Extended lower trapezius island myocutaneous flap: a fasciomyocutaneous flap based on the dorsal scapular artery

The lower trapezius island myocutaneous flap is a useful flap in head and neck reconstruction. It is thin and pliable and can reach defects in most areas of the head and neck. Its usefulness in head and neck reconstruction has often been limited or discouraged by reports of significant failure rates. In this study, the vascular anatomy and clinical use of the extended lower trapezius myocutaneous flap based solely on the dorsal scapular artery system are elucidated, and experience gained performing 20 flaps over the past 5 years by using the extended lower trapezius myocutaneous flap is reported. The vascular anatomy of the dorsal scapular artery system is reviewed in 13 fresh cadaveric dissections by using methylene blue, latex injection studies, and radiologic examination.     

The dorsal scapular island flap: an alternative for head,neck, and chest reconstruction

The back has become an increasingly popular donor site for flaps because it can provide thin, pliable tissue, with minimal bulk, and the scar can be easily hidden under clothing. The authors performed a cadaveric and clinical study to evaluate the anatomy of the dorsal scapular vessels and their vascular contribution to the skin, fascia, and muscles of the back. On the basis of anatomical studies in 28 cadavers and clinical experience with 32 cases, it was concluded that the dorsal scapular vessels provide a reliable blood supply to the skin of the medial back, making it a versatile flap to use as an island flap. A flap raised on the dorsal scapular vessels can be harvested with a long pedicle and can be rotated to reach as far as the anterior regions of the head, neck, and chest wall. Delaying and expanding the flap may help to facilitate venous drainage. The authors recommend the use of this versatile island pedicle flap as an alternative to microvascular free-tissue transfer for the reconstruction of defects in the head, neck, and anterior chest.     

The bipedicled osteocutaneous scapula flap: a new subscapular system free flap

Thirty-six adult dissections (14 cadaver and 22 operative) demonstrate the constant presence of the angular branch of the thoracodorsal artery as a vascular pedicle to the inferior pole of the scapula. This vessel originated in all cases just proximal or distal to the serratus branch of the thoracodorsal artery and arborized to the periosteum 6 to 9 cm from the bony branch of the circumflex scapular artery. In eight patients, scapular osteocutaneous flaps were raised preserving the angular branch and the circumflex scapular artery and dissecting up to the subscapular vessels. In all cases, bone was independently perfused by the angular branch. In all six cases where the angular branch was the sole supply to bone, technetium-99m scans demonstrated perfusion. Addition of this vascular pedicle to scapula bone allows two separate bone flaps with one microanastomosis and provides a longer arc of rotation between skin supplied by the circumflex scapular artery and bone. Donor-site morbidity was no greater than with the standard scapula flap.     

Clinical and basic research on occipito-cervico-dorsal flaps: including a study of the anatomical territories of dorsal trunk vessels

The authors have carried out a clinical study of all the patients who underwent reconstructions with occipito-cervico-dorsal flaps in their department between 1994 and 2003 and analyzed the outcomes of the surgery. The reconstructed areas ranged from the cheek to the anterior chest. Twenty-eight cases underwent reconstruction with microvascular augmented occipito-cervico-dorsal flaps, and four were reconstructed with single pedicle occipito-cervico-dorsal flaps. In five cases, distal partial necrosis was observed. The largest flap size was 43 x 23 cm (5 x 5-cm pedicle). In the microvascular augmented occipito-cervico-dorsal flaps, the circumflex scapular artery and veins were used in 28 cases, and dorsal intercostal perforators were used together with circumflex scapular artery and veins in five cases. The follow-up term was between 1 and 8 years. Neck scar contractures were released in all cases, and good results were obtained not only functionally but also aesthetically. In an anatomical study, the authors used 20 preserved cadavers and took angiograms of the dorsal region. Five cadavers were used to confirm the territory of each of the vessels that have close relations to the occipito-cervico-dorsal flap (the occipital artery, transverse cervical artery, circumflex scapular artery, and dorsal intercostal perforator artery). Each anatomical territory was clearly seen and its area identified.     

