Objective To investigate the effectiveness of the lower abdominal conjoined flap with bilateral superficial inferior epigastric arteries (SIEA) for repairing the large soft tissue defects on the foot and ankle. Methods The clinical data of 18 patients with large soft tissue defects on foot and ankle treated between October 2017 and January 2020 were retrospectively analyzed, including 12 males and 6 females; the age ranged from 25 to 62 years, with a median age of 35 years. The causes of injury included machine injury in 9 cases, traffic accident injury in 5 cases, cutting injury in 2 cases, and electric injury in 2 cases. All wounds were accompanied by exposure of blood vessels, tendons, bones, and joints. Wound located at ankle in 8 cases, dorsum of foot in 6 cases, and sole in 4 cases. In the emergency department, complete debridement (the defect area after debridement was 15 cm×10 cm to 25 cm×16 cm) and vacuum sealing drainage on the wound was performed. The time from debridement to flap repair was 3-10 days, with an average of 5 days. According to the defect location and scope, the lower abdominal conjoined flap with bilateral SIEA was prepared. The size of the flap ranged from 15 cm×10 cm to 25 cm×16 cm. The length of vascular pedicle was 4.5-7.5 cm, with an average of 6.0 cm; the thickness of the flap was 0.5-1.2 cm, with an average of 0.8 cm. The abdominal donor site was closed in one-stage. Results One flap was altered as the conjoined flap with the bilateral superficial circumflex iliac artery because of the absence of the SIEA in one side. Except for 1 case of skin flap with distal necrosis, the flap healed after two-stage skin grafting repair; the rest skin flaps survived, and the wounds of the donor and recipient sites all healed by first intention. All patients were followed up 12-28 months, with an average of 16 months. The skin flap had a satisfactory appearance and soft texture, without abnormal hair growth or obvious pigmentation. Only linear scars were left at the donor site, and no complication such as abdominal hernia occurred. The foot and ankle function was satisfactory. At last follow-up, the American Orthopaedic Foot and Ankle Society (AOFAS) scores were rated as excellent in 16 cases and good in 2 cases. Conclusion The lower abdominal conjoined flap with bilateral SIEA is an ideal flap for repairing large defects of foot and ankle with less morbidity scarcely, which ascribed to its ease of dissection, adjustable thinness, and concealed donor site, as well as the flexible perforator match.
ObjectiveTo investigate the effectiveness of free transverse gracilis myocutaneous flap for soft tissue defects of foot and ankle. Methods Between January 2017 and December 2020, 16 cases (17 feet) of soft tissue defects of foot and ankle were repaired with free transverse gracilis myocutaneous flaps. There were 10 males and 6 females, with an average age of 38 years (range, 23-60 years). There were 9 cases of left foot, 6 cases of right foot, and 1 case of bilateral feet. The causes of soft tissue defect were traffic accident injury in 3 cases, heavy object smash injury in 4 cases, machine injury in 3 cases, infection in 4 cases, electrical burn in 1 case, and synovial sarcoma after operation in 1 case. The wounds located at the distal plantar in 2 cases (2 feet), the heel and ankle in 6 cases (6 feet), the dorsum of the foot in 7 cases (8 feet), and the first metatarsophalangeal joint to the medial malleolus in 1 case (1 foot). The size of wounds ranged from 6 cm×5 cm to 18 cm×7 cm. The size of flap ranged from 11 cm×6 cm to 21 cm×9 cm. The donor site was sutured directly. Results After operation, 1 case (1 foot) of flap vascular crisis, 1 case (1 foot) of partial necrosis of the flap, and 1 case of partial dehiscence of the incision at donor site occurred, all of which healed after symptomatic treatment. The other flaps survived, and the incisions at donor and recipient sites healed by first intention. All patients were followed up 12-36 months (mean, 24 months). Except for 1 case (1 foot) of swollen flap, which underwent two-stage trimming, the other flaps had good shape and texture. All the flaps had a protective feeling. At last follow-up, Kofoed scores of foot and ankle function ranged from 73 to 98 (mean, 89.7); 13 cases were excellent, 2 cases were good, and 1 case was poor, with an excellent and good rate of 93.8%. Linear scar was formed at the donor site without adverse effect on lower limb function. ConclusionThe free transverse gracilis myocutaneous flap is an effective flap for repairing large soft tissue defects of foot and ankle due to its advantages of large excisable area, less variation of vascular anatomy, and concealment of donor site.
