Abstract

The selection of recipient vessels is crucial when reconstructing traumatized lower extremities using a free flap. When the dorsalis pedis artery and/or posterior tibial artery cannot be palpated, we utilize computed tomography angiography to verify the site of vascular injury prior to performing free flap transfer. For vascular anastomosis, we fundamentally perform end-to-side anastomosis or flow-through anastomosis to preserve the main arterial flow. In addition, in open fracture of the lower extremity, we utilize the anterolateral thigh flap for moderate soft tissue defects and the latissimus dorsi musculocutaneous flap for extensive soft tissue defects. The free flaps used in these two techniques are long and include a large-caliber pedicle, and reconstruction can be performed with either the anterior or posterior tibial artery. The preparation of recipient vessels is easier during the acute phase early after injury, when there is no influence of scarring. A free flap allows flow-through anastomosis and is thus optimal for open fracture of the lower extremity that requires simultaneous reconstruction of main vessel injury and soft tissue defect from the middle to distal thirds of the lower extremity.

1. Introduction

Reconstruction of a traumatized lower extremity using a free flap carries a greater risk of developing complications compared to reconstruction of other sites [14]. Many investigators have reported the importance of selecting an appropriate recipient vessel when reconstructing the lower extremity by free flap transfer [57]. To enhance the success rate of free flap transfer in open fractures of the lower extremity, anastomosis with healthy recipient vessels that have not been affected by the trauma must be performed. Chen et al. [8] recommended using the posterior tibial artery as the recipient vessel, since the anterior tibial artery is injured more frequently than the posterior tibial artery in open fracture of the lower extremity. Several investigators have performed vascular anastomosis distal to the zone of injury, since main vessels in the distal third of the lower extremity pass through a superficial layer [9, 10]. Kolker et al. [11] reported no differences in operative outcomes between use of vascular anastomosis proximal or distal to the zone of injury.

This retrospective study examined recipient vessels and vascular anastomosis techniques in 18 consecutive patients who underwent free flap transfer at an early stage after suffering open fracture of the lower extremity.

2. Patients and Methods

We performed free flap transfer within 1 week after injury in 18 consecutive patients (15 men and 3 women) who suffered Gustilo type IIIB open fracture of the lower extremity between January 2002 and December 2008. Mean age at the time of surgery was 31.9 years (range, 18–58 years). The causes of injury were a traffic accident in 15 cases and an occupational accident in 3 cases. Data on fracture site, transferred flaps, vessels selected for anastomosis, anastomosis techniques, and postoperative complications were obtained from medical records. Mean duration of follow-up was 41 months (range, 7–86 months).

3. Results

The fracture sites were the proximal third of the lower extremity in 2 cases, the middle third of the lower extremity in 7, and the distal third of the lower extremity in 9. The transferred free flaps were an anterolateral thigh flap in 13 cases and a latissimus dorsi musculocutaneous flap in 5. The anastomosed recipient arteries were the anterior tibial artery in 10 cases, the posterior tibial artery in 6, the popliteal artery in 1, and the superior medial genicular artery in 1.

The vascular anastomosis techniques used were flow-through anastomosis in 12 cases, end-to-side anastomosis in 5, and end-to-end anastomosis in 1. Postoperative complications were congestion due to thrombosis in 2 patients who subsequently underwent reexploration and deep infection that subsided with additional debridement in 1 patient. Free flaps survived in all patients, including the 3 patients who underwent reoperation (Table 1).

4. Case Reports

4.1. Case 1

A 58-year-old woman suffered open fracture injury to the lower right extremity in a traffic accident. On the day of injury, debridement and external fixation of the open fracture of the lower extremity were performed. On day 6 after injury, reconstruction was performed using intramedullary fixation and a free anterolateral thigh flap. On preoperative medical examination, the dorsalis pedis artery and posterior tibial artery were palpable. In surgery, the anterior tibial artery was carefully dissected to confirm the absence of injury. End-to-side anastomoses of the lateral circumflex femoral artery and anterior tibial artery with the anterolateral thigh flap were performed to preserve arterial blood flow. The anterolateral thigh flap survived without postoperative complications (Figure 1).

4.2. Case 2

A 21-year-old man suffered open fracture injury to the lower right extremity in an occupational accident at a construction site. At the initial surgery, debridement and external fixation were performed. Two days later, open fracture of the lower right extremity was reconstructed with intramedullary fixation and free anterolateral thigh flap. Since the anterior tibial artery had been injured in the open fracture of the lower right extremity, the anterior tibial artery was reconstructed by interposing the lateral circumflex femoral artery of the anterolateral thigh flap. Lateral circumflex femoral veins were anastomosed with the concomitant and great saphenous veins using end-to-end anastomosis. The anterolateral thigh flap survived without postoperative complications. Four months after injury, autologous bone grafting was performed for the bone defect in the open fracture of the lower extremity. Bone union was achieved by 18 months after injury, and the patient has since returned to his original occupation (Figure 2).