Epithelialization process of free fascial flaps used in reconstruction of oral cavity mucosa defects in dogs

Bare free fascial flaps are increasingly used for restoration of soft-tissue defects of the oral cavity because they provide thin, foldable tissues with high epithelialization capacity to preserve local anatomy as well as chewing, phonation, and deglutition. However, there are unanswered questions regarding the epithelialization process and other histopathologic changes occurring after transfer of these flaps into the oral cavity. To investigate these changes thoroughly, an experimental study was conducted in the dog model. Bare dorsal thoracic fascia was used as the free flap model. Ten adult dogs were used in this experiment. Oral mucosa defects measuring 6 x 5 cm were created. Free dorsal thoracic fascia flaps were harvested. The vascular pedicle of the fascia flap was anastomosed with the superior thyroidal artery and external jugular vein. Then, the flaps were transferred into the mucosa defects. The dogs were divided into groups, each composed of two animals. At 7, 14, 21, 30, and 60 days postoperatively, general anesthesia was administered to the groups 1, 2, 3, 4, and 5, respectively. First, clinical assessment was performed; then specimens were obtained. Initially, the flaps were gradually infiltrated by acute inflammatory cells coming from the circulation and then replaced by granulation tissue. Epithelial cells deriving from wound margins migrated onto the granulating flaps with eventual coverage of highly organized epithelium after 4 weeks, and the fascia flap could not be differentiated from the native mucosa. The flaps were replaced by normally maturated fibrous tissue containing regular collagen fibers, instead of atypical scar tissue. Wound contraction was calculated as 18 percent at postoperative day 60. It was detected that bare free fascia flaps used in the repair of mucosa defects act as a scaffold and complete epithelialization from surrounding margins. They can be accepted as the main surgical option for the reconstruction of oral cavity mucosa defects.     

The descending branch of the superficial circumflex artery supplying anteromedial thigh skin

This report presents an extended groin flap design that consists of a conventional skin paddle in the groin region and a vertical extension in the anteromedial thigh region, based on the superficial iliac circumflex artery and an unnamed descending branch, respectively. The inferior branch of the superficial iliac circumflex artery that supplies the thigh extension of the flap, spanning approximately the upper half of the thigh region, was found to originate approximately 2 cm from the origin of the superficial iliac circumflex artery. A total of six free and four local flaps were used in 10 patients with ages ranging from 10 to 60 years (average, 45 years). There were six male and four female patients. The free flaps were required for total facial resurfacing, through-and-through cheek defect, and burn scar contractures and traumatic defects of the lower extremity. The local flaps were used for reconstruction of scrotum defect, trochanteric decubitus ulcer, and lower abdominal skin and fascia defects. All 10 flaps survived completely. The groin flap with anteromedial thigh extension offers the following advantages: (1) it is very easy and quick to elevate; (2) a significantly increased volume of tissue is available for reconstruction, based on one axial vessel and being completely reliable; (3) the flap offers two skin paddles that are independently mobile; (4) there is no need for positional change and a two-team approach is possible; and (5) it can be raised as a vertical skin island only. The authors conclude that the groin flap with anteromedial thigh extension is a useful modification for reconstruction of both distant and local defects.     

