the foot to the EHB tendon was examined by dissection of ten adult cadaveric feet preserved in formalin. Using a dorsal approach, the anatomy of the DPN neurovascular bundle was studied relative to its neighbouring structures. Local institutional review board approval was obtained.Introduction
Method
Fifth metatarsal fractures are a common injury suffered by professional footballers. It is frequently reported in the media that such an injury will result in a 6-week absence from play. The purpose of this study was to assess frequency of media reporting of fifth metatarsal fractures, the time that is predicted by the media before the player will return to soccer and the actual time taken for the player to return to play. Internet search engines identified 40 professional footballers that suffered 49 fifth metatarsal fractures between 2001 and 2011. Information was collected from various media and team websites, match reports, photography and video evidence to provide data regarding the mechanism of injury, playing surface conditions, frequency of fractures per season, fracture treatment, estimated amount of time to be missed due to the injury and time taken to return to play.Introduction
Methods