5. Discussion

The selection of recipient vessels is crucial when reconstructing traumatized lower extremities with free flap. Since the anterior tibial artery is prone to injury in lower extremity trauma, the posterior tibial artery is often selected as the recipient vessel [8]. For recipient vessel selection, in addition to intraoperative examination, preoperative palpation, Doppler flowmetry, and angiography were conducted. Isenberg and Sherman [12] reported that if no problems are seen with the dorsalis pedis artery and posterior tibial artery based on palpation, Doppler flowmetry, and Allen’s test, preoperative angiography is unnecessary. Lutz et al. [13] also indicated that preoperative angiography should be applied only when pedal pulses of both the dorsalis pedis and posterior tibial arteries are not palpable and that routine preoperative angiography is unnecessary. On the other hand, Duymaz et al. [14] recommended computed tomography angiography as the first-stage diagnostic procedure, as this method is superior for visualizing the hemodynamics of the traumatized lower extremity. When the dorsalis pedis artery and/or posterior tibial artery are not palpable, we conduct computed tomography angiography to confirm the vascular injury site prior to free flap transfer.

The anterior lower extremity is often injured in open fracture of the lower extremity, and recipient vessels pass through a deeper layer in parts more proximal to the zone of injury, making vascular anastomosis increasingly difficult. For this reason, Stompro and Stevenson [9] conducted free flap transfer with distally based anastomosis for surgery performed in the distal third of the lower extremity, where recipient vessels pass through the superficial layer. Minami et al. [10] also stated that distally based anastomosis is useful in reconstruction of the anterior lower extremity with free flap transfer. Kolker et al. [11] reported that the outcomes of free flap transfer do not differ between distal and proximal anastomosis, stating that distal anastomosis is appropriate when proper hemodynamics are maintained in the zone of injury.

Godina et al. [15] reported a posterior approach to the recipient vessels. Specifically, they described the usefulness of the posterior approach, which can ensure a sufficient surgical field of view and healthy recipient vessels. Park and Eom [16] recommended the superior medial genicular vessels and descending genicular vessels as recipient vessels around the knee. In the two patients who suffered fracture in the proximal third of the lower extremity, recipient arteries were the superior medial genicular artery in 1 patient and the popliteal artery via a posterior approach in the other patient. Only a few recipient vessels around the knee are available for free flap transfers from the proximal third of the lower extremity, and both arteries have proven useful as recipient arteries.

For vascular anastomosis, to preserve the main arterial flow, we fundamentally perform end-to-side anastomosis or flow-through anastomosis. Various outcomes of end-to-side anastomosis have been reported [2, 9, 17, 18]. Godina [17] reported favorable outcomes from end-to-side anastomosis. However, Khouri and Shaw [2] reported that end-to-side anastomosis is prone to thrombosis. Samaha et al. [7] demonstrated a lack of differences in outcomes between end-to-end anastomosis and end-to-side anastomosis and reported that outcomes are influenced by recipient vessel selection and the condition of blood perfusion from distal areas.

To preserve main arterial flow in open fracture of the lower extremity, we perform end-to-side anastomosis if no obvious injuries to the main artery are present and flow-through anastomosis whenever possible if the fracture is accompanied by injuries to the main artery. Koshima et al. [19] reported several advantages of flow-through anastomosis, indicating that the damaged main vessels can be reconstructed simultaneously with large skin defects, while double artery inflow using both ends of the pedicle artery ensures safe blood circulation in the flap, and two concomitant pedicle veins interposed into the damaged recipient concomitant veins can be used as a drainage system in extremities with severe edema. We perform flow-through anastomosis using lateral circumflex femoral vessels of the anterolateral thigh flap and thoracodorsal vessels of the latissimus dorsi musculocutaneous flap. In the acute phase when the influences of scarring are absent, the dissection is relatively easy even in the anterior tibial artery, which is highly likely to be injured. We, therefore, performed anterior tibial artery reconstruction with flow-through anastomosis as much as possible. Free flap with flow-through anastomosis fundamentally entails a flap with stable blood flow. Although 1 patient who underwent flow-through type anterolateral thigh flap developed partial congestion, the flap ultimately survived reexploration. Free flap transfer with flow-through anastomosis does not cause vascular insufficiency as long as the surgery is performed meticulously and the proper recipient vessels are selected. When the dorsal pedis and the posterior tibial arteries are palpable, a flow-through anastomosis is not indicated.

With an open fracture of the lower extremity, we utilize an anterolateral thigh flap with the pedicle descending branch of the lateral femoral circumflex artery for the moderate soft tissue defect and the latissimus dorsi musculocutaneous flap with the pedicle thoracodorsal artery and the serratus branch for the extensive soft tissue defect. These two techniques are long and include a large-caliber pedicle, and reconstruction can be performed with either the anterior or posterior tibial artery. Preparation of recipient vessels is easier during the acute phase when the influences of scarring have not yet manifested. Free flap, which allows flow-through anastomosis, is thus optimal for simultaneous reconstruction of the main vessel injury and soft tissue defect from the middle to distal thirds of the lower extremity.

6. Conclusions

When injury to the anterior or posterior tibial artery is suspected in open fracture of the lower extremity, we perform computed tomography angiography to evaluate the arterial injury. In open fracture of the lower extremity without arterial injury, we perform free flap transfer with end-to-side anastomosis to preserve the main vessels. When the arterial injury is present from the middle to distal thirds of the lower extremity in open fracture of the lower extremity, we perform free flap transfer with flow-through anastomosis as much as possible. Free flap transfer with flow-through anastomosis is a useful method that can simultaneously reconstruct soft tissue defects and the main artery.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.