Emergency repair of upper extremity large soft tissue and vascular injuries with flow-through anterolateral thigh free flaps

Application of Flow-through Anterolateral Thigh Perforator Flaps in Replantation of Complex Severed Limb

OBJECTIVE

To explore the clinical application value of flow-through anterolateral thigh perforator (ALTP) flaps in replantation of complex severed limbs.

METHODS

Thirteen severe vascular, nerve injury, and skin or soft tissue defects in patients with complex severed limbs from August 2017 to January 2019 were enrolled in this retrospective study. The skin flap has covered the wound by using the flow-through ALTP flap technique. The main vascular defect was repaired by using the descending branch of the lateral circumflex femoral artery, and the blood supply of the transplanted limb was reconstructed. The blood supply of the flap and wound healing observed were observed after the operation. Regular follow-up was performed to observe the survival and functional recovery of the replanted limb.

RESULTS

Eleven cases of replanted limb and perforator flap survived completely. Limb shortening occurred in 3 patients owing to bone defects caused by distal amputation. After the second stage of bone transplantation, the limb length and function of those 3 patients recovered well. One case showed necrosis of the little finger after replantation of the severed palm. One case showed that the crushed forearm was severed completely. The anastomotic vascular inflammatory embolism was caused by infection and necrosis of soft tissue after replantation for 2 weeks, and then the stump wound was covered with a survived skin flap in the second stage.

CONCLUSION

The flow-through ALTP flap technique has a good therapeutic effect on the functional reconstruction of complex severed limbs with severe skin and vascular injuries.

Modified medial gastrocnemius myocutaneous flap with extended anterior, inferior and/or posterior boundaries: Anatomical observation and report of a clinical series of 33 flaps

INTRODUCTION

Reports on medial gastrocnemius myocutaneous (MGM) flaps with extended inferior and posterior boundaries are rare, and information about the MGM flaps with extended anterior boundaries is unavailable. Thus, this study aimed to investigate the vascular anatomical basis and clinical reliability of the modified MGM flap with extended anterior, inferior and/or posterior boundaries.

METHODS

Five fresh lower limb specimens from patients with recurrent tumours in the thigh were immediately irrigated and perfused. The stripped integuments were radiographed. The pretibial skin was equally divided into nine zones. The reconstruction outcomes of the modified MGM flaps were documented in 33 patients.

RESULTS

True anastomotic connections existed among the branches of the saphenous artery, the perforator from the inferior medial genicular artery and 3-5 (mean, 4.5) perforators from the posterior tibial artery in the upper two-thirds of the leg. A total of 33 modified MGM flaps were applied. The anterior margins of 26 modified flaps with extended anterior boundaries exceeded the medial edge of the tibia by 1.0-4.5 cm (mean, 2.1 cm). Fourteen modified MGM flaps were used to repair the defects involving the lower third leg, whose distal edges were located in the seventh (n = 8) or eighth (n = 6) zone. A 1-169-month (median, 9 months) follow-up was conducted for 33 patients. Of the 33 flaps, 29 (87.9 %) survived completely, partial necrosis occurred in four flaps with extended anterior (n = 2) or inferior (n = 2) boundaries.

CONCLUSIONS

Multiple source vessels are the vascular anatomical basis of the modified MGM flap with extended anterior, posterior and/or inferior boundaries. The modification of the MGM flap is feasible and reliable, broadening the applicable scope of the flap. The modified MGM flap can be applied to repair more distal, wider and larger-area defects with a simpler design and procedure.

Anterolateral thigh flow-through flap: A versatile method for reconstruction of complex extremity defects

BACKGROUND

Flow-through flaps have been widely applied only for the reconstruction of complex defects in the extremities because they can be used for arterial reconstruction and soft tissue coverage simultaneously. This report attempts to fully demonstrate the role of the anterolateral thigh (ALT) flow-through flap as a versatile method for reconstructing complex defects in the extremities.

METHODS

From February 2011 to March 2017, we retrospectively analyzed the use of a reconstructive surgical technique based on the ALT flow-through flap to treat complex extremity defects in 87 patients (trauma, n = 79; diabetic ulcers, n = 5; squamous cell carcinoma, n = 3). Emergency surgery was performed in 12 patients to bridge a major artery gap and was followed by elective reconstruction in the remaining patients. Applications of the ALT flow-through flap included bridging major artery gaps, preserving recipient blood vessel integrity, reconstructing blood vessel continuity, protecting vascular anastomoses, avoiding difficult end-to-side anastomoses in the recipient area, and balancing blood flow, as well as combined application with an additional flap.

