Distally based sural fasciomuscular flap: anatomic study and application for filling leg or foot defects

Since 1995, the authors have created 32 distally based superficial sural artery flaps based on the vascular axis of the sural nerve. The creation of the first 18 flaps permitted the authors to view perforators that issued from the gastrocnemius muscles to the vascular axis of the sural nerve. This led to the development of an anatomic study involving 25 cadaveric dissections to establish a relationship between the gastrocnemius muscles and the vascular axis of the sural nerve, with two to three constant and direct perforators from the gastrocnemius to the neurovascular axis. In this article, the technique for harvesting this new muscular flap is described. Between June of 1997 and March of 1998, three patients underwent flap operations. Two fasciomyocutaneous flaps and one fasciomuscular flap were created and were followed by uncomplicated postoperative courses in terms of flap viability and donor sites. In all cases, the flap created was designed to fill bone defects of the leg (one case) or of the foot (two cases). The results were considered to be excellent and stable over time, with follow-up periods ranging from 9 months to 18 months in duration.     

Distally based lateral supramalleolar adipofascial flap for reconstruction of the dorsum of the foot and ankle

Soft-tissue reconstruction of the dorsum of the foot and ankle has long been a challenge for reconstructive surgeons. Limitations in the available local tissue and donor-site morbidity restrict the options. In an effort to solve these difficult problems, the authors have begun to use a distally based lateral supramalleolar adipofascial flap. This report presents the authors' early experience with seven patients treated with this flap. The patients' ages ranged from 5 to 26 years; four of the patients were male and three were female. The cause of the soft-tissue defects involved acute trauma and chronic scar contracture. The flap and the adjoining raw area were covered with a full-thickness skin graft, and the donor site at the lateral aspect of the leg was closed primarily without grafting. A skin graft was taken from the groin area, which was closed primarily. Compared with the other flaps, this adipofascial flap was thinner and produced less bulkiness to the recipient site and minor aesthetic sequelae to the donor site. It is believed that this flap is versatile and effective and is a good addition to the available techniques used by reconstructive surgeons for coverage of the dorsum of the foot and ankle.     

One year successful outcomes for novel sacroiliac joint arthrodesis system

Background

The reverse sural artery flap is a generally accepted means of soft tissue reconstruction for defects of the distal third of the legs. The routine sacrifice of the sural nerve with its consequential temporary loss of sensation on the lateral aspect of the foot can be of concern to early rehabilitation of some patients.

Method

This is a case report of a 24 years old male who had Gustillo and Anderson type IIIB injury involving the upper part of the distal 3^rd and the middle 3^rd of tibia. A reverse sural artery flap was raised without transecting the sural nerve to cover the distal part of the defect.

Result

The distal part of the exposed bone was covered with the reverse sural artery flap without loss of sensation at anytime to the lateral part of the foot.

Conclusion

The reverse sural artery flap can be raised to cover the upper portion of the distal leg without severing the sural nerve.     

Reverse-flow island sural flap

The reverse flow island sural flap is presented as an alternative to flaps currently used for reconstruction of small and medium substance losses in the distal third of the leg, ankle, and heel. This is a random type of flap, based on the reverse flow of the superficial sural artery, which mainly depends on the anatomy of the perforators of the peroneal artery system.The anatomic structures that constitute the pedicle are the superficial and deep fascias, the sural nerve, the short saphenous vein, and the superficial sural artery. The skin island and the subcutaneous cellular tissue complement the flap proper. This skin island was demarcated at any point of the median or distal thirds of the leg, having the short saphenous vein and the sural nerve on its central axis. The distal dissection limit of the pedicle is located 5 centimeters above the lateral malleolus. This limit is established so as to ensure the integrity of the perforators from the principal arteries of the leg, mainly the peroneal artery, responsible for the reverse flow nourishing the flap. These perforators will affect anastomoses with the superficial sural artery in charge of irrigating the structures compounding the flap.A total of 71 patients were operated on with this technique, some of them with basic pathologic abnormalities limiting the distal blood flow, such as diabetes mellitus, and some others having proven vascular insufficiency or displaying unstable areas attributable to problems such as pseudarthrosis and osteomyelitis, which needed to be covered. Fifteen flaps (21.1 percent) suffered partial necrosis, which did not compromise the final result, and another three (4.2 percent) showed total loss. The flap in question has great mobility and versatility, allowing the treatment of specific areas of the lower limb, without sacrificing important arteries or mobilizing structures that might bring about functional deficits.     

