Objective:To explore the clinical effect on the treatment of radiation induced deep ulcers in the inguinal region with ipsilateral anterolateral thigh chimeric perforator flap.Methods:From March 2020 to March 2024, retrospective analysis of 8 patients with radiation induced deep ulcers in the inguinal region were treated with ipsilateral anterolateral thigh chimeric perforator flap in the Medical Centre of Burn Plastic and Wound Repair, the First Affiliated Hospital of Nanchang University. All ulcers induced by radiation were caused by postoperative radiotherapy in the inguinal region, of which 4 were of vulvar or penile cancer, 2 of urinary tract tumour, 1 of inguinal protuberant dermatofibrosarcoma and 1 of myofibroblastic sarcoma in lower abdominal wall. The course of the radiation induced ulcer was 0.5-11.0 years, with an average of 2.9 years. The sizes of the ulcerative wound were 2.5 cm × 3.0 cm - 5.5 cm × 7.5 cm. Preoperative biopsies of the tissues around wound and pelvic CT scans were performed to preliminarily exclude a tumour recurrence or an ulcerative malignancy, as well as to confirm the depth of radiation ulcer. The wound size after debridement was 4.5 cm × 6.0 cm-13.5 cm × 19.0 cm, with a depth of 2.0-4.0 cm. An ipsilateral anterolateral thigh chimeric perforator flap was transferred to reconstruct the wound, after the wound edges were cleared from tumour through intraoperative frozen section examinations. The flaps were 5.5 cm × 7.0 cm - 14.0 cm × 20.0 cm in size, with the volumes of muscle flap at 7.0 cm × 4.0 cm × 3.0 cm - 14.0 cm × 7.0 cm × 3.0 cm. After having the deep defect at the base of wound filled with a muscle flap, the wound surface was covered by the flap. Four patients had direct suture of the donor sites and 4 received a thick skin graft of head or contralateral thigh grafting. Survival of the anterolateral thigh chimeric perforator flaps and the healing of donor sites were observed after surgery through scheduled postoperative follow-up by the visits of outpatient clinic and distant interviews via telephone, WeChat or the internet hospital.Results:One of the ipsilateral anterolateral thigh chimeric perforator flaps had venous occlusion within 24 hours after surgery. Emergency surgical exploration revealed that it was caused by a haematoma compression due to haemorrhage in the muscle flap. Further debridement, haemostasis and suture were performed, then the wound healed. The rest of 7 flaps all survived. All donor sites healed primarily. The postoperative follow-up lasted for 5-17 months with all of the 8 patients, at 8.4 months in average. Both the donor and recipient sites healed well without recurrence of radiation ulcer in the affected sites. The appearance and texture of the flaps were good, and there was no obvious functional impairment at the donor sites.Conclusion:The treatment of radiation induced deep ulcer in the inguinal region with an ipsilateral anterolateral thigh chimeric perforator flap has shown good results, without recurrence of ulcer after surgery. The appearance and texture of the affected sites are good, and there is no secondary functional impairment at the donor site.

Objective:To explore the application strategies and clinical effects of superior gluteal artery perforator tissue flaps in repairing stage Ⅳ pressure ulcers in the sacrococcygeal region.Methods:This study was a retrospective observational study. From July 2019 to April 2024, 89 patients with stage Ⅳ pressure ulcers in the sacrococcygeal region who met the inclusion criteria were admitted to the First Affiliated Hospital of Nanchang University, including 59 males and 30 females, aged 21 to 84 years. There were 89 sacrococcygeal pressure ulcers, with an area of 5.0 cm×4.0 cm-21.0 cm×21.0 cm after debridement. According to the shape, size, and depth of the wounds after debridement, combined with the