ObjectiveTo investigate the operative method of repairing soft tissue defect of the thumb with modified radial dorsal fasciocutaneous flap and its effectiveness.MethodsBetween June 2015 and December 2016, 15 patients with volar or dorsal defects of the thumb were treated with modified radial dorsal fasciocutaneous flaps which distal pedicles were cut off. Of 15 cases, 11 were male and 4 were female, aged 35-70 years (mean, 46 years). The causes of injury included crush injury in 12 cases and avulsion injury in 3 cases. Because all patients had volar or dorsal defects of the thumb which were accompanied by tendon or bone exposure, they had no condition or desire to replant. There were 12 cases of volar defect of thumb and 3 cases of dorsal defect. The area of defects ranged from 2.0 cm×1.2 cm to 3.0 cm×2.5 cm. The time between injury and operation was 16 hours to 2 days (mean, 30.4 hours). The radial dorsal fascio-cutaneous flaps of 2.3 cm×1.5 cm to 3.3 cm×2.8 cm in size were adopted to repair defects. The donor sites were directly sutured.ResultsAll flaps survived, and no severe swelling or tension blister occurred. The donor sites and wounds healed by first intention. All patients were followed up 3-12 months (mean, 6 months). The color and texture of the grafted flaps were similar to those of normal skin, with no bloated appearance. According to total active motion standard at last follow-up, the finger function was excellent in 8 cases and good in 7 cases.ConclusionModified radial dorsal fasciocutaneous flap of the thumb is a reliable flap with easy dissection and less trauma in repair of soft tissue defects of the thumbs, and satisfactory clinical outcome can be obtained.
ObjectiveTo evaluate the effectiveness of indirect fixation of the 3rd tarsometatarsal joint in the treatment of high-energy Lisfranc injury.MethodsBetween February 2015 and February 2019, 15 patients with high-energy Lisfranc injury were treated. There were 12 males and 3 females with an average age of 44.8 years (range, 29-73 years). The average time from injury to admission was 8.8 hours (range, 2-28 hours). According to Myerson classification, there were 6 cases of type A, 4 cases of type B2, 1 case of type C1, and 4 cases of type C2; 8 cases were open injury. The 3rd tarsometatarsal joint was injured in all patients, including intact intermetatarsal ligament in 7 cases, the 2nd-3rd intermetatarsal ligament injury in 6 cases, the 3rd-4th intermetatarsal ligament injury in 1 case, and the 2nd-3rd-4th intermetatarsal ligament injury in 1 case. Among them, the 3rd tarsometatarsal joint was not fixed directly and indirectly fixed by stabilized the 2nd and 4th tarsometatarsal joints in 13 cases. The 3rd tarsometatarsal joint was fixed with Kirschner wire in 2 cases for 1 patient had complete injury of the intermetatarsal ligament and the other 1 had comminuted fracture of the base of the 3rd metatarsal. The reduction of fracture and dislocation was evaluated by X-ray films, focusing on the re-displacement of the 3rd tarsometatarsal joint. The effectiveness was evaluated by American Orthopaedic Foot and Ankle Society (AOFAS) score and visual analogue scale (VAS) score.ResultsThirteen of the 15 patients were followed up 12-26 months, with an average of 15.6 months. One case had superficial infection of the incision and healed after symptomatic treatment; the other incisions healed by first intention. At last follow-up, the VAS score was 0-3 (mean, 1.1) and the AOFAS score was 70-99 (mean, 87.5). Twelve patients achieved anatomical reduction and 1 patient had increased talar-first metatarsal angle and the mild forefoot abduction. During the follow-up, no loss of reduction of the 3rd tarsometatarsal joint was found, while the spontaneous fusion of the joint was observed in 2 patients.ConclusionIn high-energy Lisfranc injury, as long as the intermetatarsal ligament is not completely destroyed and the bony structure of the tarsometatarsal joint is intact, the 3rd tarsometatarsal joint does not need to be fixed routinely, the stability of the joint can be obtained indirectly by fixing the adjacent tarsometatarsal joint.
Objective To establish the finite element model of varus-type ankle arthritis and to implement the finite element mechanical analysis of different correction models for tibial anterior surface angle (TAS) in supramalleolar osteotomy. Methods A female patient with left varus-type ankle arthritis (Takakura stage Ⅱ, TAS 78°) was taken as the study object. Based on the CT data, the three-dimensional model of varus-type ankle arthritis (TAS 78°) and different TAS correction models [normal (TAS 89°), 5° valgus (TAS 94°), and 10° valgus (TAS 99°)] were created by software Mimics 21.0, Geomagic Wrap 2021, Solidworks 2017, and Workbench 17.0. The 290 N vertical downward force was applied to the upper surface of the tibia and 60 N vertical downward force to the upper surface of the fibula. Von Mises stress distribution and stress peak were calculated. Results The finite element model of normal TAS was basically consistent with biomechanics of the foot. According to biomechanical analysis, the maximum stress of the varus model appeared in the medial tibiotalar joint surface and the medial part of the top tibiotalar joint surface. The stress distribution of talofibular joint surface and the lateral part of the top tibiotalar joint surface were uniform. In the normal model, the stress distributions of the talofibular joint surface and the tibiotalar joint surface were uniform, and no obvious stress concentration was observed. The maximum stress in the 5° valgus model appeared at the posterior part of the talofibular joint surface and the lateral part of the top tibiotalar joint surface. The stress distribution of medial tibiotalar joint surface was uniform. The maximum stress of the 10° valgus model appeared at the posterior part of the talofibular joint surface and the lateral part of the top tibiotalar joint surface. The stress on the medial tibiotalar joint surface increased. Conclusion With the increase of valgus, the stress of ankle joint gradually shift outwards, and the stress concentration tends to appear. There was no obvious obstruction of fibula with 10° TAS correction. However, when TAS correction exceeds 10° and continues to increase, the obstruction effect of fibula becomes increasingly significant.