Super sural neurofasciocutaneous flaps in acute traumatic heel reconstructions

Conventional reversed sural flaps have been used to cover heel defects; however, the experience of the authors indicates that the reach of these flaps falls just short of the critical area to be covered. With the limitation being the location of the flap (the middle third of the leg), the authors thought that if the flap territory were extended proximally, they would have a super flap with immense potential. Nevertheless, the critical question remained, "How far?" The massive earthquake in January of 2001 in Gujarat, India, made medical personnel pressed for time, manpower, resources, and other ancillary supports. The authors were forced to make some innovations in their management of extensive heel defects. On the basis of preexisting anatomic studies, they developed the possibility of using distally based neuroskin flaps of huge dimensions that extend well beyond the conventional confines. The versatility of this extended, reversed, neuro-fasciocutaneous flap in regard to its reliability and safety, despite its huge dimensions, is commendable. The hallmarks of this successful extended sural flap, which the authors used to cover large heel defects, were basically accurate understanding of the anatomy and the use of Doppler to map the perforators and the lesser saphenous vein for inclusion in the lie of the pedicle. The authors share their experience of five cases of difficult heel reconstructions salvaged with this flap, which made them attempt to define maximum flap dimensions that can be harvested. The authors learned that the flap can be extended proximally to include the entire upper one-third of the leg posteriorly, drastically improving its reach and size, without compromising safety. The largest flap used measured 17 x 16 cm, far more than ever reported in the literature. The flaps truly deserve the classification of "super," which is usually reserved for Ponten's flaps.     

The distally based lesser saphenous venofasciocutaneous flap for ankle and heel reconstruction

Finding an appropriate soft-tissue grafting material to close a wound located over the ankle and heel can be a difficult task. The distally based lesser saphenous venofasciocutaneous flap mobilized from the posterior aspect of the upper leg, used as an island pedicle skin flap, can be useful for this purpose. The vascular supply to the flap is derived from the retrograde perfusion of the accompanying arteries of the lesser saphenous vein. These arteries descend along both sides of the lesser saphenous vein to the distal third of the leg, either terminating or anastomosing with the septocutaneous perforators of the peroneal artery. Between February of 1999 and March of 2001, four variants of this flap were applied in 21 individuals, including 11 fasciocutaneous, five fascial, three sensory, and two fasciomyocutaneous flaps. Skin defects among all patients were combined with bone, joint, and/or tendon exposure. The authors found that the flap was reliable and technically simple to design and execute. This one-stage procedure not only preserves the major arteries and the sural nerve of the injured leg, but it also has proved valuable for covering a weight-bearing heel and filling a deep defect, because it potentially provides protective sensation and a well-vascularized muscle fragment. When conventional local flaps are inadequate, this flap should be considered for its reliability and low associated morbidity.     

Versatility of the sural fasciocutaneous flap in the coverage of lower extremity wounds

The distally based sural nerve flap is an excellent option for covering defects of the lower third of the leg. It allows rapid, reliable coverage of defects extending as far distally as the forefoot. The flap can be elevated under a tourniquet in relatively bloodless fashion without sacrificing a major vessel to the foot. Its use is described in a variety of defects in 11 patients, ranging in age from 3 to 64 years. The flap was used bilaterally in one case and in cross-leg fashion in another. All defects were covered with no major complications, and none of the patients required a blood transfusion. One flap experienced a small amount of distal marginal necrosis, which was excised and closed primarily. The technical aspects of flap elevation are emphasized.     