Transverse dual-perforator fascia-sparing free TRAM flap: technique description

As techniques for breast reconstruction with autologous abdominal tissue have evolved, free transverse rectus abdominis myocutaneous flaps have persevered because of their superior reliability and minimal donor-site morbidity compared with muscle-sparing techniques. Further refinements are described in this article to maximize abdominal flap perfusion and ensure primary closure of the rectus fascia. It has been well documented that incorporating both the lateral and medial perforators provides maximal perfusion to all zones of the lower abdominal transverse skin flap. However, dissection and harvest of both sets of perforators requires disruption and/or sacrifice of abdominal wall tissues. The technique presented here was designed to use both the lateral and medial row perforators, and to minimize abdominal wall disruption. Deep inferior epigastric artery medial and lateral row perforators are selected for their diameter, proximity, and transverse orientation to each other. A transverse ellipse of fascia is incised to incorporate both perforators. The fascial incision is then extended inferiorly in a T configuration to allow for adequate exposure and harvest of the vascular pedicle and/or rectus abdominis, and primary closure. Limiting perforator selection to one row of inferior epigastric arteries diminishes perfusion to the abdominal flap. Furthermore, perforator and inferior epigastric artery dissection often results in fascial defects that are not amenable to primary closure. However, maximal abdominal flap perfusion and minimal donor-site morbidity can be achieved with the transverse dual-perforator fascia-sparing free transverse rectus abdominis myocutaneous flap technique and can be performed in most patients.     

The vascular supply of the extended tensor fasciae latae flap: how far can the skin paddle extend?

The vascular supply of the tensor fasciae latae flap and of the lateral thigh skin was studied in 10 cadavers to evaluate whether the lateral thigh skin toward the knee could be incorporated into an extended tensor fasciae latae flap. Within each cadaver, vascular injection of radiopaque material preceded flap elevation in one limb and followed flap elevation in the contralateral limb. Flaps raised after vascular injection were examined radiographically to evaluate the vascular anatomy of the lateral thigh skin independent of flap elevation. When vascular injection was made into the profunda femoris, the upper two-thirds of the flaps was better visualized than the distal third. When the injection was made into the popliteal artery, the vasculature of the distal third of the flaps was better visualized. Flaps raised before vascular injection were examined radiographically to delineate the anatomical territory of the vascular pedicle that had been injected. In these flaps, consistent cutaneous vascular supply was only seen in the skin overlying the tensor fasciae latae muscle, confirming that musculocutaneous perforators are the predominant means by which the pedicle of the tensor fasciae latae flap supplies the skin of the lateral thigh. Extended tensor fasciae latae flaps were elevated bilaterally in one cadaver, and selective methylene blue injections were made into the lateral circumflex femoral artery on one side and into the superior lateral genicular artery on the contralateral side. Methylene blue was observed in the proximal and distal thirds of the skin paddles, respectively, leaving unstained midzones. The vascular network of the lateral thigh skin could be divided into three zones. The lateral circumflex femoral artery and the third perforating branches of the profunda femoris artery perfuse the proximal and middle zones of the lateral thigh skin, respectively. The superior lateral genicular artery branch of the popliteal artery perfuses the distal zone. The middle and distal zones meet 8 to 10 cm above the knee joint, where the skin paddle of the tensor fasciae latae flap becomes unreliable. These data indicate that if the aim is to incorporate the skin over the distal thigh in an extended tensor fasciae latae flap without resorting to free-tissue transfer, then either a carefully planned delay procedure or an additional anastomosis to the superior lateral genicular artery is required.     

The use of scapular and parascapular flaps for cheek reconstruction.

This is a retrospective review of our experience with microvascular transfer of scapular and parascapular flaps for the correction of lateral facial contour deficiencies. Twenty-eight patients with congenital (n = 8) and acquired (n = 20) defects were treated with 30 flaps; two patients had bilateral flaps. The etiology of the defects included hemifacial microsomia (n = 2), oblique facial cleft (n = 1), Romberg's hemifacial atrophy (n = 5), neoplasm (n = 4), irradiation (n = 8), trauma (n = 4), tumor excision (n = 4), facial lipodystrophy (n = 2), and silicone granuloma (n = 2). The follow-up evaluation was from 2 to 13 years, with an average of 6 years. Fabrication of a facial moulage was part of the preoperative planning for each patient. These were compound flaps, including skin, deepithelialized skin, fat, fascia, and bone, if necessary. All flaps were constructed with an intact skin paddle for postoperative monitoring. Based on dissections and anatomic findings at operation, several variations in the level of emergence of the circumflex scapular artery from the triangular space and its branching patterns were noted. All flaps survived; changes in the patients' weights were reflected in the flaps. Twelve patients required secondary procedures: excision of skin monitor islands, scar revisions, debulking, or flap resuspension to the malar region. Bone grafts or alloplastic implants were necessary in four patients in whom the malar eminence could not be adequately corrected by transfer of a flap. The deepithelialized scapular/parascapular flap is preferred for correction of large lateral facial defects.     