elasticity and texture of the skin around the wounds, and the principle of minimizing damage to the donor area, the appropriate forms of superior gluteal artery perforator tissue flaps were cut for wound repair in the following three conditions. (1) For wounds with a round shape, an area of 5.0 cm×5.0 cm-21.0 cm×21.0 cm, and a depth of 1.0-3.5 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, bilobed superior gluteal artery perforator relay flap, and bilateral superior gluteal artery perforator rotational flap were used. (2) For wounds with an oval shape, an area of 5.0 cm×4.0 cm-18.5 cm×10.5 cm, and a depth of 1.0-3.0 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, unilateral superior gluteal artery perforator propeller flap combined with contralateral superior gluteal artery perforator V-Y advanced flap or keystone flap were used. (3) For wounds with a fusiformis shape, an area of 7.0 cm×4.0 cm-17.5 cm×6.0 cm, and a depth of 1.5-5.0 cm, the unilateral or bilateral superior gluteal artery perforator V-Y advanced flap, superior gluteal artery perforator keystone flap, or superior gluteal artery perforator keystone flap combined with gluteus maximus muscle flap were used. In this group of patients, a total of 40 superior gluteal artery perforator propeller flaps (with an resection area of 11.0 cm×6.0 cm-17.0 cm×11.0 cm), 22 superior gluteal artery perforator propeller myocutaneous flaps (with an resection area of 10.0 cm×5.0 cm-14.0 cm×8.0 cm), 7 bilobed superior gluteal artery perforator relay flaps (with a main flap resection area of 5.5 cm×5.5 cm-18.0 cm×11.5 cm and a side flap resection area of 4.5 cm×3.0 cm-11.0 cm×6.5 cm), 5 bilateral superior gluteal artery perforator rotational flaps (with a total resection area of 20.0 cm×16.0 cm-26.0 cm×21.0 cm on both sides), 14 superior gluteal artery perforator V-Y advanced flaps (with an resection area of 12.0 cm×10.0 cm-18.0 cm×18.0 cm), 13 superior gluteal artery perforator keystone flaps (with an resection area of 13.0 cm×6.5 cm-19.0 cm×18.0 cm), and 3 gluteus maximus muscle flaps (with an resection area of 8.0 cm×3.0 cm-15.0 cm×4.5 cm). The donor area wounds were all directly sutured. The survival of tissue flaps was observed and the incidence rate of delayed wound healing in the reception area was calculated, and wound healing in the donor area was observed. The appearance and texture of tissue flaps and recurrence of pressure ulcers were followed up.Results:After surgery, all bilateral superior gluteal artery perforator rotational flaps, superior gluteal artery perforator V-Y advanced flaps, superior gluteal artery perforator keystone flaps, and gluteus maximus muscle flaps survived well. There were 6 cases of delayed wound healing in the reception area after surgery, with an incidence rate of 6.7% (6/89). Two patients had incision dehiscence in the donor area wounds due to postoperative bleeding, the wounds healed after debridement, vacuum sealing drainage, and dressing change. The wounds in the donor area of the remaining patients healed well. Six patients were lost to follow-up. Eighty-three patients were followed up for 3-48 months, of whom 4 patients died. Among the remaining 79 patients, 3 cases had pressure ulcers recur due to improper nursing, while the rest of the patients had tissue flaps with good appearance and soft texture and no recurrence of pressure ulcers.Conclusions:Based on the characteristics of wound shape, size, and depth after debridement of stage Ⅳ pressure ulcers in the sacrococcygeal region, individualized selection of flap, myocutaneous flap, or a combination of flap and gluteus maximus muscle flap based on the perforating branch of the superior gluteal artery perforator can achieve good clinical repair results. The postoperative tissue flap survived well, with a good appearance, soft texture, and less recurrence of pressure ulcers.