External fixation devices are essential tools in the field of foot and ankle reconstruction. Mastering the fundamental knowledge and skills of external fixation is crucial for the effective application of this technique. Currently, domestically produced external fixation systems for the foot and ankle can meet the needs of treating various foot and ankle traumas, deformities, and functional reconstruction. Through this special issue on “External fixation and foot and ankle reconstruction”, we provide a detailed introduction to the essential knowledge and skills that physicians must acquire to proficiently manage external fixation and foot and ankle reconstruction.
ObjectiveTo investigate clinical application of the free peroneal artery perforator flap in soft tissue defect of foot and ankle.MethodsThe clinical data of 18 patients with soft tissue defects of foot and ankle who were repaired with free peroneal artery perforator flaps between March 2019 and March 2020 were retrospectively analyzed. Among them, there were 11 males and 7 females; the age ranged from 21 to 58 years, with an average age of 45 years. The defect was located in the ankle in 2 cases, in the hindfoot in 4 cases, in the midfoot in 5 cases, and in the forefoot in 7 cases. The causes of injury included 11 cases of traffic accident, 4 cases of machine injuries, 3 cases of infection and necrosis after internal fixation. The time from injury to flap repair was 12-48 days, with an average of 24 days. The range of wound was 3 cm×3 cm to 15 cm×8 cm, and the range of skin flap was 4 cm×3 cm to 16 cm×9 cm. The flap harvesting time, operation time, intraoperative blood loss, and complications were recorded; the flap survival and patient satisfaction were observed during follow-up; and the American Orthopaedic Foot and Ankle Society (AOFAS) foot function score was used to evaluate the foot function.ResultsThe flap harvesting time was 15-33 minutes (mean, 22 minutes); the operation time was 120-160 minutes (mean, 150 minutes); the intraoperative blood loss was 90-180 mL (mean, 120 mL). There were 3 cases of vascular crisis after operation, including 2 cases of arterial crisis, which survived after vascular exploration and vein graft repair; 1 case of venous crisis, partial necrosis of the skin flap, and skin grafting to cover the wound after repeated debridement. The remaining 15 skin flaps survived completely. All patients were followed up 6 months. The skin flaps were in good shape without obvious bloat. According to the AOFAS foot function score, 5 cases were excellent, 10 cases were good, and 3 cases were fair. The excellent and good rate was 83.3%.ConclusionThe free peroneal artery perforator flap is easy to harvest, the shape and size of the flap are easy to design, and it does not damage the main blood vessels of the limb. The appearance and function of the limbs are satisfactory after operation. It can be widely used in the repair of soft tissue defects of the foot and ankle.
Objective To summarize the clinical characteristics of foot and ankle deformities combined with knee and lower limb deformities and evaluate the advantages, clinical outcomes, and considerations of QIN Sihe’s surgical strategy for treating such complex deformities. Methods Between January 2022 and December 2024, 32 patients with foot and ankle deformities combined with knee and lower limb deformities were enrolled. The cohort included 23 males and 9 females, aged 10-67 years (mean, 41.1 years). The main etiologies included post-polio sequelae (20 cases) and congenital limb deformities (3 cases). Deformities were categorized as follows: equinovarus foot (12 cases), equinus foot (2 cases), equinovalgus foot (3 cases), equinus foot with swan-neck deformity (2 cases), calcaneus foot (5 cases), foot valgus (2 cases), knee flexion deformity (14 cases), genu recurvatum (4 cases), genu varum (3 cases), genu valgum (3 cases), lower limb shortening (3 cases), and lower limb external rotation (6 cases). QIN Sihe’s surgical strategies included osteotomies, tendon releases, and tendon transfers for deformity correction, followed by external fixation for residual deformity adjustment and stabilization. Outcomes were assessed using QIN Sihe’s Postoperative Evaluation Criteria for Lower Limb (Foot and Ankle) Deformity Correction and Functional Reconstruction. Results All patients were followed up 8-32 months (mean, 16.5 months). Complications included pin tract infection (1 case, 1 site), ankle pain (2 cases), delayed healing at the proximal tibial osteotomy site (1 case), and anterior talar dislocation (1 case). At last follow-up, insufficient correction of foot deformity was observed in 1 case; both knee and lower limb deformities were corrected, with only mild recurrence of knee flexion deformity in 1 case. The foot/ankle and knee joint function improved. Based on QIN Sihe’s Postoperative Evaluation Criteria for Lower Limb (Foot and Ankle) Deformity Correction and Functional Reconstruction, outcomes were rated as excellent in 30 cases and good in 2 cases, with an excellent-good rate of 100%. Conclusion Foot and ankle deformities combined with knee and lower limb deformities are complex, QIN Sihe’s surgical strategy can achieve satisfactory clinical outcomes for simultaneous correction.