The distally pedicled peroneus brevis muscle flap: a new flap for the lower leg

Defects of the skin and soft tissue in the region of the lateral malleolus of the ankle and the Achilles tendon, resulting in exposed bone, tendons, or osteosynthetic material, cannot be covered with free skin transplants. Local or free flaps must be employed. The authors present the construction of a peroneus brevis muscle flap with a distal pedicle as a useful alternative. Between 1993 and 1999, distal pedicled peroneus brevis muscle flaps were used in 19 patients with various types of defects. During construction of the flap, both the long peroneal muscle and the peroneal artery remained intact. In the region of the distal third of the fibula, consistently arranged branches run from the artery into the muscle, and these form the distal pedicle. The proximal portion of the muscle can be transposed distally and easily extends to the tip of the fibula and the attachment of the Achilles tendon to the calcaneus. Primary healing occurred in 16 patients undergoing flap construction. Donor-site morbidity was mostly limited to the donor-site scar. The distally pedicled peroneus brevis muscle flap is a reliable means for covering defects in the lower leg. This form of muscle flap has not yet been described in the known literature. In the authors' opinion, this flap constitutes a logical and valuable extension of local flap procedures for plastic surgery in the distal leg region.     

The anterior tibial artery flap: anatomic study and clinical application

Satisfactory replacement of skin defects over the lower leg remains a difficult problem. Various forms of coverage, including, local rotation flaps, muscle flaps, and fascial and free flaps, have their specific indications and inherent disadvantages. In this work, a new axial skin flap based on perforating vessels in the territory of the anterior tibial artery is described. A series of 50 lower leg dissections was carried out in 25 fresh cadavers after latex injection into the femoral artery. Detailed studies of the cutaneous distribution of the anterior tibial artery showed that three main arteries perfuse the anterior lateral portion of the lower leg. The superior lateral peroneal artery and the inferior lateral peroneal artery interseptal cutaneous perforators arise at an average of 25.6 and 17.2 cm from the lateral malleolus, respectively. The superior lateral peroneal artery was present in 100 percent of the specimens, whereas the inferior lateral peroneal artery was present in 70 percent of the specimens. In their course, they give several muscular branches to the peroneus longus and brevis prior to perforating the fascia and arborizing in the subcutaneous tissues of the anterolateral portion of the leg. The average external diameter was 1.6 cm for the superior and 1.4 cm for the inferior lateral peroneal artery. The superficial peroneal nerve accessory artery is the third artery which contributes to the skin of the lower leg. It arises from the superior lateral peroneal artery in 30 percent of cases, from the inferior lateral peroneal artery in 40 percent, and from both in 30 percent. The artery runs along with the superficial peroneal nerve and gives several cutaneous perforators along its descending course. Several cutaneous axial flaps can be fashioned around this anatomy. The operative technique along with demonstrative clinical cases is presented followed by pertinent discussion.     

The medial sural artery perforator free flap.

The medial sural artery supplies the medial gastrocnemius muscle and sends perforating branches to the skin. The possible use of these musculocutaneous perforators as the source of a perforator-based free flap was investigated in cadavers. Ten legs were dissected, and the topography of significant perforating musculocutaneous vessels on both the medial and the lateral gastrocnemius muscles was recorded. A mean of 2.2 perforators (range, 1 to 4) was noted over the medial gastrocnemius muscle, whereas in only 20 percent of the specimens was a perforator of moderate size noted over the lateral gastrocnemius muscle. The perforating vessels from the medial sural artery clustered about 9 to 18 cm from the popliteal crease. When two perforators were present (the most frequent case), the perforators were located at a mean of 11.8 cm (range, 8.5 to 15 cm) and 17 cm (range, 15 to 19 cm) from the popliteal crease. A series of six successful clinical cases is reported, including five free flaps and one pedicled flap for ipsilateral lower-leg and foot reconstruction. The dissection is somewhat tedious, but the vascular pedicle can be considerably long and of suitable caliber. Donor-site morbidity was minimal because the muscle was not included in the flap. Although the present series is short, it seems that the medial sural artery perforator flap can be a useful flap for free and pedicled transfer in lower-limb reconstruction.     

The simple and effective choice for treatment of chronic calcaneal osteomyelitis: neurocutaneous flaps

The authors describe their experience with the use of distally based saphenous and sural neurofasciocutaneous flaps for the treatment of calcaneal osteomyelitis in nine cases. Aggressive débridement of all nonviable and poorly vascularized tissue and coverage with a distally based neurofasciocutaneous flap were coupled with a thorough antibiotic course in all cases. The deepithelized peripheral parts of all flaps were buried in the bone cavities after bone débridement. Follow-up periods ranged from 15 to 27 months. All flaps survived completely. All of the wounds except one healed completely. These flaps have adequate blood flow for the management of chronic bone infections. They also have many advantages, such as easy quick elevation, short operative time, and acceptable donor-site morbidity. Moreover, patients treated with neurocutaneous flaps do not require debulking procedures or special shoes. Reconstruction with neurocutaneous flaps after radical débridement is a versatile alternative to the use of local or distant muscle flaps and calcanectomy procedures for patients with osteomyelitis of the os calcis.     