The tensor fascia lata myocutaneous free flap.

The tensor fascia lata muscle and its overlying skin provide a reliable myocutaneous unit containing a large amount of soft tissue for a free flap transfer. Its anatomy is outlined, and the operative technique for transfer is detailed in a case of chronic stasis ulcer of the lower leg.     

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.     

The parascapular flap for treatment of lower extremity disorders

The parascapular flap was used as a free microvascular transfer for soft-tissue resurfacing of 11 lower extremities. The diagnoses included four cases of osteomyelitis, three cases of vascular ulceration, one case of combined osteomyelitis and vascular ulceration, two cases of posttraumatic heel defects, and one case of extensive soft-tissue contracture overlying a posttraumatic defect of the femur. All cases were successful clinically. Anatomically, the parascapular flap is supplied by the cutaneous parascapular artery, a branch of the circumflex scapular artery, which itself derives from the subscapular artery. Flap territory may reach 15 x 30 cm, and the vascular pedicle can extend 14 cm if the subscapular artery is taken. Advantages of this flap include the constancy, length, and caliber of the vascular pedicle; the length and width attributes, which allow both coverage of large wounds and primary closure of the donor defect; and an absence of disruption of musculoskeletal function.     

Experimental pretransfer expansion of free-flap donor sites: II. Physiology, histology, and clinical correlation

There is a statistically significant increase in blood flow into expanded cutaneous and myocutaneous flaps in a pig model over controls. The vascular trees within flaps enlarge following expansion, and pronounced neovascularization is seen in the papillary dermis and capsular layers. Experimentally, there is differential thinning of all tissue layers except the epidermis. A successful clinical application of this technique, by free-tissue transfer of an expanded fasciocutaneous scapular flap, is described. The technique is applicable when altered flap size or contour is desired.     

Free anterolateral thigh adipofascial perforator flap

The anterolateral thigh adipofascial flap is a vascularized flap prepared from the adipofascial layer of the anterolateral thigh region. It is a perforator flap based on septocutaneous or musculocutaneous perforators of the lateral circumflex femoral system. With methods similar to those used for the free anterolateral thigh flap, only the deep fascia of the anterolateral thigh and a 2-mm-thick to 3-mm-thick layer of subcutaneous fatty tissue above the fascia were harvested. In 11 cases, this flap (length, 5 to 11 cm; width, 4 to 8 cm) was used for successful reconstruction of extremity defects. Split-thickness skin grafts were used to immediately resurface the adipofascial flaps for eight patients, and delayed skin grafting was performed for the other three patients. The advantage of the anterolateral thigh adipofascial flap is its ability to provide vascularized, thin, pliable, gliding coverage. In addition, the donor-site defect can be closed directly. Other advantages of this flap, such as safe elevation, a long wide vascular pedicle, a large flap territory, and flow-through properties that allow simultaneous reconstruction of major-vessel and soft-tissue defects, are the same as for the conventional anterolateral thigh flap. The main disadvantage of this procedure is the need for a skin graft, with the possible complications of subsequent skin graft loss or hyperpigmentation.     

