Objective To summarize the clinical effects of the repairing methods for deep wounds of the foot and ankle. Methods From March 2002 to June 2006, 49 patients with skin and deep tissue defects of the foot and ankle underwent the repairing treatment. Of them, 36 were males and 13 were females, aged 16 to 67 years( 39 years on average). The causes of injuries included mangled injury in 24 cases, high fall injury in 9 cases, cut injury in 7 cases, malignant soft tissue tumor in 5 cases, decubital ulcer in 2 cases, and electric burn in 2 cases. Of the 49 cases, 19 were in left side and 30 in right side. The defect size of skin ranged from 3 cm×2 cm to 20 cm×15 cm and deep tissue injuries were accompanied by defects of tendon and ligament in 24 cases, by damage of joint in 12 cases, and by bone defect in 9 cases, and 35 of them had infections, and 2 of them had diabetes of stage 2. The time between the injury and surgery ranged from 4 hours to 1 year.The wounds were repaired separately by local flap(3 cm×3 cm to 6 cm×4 cm) in 15 cases, local island flap(8 cm×5 cm to 12 cm×7 cm) in 25 cases, free flap(15 cm×11 cm to 24 cm×17 cm) in 4 cases, and cross leg flap(5 cm×4 cm to 8 cm×6 cm) in 5 cases. In 24 cases of defects of tendon and ligament, 15 underwent the reconstruction in one-stage operations,9 in two-satge operation.In 9 cases accompanied by bone defect, twostage bone grafting (12-64 g) was given after wound healed. Results All of the 49 flaps survived. Fortysix healed by the first intention and 3 with distal edge necrosis healed after skin grafting. Two patients with sinus formation healed after 68 months of dressing change. All the cases were followed up 6 months to 3 years, and all the flaps were well developed, the functions of the foot and ankle were satisfactory. Conclusion It can get an excellent result of appearance and function recovery repairing deep wounds of the foot and ankle with proper flaps in earlier time.
Objective To explore a suitable repairing method for skin defects of the foot and ankle, and to evaluate the therapeutic effects of the different repairing methods. Methods From January 2000 to October 2005, 36 patients with skin defects of the foot and ankle underwentthe repairing treatment, of whom 35 were males and 1 was female, aged 5-62 years, averaged 38 years. Of the 36 patients, 12 had an injury by a machine, 22 had a traffic accident, 1 had an infection, and 1 had a cold injury. And the injuries involved the dorsum of the foot, heel, forefoot, and medial or lateral malleolus. The injuries were respectively treated by 2 different repairing methods, the repair with the coverage by the lateral supramalleolar flaps and the repair with the coverage by the reverse sural neurocutaneous flaps. The skin defectsranged in area from 5 cm×4 cm to 20 cm×10 cm. The lateral supramalleolar flapwas used in 15 patients (15 flaps) with a flap area of 5 cm×4 cm-15 cm×8 cm,and the reverse sural neurocutaneous flap was used in 21 patients (22 flaps) with a flap area of 6 cm×4 cm20 cm×10 cm. We retrospectively observed the therapeutic results and compared the success rates of the two methods. Results Of the 36 patients, 15 underwent the repair with the coverage by 15 lateral supramalleolar flaps; 10 achieved a complete survival of the flaps, 2 developed an epidermal necrosis over the distal part, and 3 developed a complete necrosis.The other 21 patients underwent the repair with the coverage by 22 reverse sural neurocutaneous flaps. Of the 22 flaps, 21 had a complete survival, and only 1 failed to survive. The comparison revealed that there was no difference in the color, texture, and contour of the flaps between the 2 repaired groups. And the patients in the 2 groups were equally satisfied with the repairing treatments. The sensation of the flaps recovered to S0-S1. Conclusion The repairing of the foot and ankle skin defects with the coverage by the lateral supramalleolar flaps or by the reverse sural neurocutaneous flaps can achieve a similar good therapeutic result. However, the repair with the lateral supramalleolarflaps is more suitable for the skin defect of a smaller area over the medial orlateral malleolus, or the proximal dorsum of the foot; the repair with the reverse sural neurocutaneous flaps is more suitable for the skin defect of a larger area over the foot and ankle without serious destruction of the malleolar arterial rete.
ObjectiveTo explore the application value of digital subtraction angiography (DSA) in repairing foot and ankle wounds with posterior tibial arterial perforator flaps. MethodsBetween January 2010 and May 2014, 12 cases of foot and ankle wounds were repaired using posterior tibial arterial perforator flaps. There were 7 males and 5 females with an average age of 36 years (range, 22-54 years). The causes were machine injury in 2 cases, falling injury in 3 cases, and traffic accident injury in 7 cases. The disease duration ranged from 7 to 45 days (mean, 16 days). The size of wound ranged from 6 cm×4 cm to 10 cm×5 cm. Preoperative DSA was performed to observe the orientation and distribution of the posterior tibial arterial perforator and the relationship between perforator vessels. Correspondently, the flaps were designed and harvested. The size of flap ranged from 7 cm×5 cm to 11 cm×6 cm. The donor sites were repaired with skin grafts. ResultsPosterior tibial arterial perforator vessels send out ascending branches and descending branches while going down in the superficial layer. All branches were connected to form vertical chain-form anastamosis, and its orientation was consistent with limb vertical axis. According to DSA results, the flaps were designed and harvested easily. All flaps survived after operation. Meanwhile, wounds healed by first intention. All skin grafts at donor site survived. All patients were followed up 6 months. The flaps had good appearance, color, and texture. No ulcer was found. Affected feet had normal walking function. ConclusionThe size, distribution, and chain-form anastamosis condition of the posterior tibial arterial perforator vessels can be accurately observed by DSA, which provides imaging evidence for harvesting posterior tibial arterial perforator flaps and improves the success rate for repairing foot and ankle wounds.