A new flap design: neural-island flap

This report introduces the "neural-island flap" concept, which represents a consistent and reliable skin flap design supplied only by the intrinsic vasculature of a cutaneous nerve. In this study, the lateral femoral cutaneous nerve was selected as the pedicle of the neural-island flap, and a standard skin flap, which is the territory of the accompanying vessels (i.e., iliac branches of the iliolumbar artery and vein), was elevated on the lower dorsal region of the rats. In a total of 92 Wistar rats, three experiments were performed. In part I (n = 24), the vascular anatomy of the lateral femoral cutaneous nerve was established by the methods of dissection, microangiography, nerve mapping, perfusion with colored latex and India ink, and histologic analysis. In part II (n = 46), the role of the cutaneous nerve in supporting an acutely elevated skin flap was explored by creating five flap groups as follows: group 1, conventional flap (artery, vein, and nerve intact); group 2, neural island flap (only the nerve intact); group 3, neurocutaneous flap (vein and nerve intact); group 4, denervated flap (artery and vein intact); and group 5, skin graft. In part III (n = 22), the role of a preliminary surgical delay procedure to augment the survival of the neural island flap was investigated. Results of the anatomic studies indicated a consistent perineural vasculature by the accompanying iliolumbar artery. Skin flaps survived totally in groups where the artery and vein were intact, whereas mean survival rates for the neural island flap and the neurocutaneous flap were 38.2 +/- 3.1 percent and 44.5 +/- 3.8 percent, respectively (p > 0.05). Results of part III of the experiment demonstrated a significantly higher survival for the delayed neural island flap (94.5 +/- 5.5 percent) compared with the acutely elevated neural island flap (p < 0.05). The perineural and intraneural vessels were found to be greatly dilated after a delay procedure, demonstrated by direct observation, microangiography, histologic analysis, dye injection study, and scanning electron microscopy. On the basis of this promising series of experiments, a clinical technique was developed using the sural neural-island flap. The flap was used to reconstruct lower extremity defects in four cases. A delay procedure was accomplished in the first stage by elevating a fasciocutaneous flap from the midcalf region based on a posterior skin bridge and the sural nerve. After a 2-week delay period, a sural neural-island flap was created based on the nerve and transposed to the defect. Flap survival was complete in all cases, with a satisfactory result. The authors conclude that this report proves for the first time that a robust and reliable skin flap can be created pedicled only by the intrinsic vasculature of a cutaneous nerve, after a proper surgical delay. The so-created neural-island flap design offers two novel advantages: (1) a very narrow pedicle and (2) a pedicle without any restriction to a specific pivot point, in addition to the previously described unique advantages of preservation of a major artery and avoidance of microvascular anastomoses.     

Forefoot reconstruction by reversed island flaps in diabetic patients

Soft-tissue coverage of the foot is often difficult, especially when the distal third of the foot (dorsal or plantar aspects) is involved. The clinical situation can be further complicated when diabetic patients are affected by painful and unstable wounds of this kind because of the familiar phenomenon of vasculopathy. The purpose of this study was to evaluate the possibility of using distally based foot flaps to cover forefoot defects in diabetic patients. Preoperative selection of patients was the key to this study; those who had other major disease, chronic infection, bone involvement, and/or insufficient foot vascularization were excluded from the study. The authors report a series of 12 diabetic patients in whom the reconstruction of medium-sized defects (ranging from 1.5 x 2.0 cm to 3.0 x 7.0 cm) of the forefoot was performed using distally based dorsalis pedis flaps or medial plantar flaps. The transferred flaps survived and adapted well to the defects, except for one flap in a patient who had a slight venous insufficiency at outset. Wearing their own footwear, patients could walk after 20 to 30 days. After the follow-up period (3 months to 3 years), no skin breakdown in the treated areas was observed. Temporary donor-site pain was reported by medial plantar flap patients, and partial skin graft loss at the donor site occurred in some of the dorsalis pedis patients. The authors suggest that in selected cases, medium-sized soft-tissue defects involving the dorsal aspects or the weight-bearing areas of the diabetic foot can be successfully covered with distally based island flaps.     