ObjectiveTo investigate the feasibility and effectiveness of free popliteal artery cutaneous branch flap anastomosed with lateral tarsal artery and vein for the repair of wound on the foot and ankle by anatomical observation and clinical application. MethodsLatex was poured into the blood vessels of 8 cadavers, then perforator vessel of posterolateral upper calf was dissected, and the popliteal artery cutaneous branch flap was designed with a pedicle of 2.5 cm in length; the lateral tarsal artery of the foot was dissected, could be freed to 6 cm in length; the diameter of these vessels was measured, and the number of the accompanying veins was counted. Between March 2010 and January 2013, 13 cases of foot and ankle wounds were repaired with popliteal artery cutaneous branch flap anastomosed with lateral tarsal artery and vein. The size of flaps ranged from 6.0 cm×4.0 cm to 7.5 cm×5.5 cm. There were 11 males and 2 females, aged from 41 to 65 years (mean, 47.3 years). The causes of injury included traffic accident in 8 cases, crushing in 4 cases, and twist by machine in 1 case. The size of wounds, ranged from 5.0 cm×3.5 cm to 7.0 cm×5.0 cm. The donor sites were sutured directly. ResultsAccording to anatomical observation, the popliteal artery cutaneous branch flap was designed by using the lateral popliteal artery perforator for shaft. The vessel of the pedicle perforator flaps from the popliteal artery cutaneous branch flap matched well with the lateral tarsal artery. Clinical results: vascular crisis occurred in 2 flaps, which survived after symptomatic treatment; the other flaps survived, with primary healing of wound and incision at donor site. The patients were all followed up 5-18 months (mean, 11 months). The flap had normal color and good elasticity. Second stage operation was performed to make the flap thinner in 3 female patients because of bulky flaps. The remaining patients had no obvious fat flap. According to American Orthopaedic Foot and Ankle Society (AOFAS) score for evaluation of the ankle function at 6 months after operation, the results were excellent in 7 cases, good in 5 cases, and fair in 1 case, with an excellent and good rate of 92.3%. ConclusionFree popliteal artery cutaneous branch flap anastomosed with lateral tarsal artery and vein for the repair of wound on the foot and ankle is simple and effective. The donor site is hidden.
Objective To investigate the safety and effectiveness of using the Taylor spatial frame (TSF) based on the Ilizarov tension-stress principle for treatment of post-burn foot and ankle deformities in adults. Methods A clinical data of 6 patients with post-burn foot and ankle deformities treated between April 2019 and November 2023 was retrospectively analyzed. There was 1 male and 5 females with an average age of 28.7 years (range, 20-49 years). There were 3 cases of simple ankle equinus, 2 cases of ankle equinus, midfoot rocker-bottom foot, and forefoot pronation, and 1 case of calcaneus foot and forefoot pronation. Preoperative American Orthopedic Foot and Ankle Society (AOFAS) score was 45.3±18.2, 12-Item Short-Form Health Survey (SF-12)-Physical Component Summary (PCS) score was 34.3±7.3 and Mental Component Summary (MCS) score was 50.4±8.8. Imaging examination showed tibial-calcaneal angle of (79.8±31.5)°, calcaneus-first metatarsal angle of (154.5±45.3)°, talus-first metatarsal angle of (–19.3±35.0)°. Except for 1 case with severe deformity that could not be measured, the remaining 5 cases had talus-second metatarsal angle of (40.6±16.4)°. The deformities were fixed with TSF after soft tissue release and osteotomy. Then, the residual deformities were gradually corrected according to software-calculated prescriptions. TSF was removed after maximum deformity correction and osteotomy healing. External fixation time, brace wearing time after removing the TSF, and pin tract infection occurrence were recorded. Infection severity was evaluated based on Checketts-Otterburns grading. Joint function was evaluated using AOFAS score and SF-12 PCS and MCS scores. Patient satisfaction was assessed using Likert score. Imaging follow-up measured relevant indicators to evaluate the degree of deformity correction. Deformity recurrence was observed during follow-up. Results The external fixation time was 103-268 days (mean, 193.5 days). The mild pin tract infections occurred during external fixation in all patients, which healed after pin tract care and oral antibiotics. No serious complication such as osteomyelitis, fractures, neurovascular injury, or skin necrosis occurred. After external fixation removal, 3 cases did not wear braces, while the remaining 3 cases wore braces continuously for 6 weeks, 8 weeks, and 3 years, respectively. All patients were followed up 13.9-70.0 months, with an average of 41.7 months. During follow-up, none of the 6 patients had recurrence of foot deformity. At 1 year after operation, the AOFAS score was 70.0±18.1, SF-12-PCS and MCS scores were 48.9±4.5 and 58.8±6.4, respectively, all showing