RESULTS

The flap size ranged from 6 × 3 cm to 17 × 9 cm. ALT flow-through flaps were used in combination with an additional flap (n = 4) and in vascular reconstruction (n = 83). Three patients required of the microvascular anastomostic reexploration for venous congestion, total necrosis occurred in two patients, and partial necrosis occurred in one patient. At the donor site, there were three cases of infection and two cases of wound dehiscence. At the recipient site, one case of infection and two cases of wound dehiscence were observed. One patient presented with deep infection secondary to renal failure and underwent amputation. During the follow-up period (range, 1-33 months), all other flaps (84 cases) survived uneventfully, with normal texture and color.

CONCLUSION

The ALT flow-through flap plays many roles as it is a versatile method for reconstructing complex defects of the extremities and serves various other clinical purposes.

Twenty-minute harvesting of flow-through type vastus lateralis muscle flap significantly reduces the need for a temporary intravascular shunt in the treatment of severe upper extremity trauma in civilian patients

For the reconstruction of severe upper extremity trauma involving arterial injury in civilian patients, it is generally recommended that the revascularization time be shortened using a temporary intravascular shunt (TIVS). However, if a flow-through type vastus lateralis muscle (VLm) flap can be harvested in 20 minutes and bypassed at the obstructed ischemic zone within 30 minutes, blood flow can be restored as quickly or more quickly than when using a TIVS, eliminating the need for a TIVS. This procedure was applied in the reconstruction of 3 cases of severe extremity trauma with vascular injury. The mean age was 69.7 years. Surgery was started an average of 2.93 hours from the onset. The average flap harvest time was 0.33 hours. The average time to revascularization from flap harvest was 1.33 hours, the average total operation time was 6.43 hours, and all upper extremities were salvaged. No cases showed ischemia-reperfusion injury or severe muscle contracture. The flow-through-type VLm flap can be applicable as a bypass graft for a 20 cm defect at any region distal to the elbow. In addition, harvesting the flap attached to blood-rich muscle not only controls the infection of contaminated wounds through the filling of dead space, but also has the potential to replace damaged muscle or tendon tissue. Even though TIVS placement is currently used extensively in this field of treatment, its role could be significantly reduced if a flow-through-type VLm flap can be harvested within 20 minutes.

Management of Complex Upper Extremity Trauma with Associated Vascular Injury

Introduction Combined soft tissue and vascular injuries of the upper extremity pose several challenges at once to the plastic surgeon. Many decisions have to be taken urgently that will influence the salvage or amputation of the affected extremity. The aim of this article was to provide an evidence-based outline for the management of such injuries. Learning objectives of this article are as follows: (1) approach to a patient with upper extremity composite tissue and vascular injury presenting to the emergency, (2) decision-making as to when to salvage and when to go for amputation of the traumatized upper extremity, (3) role of imaging in emergency situation, (4) role of fasciotomy, (5) intraoperative sequencing of steps, and (6) options for vascular reconstruction and the flaps used for coverage. After reading this article, the reader should have a clear understanding of the management of vascular injury in a patient with composite defects of upper extremity.

Degree of Soft Tissue Injury is a Major Determinant of Successful Arterial Repair in the Extremity: A New Classification of Extremity Arterial Injury?

BACKGROUND

This study aimed to investigate outcomes after extremity arterial injury repair and examined the association between outcomes and the degree of soft tissue injury and vascular repair methods.

METHODS

A retrospective study was conducted on 106 patients (108 cases) who underwent emergent microsurgical repair of extremity arterial injury due to trauma and non-perfusion of the affected extremity. The cases were divided into three groups by degree of associated soft tissue injuries: (A) adequate soft tissue coverage over the injured major vessels after radical debridement, (B) inadequate soft tissue coverage over the injured major vessels after radical debridement, and (C) radical debridement was not feasible due to unclear extent of injured soft tissue. Differences in vascular repair methods and outcomes among the three groups were analyzed.

RESULTS

In Group A (n = 61), microvascular suture and vessel graft achieved 95.1% and 85.0% successful limb reperfusion, respectively. In Group B (n = 31), vessel reconstruction with flap coverage achieved 100% successful reperfusion. Vessel graft achieved 28.6% successful limb reperfusion, while there were no cases of successful reperfusion using microvascular sutures. In Group C (n = 16), no vascular repair method achieved successful reperfusion. There were significant differences among the three groups in successful reperfusion (p < 0.001) and limb salvage (p < 0.001).

CONCLUSION

The extent of associated soft tissue injury was associated with different vascular repair methods and outcomes. We propose a new system for classifying these injuries according to the degree of associated soft tissue injury.

