OBJECTIVE: To investigate the repairing method of inguinal scar contracture deformity in children with transpositional fasciocutaneous flap of anterior-medial side of thigh. METHODS: From August 1989 to August 1999, 33 cases with inguinal scar contracture deformity were adopted in this study. Among them, there were 26 males and 7 females, aged from 3 to 11 years old. The transpositional fasciocutaneous flap consisted of a huge tongue-shape flap with a pedicled triangular flap between the edge of skin defect and the above tongue-shape flap. The maximal size of the transpositional fasciocutaneous flap was 18 cm x 10 cm and the minimal size was 13 cm x 8 cm, the transpositional angle was 60 degrees to 80 degrees. During operation, the tongue-shape flap was used to repair the inguinal region and the triangular flap was used to repair the donor site in one stage. RESULTS: All the flaps survived. The function and appearance of perineum were satisfactory. CONCLUSION: The transpositional fasciocutaneous flap is suitable for repairing the inguinal scar contracture deformity in children, and skin graft is unnecessary.
To explore the feasibility of applying magnetic stimulation technology to the movement control of animal robots, the influence of coil radius, number of turns and other factors on the intensity, depth and focus of magnetic stimulation was simulated and analyzed for robot pigeons. The coil design scheme was proposed. The coil was placed on the head and one of the legs of the pigeon, and the leg electromyography (EMG) was recorded when magnetic stimulation was performed. Results showed that the EMG was significantly strengthened during magnetic stimulation. With the reduction of the output frequency of the magnetic stimulation system, the output current was increased and the EMG was enhanced accordingly. Compared with the brain magnetic stimulation, sciatic nerve stimulation produced a more significant EMG enhancement response. This indicated that the magnetic stimulation system could effectively modulate the functions of brain and peripheral nerves by driving the coil. This study provides theoretical and experimental guidance for the subsequent optimization and improvement of practical coils, and lays a preliminary theoretical and experimental foundation for the implementation of magnetic stimulation motion control of animal robots.