Objective:To explore the clinical effect on the treatment of radiation induced deep ulcers in the inguinal region with ipsilateral anterolateral thigh chimeric perforator flap.Methods:From March 2020 to March 2024, retrospective analysis of 8 patients with radiation induced deep ulcers in the inguinal region were treated with ipsilateral anterolateral thigh chimeric perforator flap in the Medical Centre of Burn Plastic and Wound Repair, the First Affiliated Hospital of Nanchang University. All ulcers induced by radiation were caused by postoperative radiotherapy in the inguinal region, of which 4 were of vulvar or penile cancer, 2 of urinary tract tumour, 1 of inguinal protuberant dermatofibrosarcoma and 1 of myofibroblastic sarcoma in lower abdominal wall. The course of the radiation induced ulcer was 0.5-11.0 years, with an average of 2.9 years. The sizes of the ulcerative wound were 2.5 cm × 3.0 cm - 5.5 cm × 7.5 cm. Preoperative biopsies of the tissues around wound and pelvic CT scans were performed to preliminarily exclude a tumour recurrence or an ulcerative malignancy, as well as to confirm the depth of radiation ulcer. The wound size after debridement was 4.5 cm × 6.0 cm-13.5 cm × 19.0 cm, with a depth of 2.0-4.0 cm. An ipsilateral anterolateral thigh chimeric perforator flap was transferred to reconstruct the wound, after the wound edges were cleared from tumour through intraoperative frozen section examinations. The flaps were 5.5 cm × 7.0 cm - 14.0 cm × 20.0 cm in size, with the volumes of muscle flap at 7.0 cm × 4.0 cm × 3.0 cm - 14.0 cm × 7.0 cm × 3.0 cm. After having the deep defect at the base of wound filled with a muscle flap, the wound surface was covered by the flap. Four patients had direct suture of the donor sites and 4 received a thick skin graft of head or contralateral thigh grafting. Survival of the anterolateral thigh chimeric perforator flaps and the healing of donor sites were observed after surgery through scheduled postoperative follow-up by the visits of outpatient clinic and distant interviews via telephone, WeChat or the internet hospital.Results:One of the ipsilateral anterolateral thigh chimeric perforator flaps had venous occlusion within 24 hours after surgery. Emergency surgical exploration revealed that it was caused by a haematoma compression due to haemorrhage in the muscle flap. Further debridement, haemostasis and suture were performed, then the wound healed. The rest of 7 flaps all survived. All donor sites healed primarily. The postoperative follow-up lasted for 5-17 months with all of the 8 patients, at 8.4 months in average. Both the donor and recipient sites healed well without recurrence of radiation ulcer in the affected sites. The appearance and texture of the flaps were good, and there was no obvious functional impairment at the donor sites.Conclusion:The treatment of radiation induced deep ulcer in the inguinal region with an ipsilateral anterolateral thigh chimeric perforator flap has shown good results, without recurrence of ulcer after surgery. The appearance and texture of the affected sites are good, and there is no secondary functional impairment at the donor site.

Objective:To explore the application strategies and clinical effects of superior gluteal artery perforator tissue flaps in repairing stage Ⅳ pressure ulcers in the sacrococcygeal region.Methods:This study was a retrospective observational study. From July 2019 to April 2024, 89 patients with stage Ⅳ pressure ulcers in the sacrococcygeal region who met the inclusion criteria were admitted to the First Affiliated Hospital of Nanchang University, including 59 males and 30 females, aged 21 to 84 years. There were 89 sacrococcygeal pressure ulcers, with an area of 5.0 cm×4.0 cm-21.0 cm×21.0 cm after debridement. According to the shape, size, and depth of the wounds after debridement, combined with the elasticity and texture of the skin around the wounds, and the principle of minimizing damage to the donor area, the appropriate forms of superior gluteal artery perforator tissue flaps were cut for wound repair in the following three conditions. (1) For wounds with a round shape, an area of 5.0 cm×5.0 cm-21.0 cm×21.0 cm, and a depth of 1.0-3.5 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, bilobed superior gluteal artery perforator relay flap, and bilateral superior gluteal artery perforator rotational flap were used. (2) For wounds with an oval shape, an area of 5.0 cm×4.0 cm-18.5 cm×10.5 cm, and a depth of 1.0-3.0 cm, the superior gluteal artery perforator propeller flap or myocutaneous flap, unilateral superior gluteal artery perforator propeller flap combined with contralateral superior gluteal artery perforator V-Y advanced flap or keystone flap were used. (3) For wounds with a fusiformis shape, an area of 7.0 cm×4.0 cm-17.5 cm×6.0 cm, and a depth of 1.5-5.0 cm, the unilateral or bilateral superior gluteal artery perforator V-Y advanced flap, superior gluteal artery perforator keystone flap, or superior gluteal artery perforator keystone flap combined with gluteus maximus muscle flap were used. In this group of patients, a total of 40 superior gluteal artery perforator propeller flaps (with an resection area of 11.0 cm×6.0 cm-17.0 cm×11.0 cm), 22 superior gluteal artery perforator propeller myocutaneous flaps (with an resection area of 10.0 cm×5.0 cm-14.0 cm×8.0 cm), 7 bilobed superior gluteal artery perforator relay flaps (with a main flap resection area of 5.5 cm×5.5 cm-18.0 cm×11.5 cm and a side flap resection area of 4.5 cm×3.0 cm-11.0 cm×6.5 cm), 5 bilateral superior gluteal artery perforator