Distally based anterolateral thigh flap: an anatomic and clinical study

The distally based anterolateral thigh flap has been used for coverage of soft-tissue defects of the knee and upper third of the leg. This flap is based on the septocutaneous or musculocutaneous perforators derived from the lateral circumflex femoral system. The purpose of this study was to examine the results of anatomical variations of the descending branch of the lateral circumflex femoral artery and the retrograde blood pressure of the descending branch of the lateral circumflex femoral artery so that the surgical technique for raising and transferring a distally based anterolateral thigh flap to the knee region could be improved. The authors have actually used this flap in three cases. In 11 thighs of six cadavers, the descending branch of the lateral circumflex femoral artery had a rather consistent connection with the lateral superior genicular artery or profunda femoral artery in the knee region. The pivot point, located at the distal portion of the vastus lateralis muscle, ranges from 3 to 10 cm above the knee. In their three cases, the maximal flap size was 7.0 x 16.0 cm and was harvested safely, without marginal necrosis. The mean pedicle length was 15.2 +/- 0.7 cm (range, 14.5 to 16 cm). The average proximal and distal retrograde blood pressure of the descending branch of the lateral circumflex femoral artery was also studied in another 11 patients, and the anterolateral thigh flap being used for reconstruction of head and neck defects showed 58.3 and 77.7 percent of proximal antegrade blood pressure, respectively. The advantages of this flap include a long pedicle length, a sufficient tissue supply, possible combination with fascia lata for tendon reconstruction, and favorable donor-site selection, without sacrifice of major vessels or muscles.     

Clinical applications of free soleus and peroneal perforator flaps

Clinical applications of two free lateral leg perforator flaps are described: a free soleus perforator flap that is based on the musculocutaneous perforator vessels from one of the three main arteries in the proximal lateral lower leg, and a free peroneal perforator flap that is based on the septocutaneous or direct skin perforator vessels from the peroneal artery in the distal and middle thirds of the lateral lower leg. The authors applied free soleus perforator flaps to 18 patients and free peroneal perforator flaps to five patients with soft-tissue defects. The recipient site was the great toe in 14 patients, the hand and fingers in five patients, the leg in two patients, and the upper arm and the jaw in one patient each. The largest soleus perforator flap was 15 x 9 cm, and the largest peroneal perforator flap was 9 x 4 cm. Vascular pedicle lengths ranged from 6.5 to 10 cm in soleus perforator flaps and from 4 to 6 cm in peroneal perforator flaps. All flaps, except for the flap in one patient in the peroneal perforator flap series, survived completely. Advantages of these flaps are that there is no need to sacrifice any main artery in the lower leg, and there is minimal morbidity at the donor site. For patients with a small to medium soft-tissue defect, these free perforator flaps are useful.     

The medial adiposofascial flap of the leg: anatomical basis and clinical applications

Despite recent advances in microsurgical techniques, coverage of lower leg defects by locoregional flaps remains indicated in selected cases. The interest in these types of flaps has improved because recent clinical work advocates that fascial and fasciocutaneous flaps can be well indicated for bone coverage. The anatomical study of the medial adiposofascial flap is presented in this article. The flap is based on the rich vascular network supplied by the saphenous artery and the posterior tibial artery perforators. This flap can be harvested on the anteromedial aspect of the leg and can be mobilized to cover defects located between the patella and the heel. This multiple blood supply makes it possible to harvest this flap in various ways, so various defects can be covered. To confirm and prove the versatility and clinical value of this flap, the authors have studied a series of 22 cases in which this flap was used for coverage of lower leg defects. For these defects, especially when situated in the lower third or around the heel and ankle, coverage by a free flap is most often the only proposed solution. However, the authors have obtained excellent results in the majority of these cases, avoiding a free flap procedure. Moreover, in this way, the option of using a free flap remains possible if needed. There is minimal donor-site morbidity and a high functional and aesthetic outcome, making this flap a first-choice flap in selected cases of lower leg defects.     