Reconstruction of extra-large severe punching hole injury in the palm: A case report

A 48-year-old man sustained a severe punching hole injury of 8 cm in diameter on the palm of his left hand using a punching instrument (for making the bottom of drink cans), and his middle and ring fingers were almost amputated. A flow-through type immediate ALT (anterolateral thigh) flap was used to bypass the distal blood flow and a titanium plate for mandibular reconstruction and plantar glabrous skin were used to preserve the floating amputated fingers. As there has been no report of reconstruction of a punching hole in the palmar region that exceeds 8 cm in diameter, this report is novel and educational.

[Application of free anterolateral thigh flap with fascia lata for diabetic foot ulcers with bone exposure]

OBJECTIVE

To investigate the effectiveness of free anterolateral thigh flap (ALTF) with fascia lata in repairing diabetic foot ulcers (DFUs) with bone exposure.

METHODS

Between January 2019 and January 2021, 20 patients with DFUs with bone exposure were admitted. There were 17 males and 3 females with a median age of 57.5 years (range, 48-76 years). There were 10 cases of Wagner grade 3 and 10 cases of grade 4. The DFUs formed 1 to 14 months, with a median time of 3 months. The patients underwent CT angiography, which showed extensive atherosclerosis in both lower limbs; 6 of them were severely narrowed or occluded and underwent percutaneous transluminal angioplasty. The size of wound ranged from 7 cm×6 cm to 27 cm×10 cm after applied first-stage debridement combined with vacuum sealing drainage treatment. In the second-stage, free ALTF with fascia lata was used to repair wounds and partial defects of tendons. The size of flap ranged from 8 cm×5 cm to 28 cm×11 cm. The wound of the donor site was sutured directly. The survival of the flap, the healing time of the wound, and the complications were recorded. The laser speckle blood flow imaging system was used to detect the blood perfusion of the flap and the skin around the flap at 2 weeks and 6 months after operation. The foot function was evaluated by American Orthopaedic Foot and Ankle Society (AOFAS) score at 6 months after operation.

RESULTS

After operation, effusion under the flap happened in 6 cases, which cured after symptomatic treatment. Flaps survived completely in 14 cases. The tissue necrosis at the edges of the flaps occurred in 3 cases and healed after dressing changes. Venous crisis of flaps occurred in 3 cases, of which 1 case was completely necrotic after exploration, and the other 2 cases were partially alive. The wounds of 3 cases were repaired with skin grafts after debridement and dressing. The flap survival rate was 95.0%, and the limb salvage rate was 100%. The wound healing time after flap transplantation was 14-30 days, with an average of 19.1 days. Two patients had recurrence of peripheral skin ulcers of the flaps within 1 month after healing, which healed after conservative dressing changes. Eighteen cases of incisions at donor site healed by first intention, 2 cases had local skin necrosis and healed by debridement and suture. All patients were followed up 6-30 months, with a median time of 11 months. The texture, appearance, and elasticity of the flaps were good. All patients could walk alone without pain. At 6 months after operation, the AOFAS score was 75.9±11.9, which was significantly different from that (44.7±18.4) before operation ( t=-7.025, P=0.000). The blood perfusion value increased from (38.1±7.8) PU at 2 weeks to (42.7±10.3) PU, and the difference was significant ( t=-4.680, P=0.001).

CONCLUSION

Free ALTF with fascia lata has a rich blood supply and a high survival rate. It can be used to repair DFUs with bone exposure. After the free skin flap healed, it can promote revascularization of the affected foot, reduce the probability of ulcer recurrence, and avoid amputation.

Clinical guideline for vascularized composite tissue cryopreservation

At the Summit on Organ Banking through Converging Technologies held recently in Boston, tissue and organ cryopreservation technology was a topic of considerable interest. Although cryopreservation has been widely used in clinical practice, it currently remains limited to bloodless tissues with simple structures and functions that are small or thin, for example, ultra-thin skin, ovarian tissue slices, and other similar tissues. For whole organs, except for successful cryopreservation of rat ovaries (2002) and hind limbs (August 2002), successful cryopreservation of vascularized animal tissues or organs and their replantation have not yet been reported. We conducted histological and electron microscopic examinations on muscle after blood supply restoration to explain this problem and describe our experience with the goal of informing our colleagues to further develop the technology. To achieve broad application of vascularized tissue and organ cryopreservation, we have summarized our experience and established a clinical application scope for vascularized composite tissue cryopreservation.

Emergency Repair of Severe Limb Injuries With Free Flow-Through Chimeric Anterolateral Thigh Perforator Flap

BACKGROUND

Complex limb trauma often involves both soft tissue and vascular defects, and is challenging for surgeons. The traditional musculocutaneous flap cannot achieve a 3-dimensional wound repair. Here we report our experience with a single-stage reconstruction and revascularization performed on complex extremity injuries using a free flow-through chimeric anterolateral thigh perforator (ALTP) flap.