rotational flaps (with a total resection area of 20.0 cm×16.0 cm-26.0 cm×21.0 cm on both sides), 14 superior gluteal artery perforator V-Y advanced flaps (with an resection area of 12.0 cm×10.0 cm-18.0 cm×18.0 cm), 13 superior gluteal artery perforator keystone flaps (with an resection area of 13.0 cm×6.5 cm-19.0 cm×18.0 cm), and 3 gluteus maximus muscle flaps (with an resection area of 8.0 cm×3.0 cm-15.0 cm×4.5 cm). The donor area wounds were all directly sutured. The survival of tissue flaps was observed and the incidence rate of delayed wound healing in the reception area was calculated, and wound healing in the donor area was observed. The appearance and texture of tissue flaps and recurrence of pressure ulcers were followed up.Results:After surgery, all bilateral superior gluteal artery perforator rotational flaps, superior gluteal artery perforator V-Y advanced flaps, superior gluteal artery perforator keystone flaps, and gluteus maximus muscle flaps survived well. There were 6 cases of delayed wound healing in the reception area after surgery, with an incidence rate of 6.7% (6/89). Two patients had incision dehiscence in the donor area wounds due to postoperative bleeding, the wounds healed after debridement, vacuum sealing drainage, and dressing change. The wounds in the donor area of the remaining patients healed well. Six patients were lost to follow-up. Eighty-three patients were followed up for 3-48 months, of whom 4 patients died. Among the remaining 79 patients, 3 cases had pressure ulcers recur due to improper nursing, while the rest of the patients had tissue flaps with good appearance and soft texture and no recurrence of pressure ulcers.Conclusions:Based on the characteristics of wound shape, size, and depth after debridement of stage Ⅳ pressure ulcers in the sacrococcygeal region, individualized selection of flap, myocutaneous flap, or a combination of flap and gluteus maximus muscle flap based on the perforating branch of the superior gluteal artery perforator can achieve good clinical repair results. The postoperative tissue flap survived well, with a good appearance, soft texture, and less recurrence of pressure ulcers.

Objective:To explore the clinical efficacy of posterior femoral cutaneous nerve nutrient vessel adipofascial flaps plus free-style gluteal perforator flaps in repairing stage IV sciatic tuberosity pressure ulcers.Methods:A retrospective case series study was conducted to analyze the clinical data of 16 patients (16 wounds) with stage IV sciatic tuberosity pressure ulcers admitted to First Affiliated Hospital of Nanchang University from May 2021 to February 2024, including 10 males and 6 females, aged 21-84 years [(58.5±16.5)years]. Among them, 8 patients were complicated with chronic osteomyelitis of the ischium at 8 sites. The wound area before debridement ranged from 2.0 cm×1.5 cm to 9.0 cm×7.0 cm. All the patients underwent staged surgery. In phase I surgery, the scar tissue at the wound margin, necrotic tissue, bursa, and chronic osteomyelitic lesions were removed in the ischium. After debridement, the wound area ranged from 4.0 cm×3.0 cm to 12.0 cm×8.0 cm. Negative pressure closure drainage (VSD) was performed and wound bed preparation was completed. In phase II surgery, the posterior femoral cutaneous nerve nutrient vessel adipofascial flaps were flipped, filled into the wound cavity, and then used to repair the wound by advancing and rotating in combination with free-style gluteal perforator flap. The area of posterior femoral cutaneous nerve nutrient vessel adipofascial flaps ranged from 9.0 cm×3.5 cm to 19.0 cm×10.0 cm and the area of the free-style gluteal perforator flaps ranged from 5.0 cm×4.0 cm to 13.0 cm×8.5 cm. The amount of bleeding in phase II surgery was recorded. The survival and wound healing of the posterior femoral cutaneous nerve nutrient vessel adipofascial flaps and free-style gluteal perforator flaps were observed. At the last follow-up, recurrence of pressure ulcers and osteomyelitis, external appearance of the wound, and secondary functional impairment and deformity in the donor sites were observed.Results:All the patients were followed up for 6-15 months [(9.4±3.1)months]. The intraoperative bleeding volume in phase II surgery was 80-300 ml [(162.9±60.6)ml]. All the posterior femoral cutaneous nerve nutrient vessel adipofascial flaps survived well after surgery. A small area of bruising was observed at the distal end of the freestyle gluteal perforator flap in 1 patient at 1 day after surgery, which was relieved after removing some of the sutures. Torn suture of the incision was found as a result of postoperative subcutaneous hematoma in the donor site of the posterior femoral cutaneous nerve nutrient vessel adipofascial flap in 1 patient at 1 day after surgery, which healed at 22 days after bedside debridement and dressing change. All other incisions healed well. At the last follow-up, there was no recurrence of pressure ulcers or osteomyelitis and the wound was mildly pigmented and soft. There were no secondary functional impairments or deformities in the posterior femoral or gluteal donor sites.Conclusion:Posterior femoral cutaneous nerve nutrient vessel adipofascial flaps plus freestyle gluteal perforator flaps can be used in the repair of stage IV sciatic tuberosity pressure ulcer wounds, with the advantages of less intraoperative bleeding, high tissue flap survival rate, good wound healing, no recurrence of pressure ulcers or osteomyelitis after surgery, good wound appearance and texture, and no secondary functional impairment or deformity in the donor sites.