significant improvement compared to preoperative values (P<0.05). Imaging follow-up showed that all osteotomies healed, and all distraction cases achieved bony union at 6 months after stopping stretching. At 1 year after operation, tibial-calcaneal angle was (117.5±12.8)° and talus-first metatarsal angle was (–3.3±19.3)°, both showing significant improvement compared to preoperative values (P<0.05). Calcaneus-first metatarsal angle was (132.0±14.4)°, which also improved compared to preoperative values but without significant difference (P>0.05). Except for 1 case with severe deformity that could not be measured, the remaining 5 cases had talus-second metatarsal angle of (18.0±6.4)°. And there was no significant difference (P>0.05) between pre-and post-operative data of 4 patients with complete data. At 1 year after operation, 1 patient was satisfied with effectiveness and 5 patients were very satisfied. Conclusion The TSF, by applying the Ilizarov tension-stress principle for gradual distraction and multi-planar adjustment, combined with soft tissue release and osteotomy, can effectively correct foot and ankle deformities after burns, especially equinus deformity with contracture of the posterior soft tissues of the lower leg. There are still limitations in treating cases with tight, adherent scars on the dorsum of the foot that require long-distance distraction. If necessary, a multidisciplinary approach combined with microsurgical techniques can be utilized.
ObjectiveTo review the research progress on correction of severe foot and ankle deformities with digital hexapod external fixators. Methods The relevant research literature on digital hexapod external fixators at home and abroad in recent years was reviewed and analyzed. Taking Taylor spatial frame (TSF) as a representative, this article elaborates on the research progress of this technology in the treatment of severe foot and ankle deformities from aspects such as device principle, technical characteristics, clinical application, complication management, and controversial perspectives, aiming to provide theoretical references for clinical application. Results The treatment of severe foot and ankle deformities is a complex challenge in orthopedics, often involving multiple plane alignment abnormalities, muscle weakness, soft tissue contractures, and joint dysfunction. The digital hexapod external fixators (such as TSF), based on the principle of six degrees of freedom motion and combined with computer-assisted technology, enables precise correction of multi-dimensional deformities. Conclusion The digital hexapod external fixators provides a minimally invasive and efficient option for the treatment of severe foot and ankle deformities, and shows significant advantages in the treatment of complex post-traumatic deformities, neuromuscular deformities, diabetes Charcot arthropathy, and other diseases.
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 investigate the effectiveness of perforator propeller flap of lower limb in the treatment of foot and ankle defect in children. Methods The clinical data of 28 children with foot and ankle defect treated with perforator propeller flap of lower limb between January 2018 and January 2021 were retrospectively analyzed. There were 18 boys and 10 girls with an average age of 7.3 years (range, 6-14 years). There were 8 cases of traffic accident injury and 20 cases of chronic infection wound. The disease duration was 2-4 months, with an average of 2.8 months. After thorough debridement, the residual wound size ranged from 5 cm×4 cm to 9 cm×5 cm. Repairing was performed after 7-28 days of the infection in control. According to the location, size, and shape of the wound, the perforating vessels were located by ultrasonic Doppler, and the perforator propeller flap (area ranged from 6 cm×5 cm to 11 cm×6 cm) was designed and harvested to repair the wound. Flap transfer combined with free split-thickness skin graft covered the wound in 2 cases. The donor site was sutured directly (22 cases) or repaired with skin graft (6 cases). Results Twenty-six flaps survived, of which 20 cases were in primary healing, and 6 cases had epidermal necrosis at the end of small paddle, which healed after dressing change. Necrosis occurred in 2 cases due to venous crisis which healed after anterolateral femoral flap free transplantation. Primary wound healing was achieved in donor site. All 28 children were followed up 6-24 months (mean, 10.5 months). The texture, shape, and motor function of the lower limb was satisfactory. At last follow-up, the American Orthopaedic Foot and Ankle Association (AOFAS) score was 89.8±8.0, which was significantly different from the preoperative score (79.6±10.4) (t=−11.205, P<0.001); 20 cases were excellent, 6 cases were good, and 2 cases were poor, and the excellent and good rate was 92.8%. ConclusionThe perforator propeller flap of lower limb in children has its own characteristics. It is a reliable method to repair the foot and ankle defect in children.