The role of the large superficial vein in survival of proximally based versus distally based sural veno-neuro-fasciocutaneous flaps in a rabbit model

A sural veno-neuro-fasciocutaneous flap in the New Zealand White rabbit was developed, and the role of the large subcutaneous lesser saphenous vein was investigated in proximally based versus distally based flaps. Retrograde dye injection showed that the lesser saphenous vein in rabbits has many valves with strong resistance against reflux. Twenty rabbits were randomly allocated into four groups of 10 flaps each. Group I consisted of proximally based flaps with the lesser saphenous vein intact (outflow) in the veno-neuro-adipofascial pedicle. Group II also consisted of proximally based flaps but the lesser saphenous vein was ligated at 1 cm proximal to the pedicle. Group III consisted of distally based flaps with the lesser saphenous vein intact (inflow) in the veno-neuro-adipofascial pedicle. Group IV also consisted of distally based flaps, but the lesser saphenous vein was ligated at 1 cm distal to the pedicle. The results showed that the mean flap survival area in group I (88.8 percent) was statistically higher than that in group II (62.6 percent, p < 0.001), and was higher in group IV (55.5 percent) than in group III (22.7 percent, p < 0.01). However, group II and group IV had no significant difference (p > 0.05). This experiment demonstrated that flap viability is determined by its intrinsic vascularization, both arterial and venous. The large superficial subcutaneous vein has a positive role (venous outflow) in proximally based flaps but a negative role (venous inflow) in distally based flaps. If the effect of the large subcutaneous vein is excluded, distally based flaps are not inherently inferior to proximally based flaps.     

A clinical experience with perforator flaps in the coverage of extensive defects of the upper extremity

Traditional skin free flaps, such as radial arm, lateral arm, and scapular flaps, are rarely sufficient to cover large skin defects of the upper extremity because of the limitation of primary closure at the donor site. Muscle or musculocutaneous flaps have been used more for these defects. However, they preclude a sacrifice of a large amount of muscle tissue with the subsequent donor-site morbidity. Perforator or combined flaps are better alternatives to cover large defects. The use of a muscle as part of a combined flap is limited to very specific indications, and the amount of muscle required is restricted to the minimum to decrease the donor-site morbidity. The authors present a series of 12 patients with extensive defects of the upper extremity who were treated between December of 1999 and March of 2002. The mean defect was 21 x 11 cm in size. Perforator flaps (five thoracodorsal artery perforator flaps and four deep inferior epigastric perforator flaps) were used in seven patients. Combined flaps, which were a combination of two different types of tissue based on a single pedicle, were needed in five patients (scapular skin flap with a thoracodorsal artery perforator flap in one patient and a thoracodorsal artery perforator flap with a split latissimus dorsi muscle in four patients). In one case, immediate surgical defatting of a deep inferior epigastric perforator flap on a wrist was performed to immediately achieve thin coverage. The average operative time was 5 hours 20 minutes (range, 3 to 7 hours). All but one flap, in which the cutaneous part of a combined flap necrosed because of a postoperative hematoma, survived completely. Adequate coverage and complete wound healing were obtained in all cases. Perforator flaps can be used successfully to cover a large defect in an extremity with minimal donor-site morbidity. Combined flaps provide a large amount of tissue, a wide range of mobility, and easy shaping, modeling, and defatting.     

Distal lower leg local random fasciocutaneous flaps

Significant open wounds of the distal third of the lower leg that require some form of vascularized flap have historically been covered with distant cross-leg flaps or more appropriately with microsurgical tissue transfers. The rediscovery of the "random" fasciocutaneous flap as a reliable single-stage option for proximal lower leg defects has been extended distally to allow an expedient alternative in lieu of these more complicated procedures. Over the past 7 years, 17 selected patients had closure of distal leg and ankle wounds with 19 local antegrade-oriented fasciocutaneous flaps. All eventually healed without serious sequelae, although 5 (26 percent) had minor complications, except for one case that could only be salvaged with a free-tissue transfer in order to prevent limb amputation. For small- or moderate-sized, uncontaminated injuries, this approach warrants consideration under appropriate circumstances as a simpler option that may permit satisfactory healing and avoids the known risks of microsurgical tissue transfers.