Objective:To explore the clinical efficacy of posterior femoral cutaneous nerve nutrient vessel adipofascial flaps plus free-style gluteal perforator flaps in repairing stage IV sciatic tuberosity pressure ulcers.Methods:A retrospective case series study was conducted to analyze the clinical data of 16 patients (16 wounds) with stage IV sciatic tuberosity pressure ulcers admitted to First Affiliated Hospital of Nanchang University from May 2021 to February 2024, including 10 males and 6 females, aged 21-84 years [(58.5±16.5)years]. Among them, 8 patients were complicated with chronic osteomyelitis of the ischium at 8 sites. The wound area before debridement ranged from 2.0 cm×1.5 cm to 9.0 cm×7.0 cm. All the patients underwent staged surgery. In phase I surgery, the scar tissue at the wound margin, necrotic tissue, bursa, and chronic osteomyelitic lesions were removed in the ischium. After debridement, the wound area ranged from 4.0 cm×3.0 cm to 12.0 cm×8.0 cm. Negative pressure closure drainage (VSD) was performed and wound bed preparation was completed. In phase II surgery, the posterior femoral cutaneous nerve nutrient vessel adipofascial flaps were flipped, filled into the wound cavity, and then used to repair the wound by advancing and rotating in combination with free-style gluteal perforator flap. The area of posterior femoral cutaneous nerve nutrient vessel adipofascial flaps ranged from 9.0 cm×3.5 cm to 19.0 cm×10.0 cm and the area of the free-style gluteal perforator flaps ranged from 5.0 cm×4.0 cm to 13.0 cm×8.5 cm. The amount of bleeding in phase II surgery was recorded. The survival and wound healing of the posterior femoral cutaneous nerve nutrient vessel adipofascial flaps and free-style gluteal perforator flaps were observed. At the last follow-up, recurrence of pressure ulcers and osteomyelitis, external appearance of the wound, and secondary functional impairment and deformity in the donor sites were observed.Results:All the patients were followed up for 6-15 months [(9.4±3.1)months]. The intraoperative bleeding volume in phase II surgery was 80-300 ml [(162.9±60.6)ml]. All the posterior femoral cutaneous nerve nutrient vessel adipofascial flaps survived well after surgery. A small area of bruising was observed at the distal end of the freestyle gluteal perforator flap in 1 patient at 1 day after surgery, which was relieved after removing some of the sutures. Torn suture of the incision was found as a result of postoperative subcutaneous hematoma in the donor site of the posterior femoral cutaneous nerve nutrient vessel adipofascial flap in 1 patient at 1 day after surgery, which healed at 22 days after bedside debridement and dressing change. All other incisions healed well. At the last follow-up, there was no recurrence of pressure ulcers or osteomyelitis and the wound was mildly pigmented and soft. There were no secondary functional impairments or deformities in the posterior femoral or gluteal donor sites.Conclusion:Posterior femoral cutaneous nerve nutrient vessel adipofascial flaps plus freestyle gluteal perforator flaps can be used in the repair of stage IV sciatic tuberosity pressure ulcer wounds, with the advantages of less intraoperative bleeding, high tissue flap survival rate, good wound healing, no recurrence of pressure ulcers or osteomyelitis after surgery, good wound appearance and texture, and no secondary functional impairment or deformity in the donor sites.