Objective To evaluate the short-term effectiveness of Ilizarov technique combined with steel needle internal fixation in treating Charcot neuroarthropathy (CN) of the foot and ankle. Methods Between June 2020 and December 2023, 12 patients with Eichenholtz stage Ⅲ CN of the foot and ankle were treated with Ilizarov technique and steel needle internal fixation. There were 9 males and 3 females with an average age of 48.6 years (range, 19-66 years). The disease duration ranged from 1 to 16 months (mean, 6.8 months). Ankle joint involvement predominated in 7 cases, while midfoot involvement occurred in 5 cases; 3 cases presented with skin ulceration and soft tissue infection. Preoperative American Orthopedic Foot and Ankle Society (AOFAS) score was 31.2±9.0, 36-Item Short-Form Health Survey (SF-36)-Physical Component Summary (PCS) score was 32.6±6.8, and Mental Component Summary (MCS) score was 47.8±8.4. Postoperative assessments included wound healing, regular X-ray film/CT evaluations of fusion status, and effectiveness via AOFAS and SF-36-PCS, MCS scores. ResultsAll operations were successfully completed without neurovascular complication. Two patients experienced delayed wound healing requiring intervention, and the others achieved primary healing. All patients were followed up 15-43 months (mean, 23.3 months). Imaging confirmed successful joint fusion within 13-21 weeks (mean, 16.8 weeks). At last follow-up, the AOFAS score was 72.5±6.4, and the SF-36-PCS and MCS scores were 63.2±8.4 and 76.7±5.3, respectively, all of which improved compared to preoperative levels, with significant differences (P<0.05). Conclusion Ilizarov technique combined with steel needle internal fixation effectively restores walking function and achieves satisfactory short-term effectiveness in CN of the foot and ankle.
Objective To evaluate the clinical outcomes of free perforator flaps combined with skin graft for reconstruction of ankle and foot soft tissue defects. Methods Between June 2014 and October 2015, 20 cases of ankle and foot soft tissue defects were treated. There were 16 males and 4 females, aged from 19 to 61 years (mean, 43.3 years). Injury was caused by traffic accident in 7 cases, by crashing in 9 cases, and machine twist in 4 cases. The locations were the ankle in 6 cases, the heel in 3 cases, the dorsum pedis in 4 cases, and the plantar forefoot in 7 cases of avulsion injury after toes amputation. The size of wound ranged from 15 cm×10 cm to 27 cm×18 cm. The time from injury to treatment was from 11 to 52 days (mean, 27 days). The anterolateral thigh perforator flap was used in 11 cases, thoracodorsal antery perforator flap in 3 cases, medial sural artery perforator flap in 4 cases, deep inferior epigastric perforator flap in 1 case, and anteromedial thigh perforator flap in 1 case, including 5 chimeric perforator flaps, 5 polyfoliate perforator flaps, 3 flow-through perforator flaps, and 3 conjoined perforator flaps. The size of the perforator flap ranged from 10.0 cm×6.5 cm to 36.0 cm×8.0 cm, the size of skin graft from 5 cm×3 cm to 18 cm×12 cm. Results Venous crisis occurred in 2 flaps which survived after symptomatic treatment; 18 flaps survived successfully and skin grafting healed well. The follow-up time ranged 4-18 months (mean, 8.3 months). The flaps had good appearance, texture and color, without infection. The patients could walk normally and do daily activities. Only linear scars were observed at the donor sites. Conclusion Free perforator flap can be used to reconstruct defects in the ankle and foot, especially in the weight-bearing area of the plantar forefoot. A combination of free perforator flap and skin graft is ideal in reconstruction of great soft tissue defects in the ankle and foot.
The technical deficiencies in traditional medical imagining methods limit the study of in vivo ankle biomechanics. A dual fluoroscopic imaging system (DFIS) provides accurate and non-invasive measurements of dynamic and static activities in joints of the body. This approach can be used to quantify the movement in the single bones of the ankle and analyse different morphological and complex bone positions and movement patterns within these organs and has been widely used in the field of image diagnosis and evaluation of clinical biomechanics. This paper reviews the applications of DFIS that were used to measure the in vivo kinematics of the ankle in the field of clinical and sports medicine. The advantages and shortcomings of DFIS in the practical application are summarised. We further put forward effective research programs for understanding the movement as well as injury mechanism of the ankle in vivo, and provide constructive research direction for future study.
Objective To review the current research progress of three-dimensional (3-D) printing technique in foot and ankle surgery. Methods Recent literature associated with the clinical application of 3-D printing technique in the field of medicine, especially in foot and ankle surgery was reviewed, summarized, and analyzed. Results At present, 3-D printing technique has been applied in foot and ankle fracture, segmental bone defect, orthosis, corrective surgery, reparative and reconstructive surgery which showed satisfactory effectiveness. Currently, there are no randomized controlled trials and the medium to long term follow-up is necessary. Conclusion The printing materials, time, cost, medical ethics, and multi-disciplinary team restricted the application of 3-D printing technique, but it is still a promising technique in foot and ankle surgery.