Introduction. There is limited evidence assessing the effect of the Ankle Foot Orthosis (AFO) on gait improvements in diplegic cerebral palsy. In particular, the effect of the AFO on vertical forces during gait has not been reported. Appropriate vertical ground reaction forces are crucial in enabling children with CP to walk efficiently. This study investigated the effect of AFO application on the vertical forces in gait, particularly the second vertical peak in force (FZ2) in late stance. The force data was compared with the barefoot walk. Patients and Methods. A retrospective analysis of nineteen children (8M,11F) who met inclusion criteria of a diagnosis of spastic diplegic CP, ability to walk independently barefoot and also using bilateral rigid AFOs were included. Gait data were acquired using the Vicon-Nexus ® motion-capture. Resulting ground reaction force data were recorded. Appropriate statistical methods assessed significance between barefoot and AFO data. Results. 68.4% of subjects experienced increase in FZ2 magnitude in left leg and 63.2% experienced objective increase in right leg after AFO application. Mean increased in FZ2 was 5.33N in left leg and 8.53 N in right leg. Results indicate significant improvement in amplitude of FZ2 generation with AFO application, significantly increased gait efficiency, and a significantly normalized pattern of vertical force produced during gait. Discussion. The AFO is effective in enabling children with diplegic CP to achieve efficient gait patterns. Our study is the first to our knowledge that focuses on the effect of AFO on specifically vertical ground reaction force produced in gait

Introduction. The fracture healing outcome is often evaluated via ex vivo testing of the fracture callus. However, there is only a small time window, where the callus stiffness is significantly different, i.e. a delayed fracture healing might be undetected if the time point of sacrifice is improper. The aim of this study was to develop an in vivo monitoring concept, which allows determining the fracture callus stiffness in vivo over the whole healing time in rats. Hypothesis. The fracture callus stiffness can be monitored by measuring the deformation of the external fixation device during gait analysis at several healing time points. Materials & Methods. The right femurs of sixteen wistar rats were osteotomized and stabilized with an external fixation device (stiffness 119 N/mm or 32 N/mm). The fixator body was instrumented with a stain gauge to measure the deformation. Gait analysis was performed once per week in a gait wheel equipped with a ground reaction force measuring device. Results. The deformation of the fixation devices decreased over the healing time indicating an increase of the callus stiffness. The flexible fixated group showed a later increase of the callus stiffness indicating a delay in fracture healing. Discussion & Conclusion. Measuring the deformation of the fixator and gait analysis provides a powerful tool to monitor the fracture healing process in rats. With this, it is possible to detect a delayed fracture healing process more reliable than with ex vivo analyses