Modelling of forefoot injuries caused by brake pedal loading – a finite element analysis case study

Introduction Lower extremity injuries, in particular the foot/ankle are one of the most common in automotive crashes.[1] Although not life threatening, they can lead to long term medical complications or permanent disability[2]. In most cases foot and/or ankle fractures are caused during frontal automotive crashes, while the driver attempts an emergency brake and the foot is subject to crash loading [3]. In these cases, fractures of the forefoot, in particular the metatarsals are very common [4] and range from simple fractures to severe crush injuries [5]. The location of metatarsal fractures in a car crash victim can be dictated by the loading pattern [5]. However, there is little information about whether the pedal has an effect on the mechanism or extent of injury. In order to evaluate the effect of brake pedal loading on the injury tolerance of the metatarsal, a computer based finite element analysis was performed to assess the regional capabilities in terms of loading transmission around the forefoot. Methods A Finite Element (FE) model of the foot and ankle was developed from a 3D reconstruction of CT images [6] of a female subject using Simpleware (Simpleware Ltd) segmentation software. The model was then imported into ANSYS Workbench for FE analysis (ANSYS Academic Research, Release 14.0). Material properties for the analysis were assumed to be homogenous and linearly isotropic. The cortical and simple ligamentous structures attaching the bones together were modelled. Variable pedal forces obtained from automobile crash data were applied to the forefoot region (i.e. ball of the foot) of the model, and the loading patterns of stress were analysed (Figure 1).