PATIENTS AND METHODS

Seventeen patients (16 men; aged 19-55 years) with complex soft tissue defects attended our hospital from January 2010 to November 2017. All patients underwent reconstruction based on free flow-through chimeric ALTP flap for complex injuries in their extremities. The wound size ranged from 16 × 8 to 45 × 30 cm. The injured artery was flow-through anastomosed with the descending branch of the lateral femoral circumflex artery to regain blood flow. The muscle flap was used to fill the deep dead space on the injury site. The skin and fascial flaps were used for superficial cover. The donor site defects were sutured directly in 6 patients; simultaneous skin grafts were applied in the remaining 11 patients.

RESULTS

The ALTP flaps survived in 15 patients. Failure necessitated limb amputation in 2 patients. Six patients received both skin and fasciae flaps; 11 received flaps comprising the skin, fasciae, and vastus lateralis muscle. Partial necrosis after skin grafting was observed in 11 patients, and the wounds healed either by dressing change (1 patient) or second skin graft (10 patients). All donor sites healed without complications. All patients were followed up for 5 to 60 months (mean, 21.8 months).

CONCLUSIONS

The flow-through chimeric ALTP flap can be used for 1-stage reconstruction of 3-dimensional soft tissue defects and vascular gap. It is feasible for managing complex injuries of both the upper and lower extremities in emergency settings.

Revisiting the Blood Supply of the Rectus Femoris: A Case Report and Computed Tomography Angiography Study

BACKGROUND

Rectus femoris necrosis is a rare but severe complication after anterolateral thigh flap (ALTF) harvesting. It has been previously reported that the blood supply of the rectus femoris (RF) often arises from the same source artery as the ALTF; however, precise descriptions of the relationship remain limited. This article revisits the blood supply of the RF based on computed tomography angiography (CTA) and analyzes the possible influence of the blood supply on the RF during ALTF harvesting.

METHODS

Between December 2017 and June 2018, CTA images of the bilateral lower extremities of 25 patients were studied. The RF length, number, and diameter of branches at the entry point into muscle, location, and overall branch vessel origins were recorded.

RESULTS

The average ± SD RF length was 384.73 ± 19.28 mm. There were 170 branches (mean ± SD, 3.4 ± 0.96 branches per thigh), mainly arising from the lateral circumflex femoral artery. The average ± SD diameter was 1.90 ± 0.51 mm. The first branch was located at 1/5 of the proximal site of the RF, and 91% of all branches were located above the midpoint. The RF vascularity can be classified into 2 types: type 1 (36% of sides) has branches that arise from a single artery (descending lateral circumflex femoral artery or femoral artery), whereas type 2 (64% of sides) has branches at the 1/5 proximal and 4/5 distal parts, which arise from different arteries.

CONCLUSIONS

Preoperative CTA can provide anatomic information about the RF's nutrient vessel(s) and helps to optimize ALTF design.

Treatment of Large and Complicated Scalp Defects with Free Flap Transfer

BACKGROUND

Large scalp defects, especially those complicated by calvarial defects, titanium mesh exposure, or cerebrospinal fluid (CSF) leak, pose a challenge for the neurosurgeon and plastic surgeon. Here, we describe our experience of reconstructing the complex scalp defect with free flap transfer.

METHODS

From October 2012 to September 2017, 8 patients underwent free flap transfer for the reconstruction of the scalp or complicated scalp and calvarial defects. Five patients presented with scalp tumor and the other 3 patients with scalp necrosis or ulceration (2 patients with titanium plate exposure). Seven anterolateral thigh flaps and one radial forearm flap were harvested and employed. The clinical data, including defect characteristics, flap type, complications, and outcomes, were recorded and analyzed.

RESULTS

Five patients were pathologically diagnosed with malignant tumor, and 3 of them were given further radiotherapy. For the 2 patients with exposure of titanium plate, no titanium plate was removed. For the patient with scalp necrosis after decompressive craniectomy accompanied by CSF leakage, the CSF leak was stopped after reconstruction. The size of the flaps ranged from 3 to 14 cm in width and 4 to 18 cm in length. No flap failure occurred in these cases. From follow-up to the present, no ulceration or necrosis occurred.

CONCLUSIONS

Free flap transfer is an ideal method for the reconstruction of large, complicated scalp defects with a one-stage operation. The anterolateral thigh flap is favored because of its durability, adjustability, water tightness, and infection prevention.