Free tensor fasciae latae perforator flap for the reconstruction of defects in the extremities

In the three cases presented in this study, free tensor fasciae latae perforator flaps were used successfully for the coverage of defects in the extremities. This flap has no muscle component and is nourished by muscle perforators of the transverse branch of the lateral circumflex femoral system. The area of skin that can by nourished by these perforators is larger than 15 x 12 cm. The advantages of this flap include minimal donor-site morbidity, the preservation of motor function of the tensor fasciae latae muscle and fascia lata, the ability to thin the flap by removing excess fatty tissue, and a donor scar that can be concealed. In cases that involve transection of the perforator above the deep fascia, the operation can be completed in a very short period of time. This flap is especially suitable as a free flap for young women and children who have scars in the proximal region of the lateral thigh or groin region that were caused by split-thickness skin grafting or full-thickness skin grafting during previous operations.     

Superiority of the deep circumflex iliac vessels as the supply for free groin flaps. Clinical work.

In this paper we present 16 cases of free transfer of compound flaps from the groin, 11 using the deep circumflex iliac vessels as a stem and 5 using the superficial circumflex iliac vessels as a stem. We found the deep vessels superior in many ways to the superficial vessels for this purpose; they are larger, permitting greater ease in anastomoses and providing more reliable blood flow. We believe that larger osteocutaneous or myocutaneous flaps can be transferred on the deep vessels than on the superficial ones-and that the deep circumflex iliac flap may supplant the conventional free going flap in most situations. The method evolved in response to patient need, not for surgical éclat.     

Osteocutaneous flap prefabrication based on the principle of vascular induction: an experimental and clinical study

Conventional osteomyocutaneous flaps do not always meet the requirements of a composite defect. A prefabricated composite flap may then be indicated to custom create the flap as dictated by the complex geometry of the defect. The usual method to prefabricate an osteocutaneous flap is to harvest a nonvascularized bone graft and place it into a vascular territory of a soft tissue, such as skin, muscle, or omentum, before its transfer. The basic problem with this method is that the bone graft repair is dependent on the vascular carrier; the bone needs to be revascularized and regenerate. The bone graft may not be adequately perfused at all, even long after the transfer of the prefabricated flap. This study was designed to prefabricate an osteocutaneous flap where simply the bone nourishes the soft tissues, in contrast to the conventional technique in which the soft tissue supplies a bone graft. This technique is based on the principle of vascular induction, where a pedicled bone flap acts as the vascular carrier to neovascularize a skin segment before its transfer. Using a total of 40 New Zealand White rabbits, two groups were constructed as the experimental and control groups. In the experimental group, a pedicled scapular bone flap was induced to neovascularize the dorsal trunk skin by anchoring the bone flap to the partially elevated skin flap with sutures in the first stage. After a period of 4 weeks, the prefabricated composite flaps (n = 25) were harvested as island flaps pedicled on the axillary vessels. In the control group, nonvascularized scapular bone graft was implanted under the dorsal trunk skin with sutures; after 4 weeks, island composite flaps (n = 15) were harvested pedicled on the cutaneous branch of the thoracodorsal vessels. In both groups, viability of the bony and cutaneous components was evaluated by means of direct observation, bone scintigraphy, measurement of bone metabolic activity, microangiography, dye injection study, and histology. Results demonstrated that by direct observation on day 7, the skin island of all of the flaps in the experimental group was totally viable, like the standard axial-pattern flap in the control group. Bone scintigraphy revealed a normal to increased pattern of radionuclide uptake in the experimental group, whereas the bone graft in the control group showed a decreased to normal pattern of radioactivity uptake. The biodistribution studies revealed that the mean radionuclide uptake (percent injected dose of 99mTc methylene diphosphonate/gram tissue) was greater for the experimental group (0.49+/-0.17) than for the control group (0.29+/-0.15). The difference was statistically significant (p<0.01). By microangiography, the cutaneous component of the prefabricated flap of the experimental group was observed to be diffusely neovascularized. Histology demonstrated that although the bone was highly vascular and cellular in the experimental group, examination of the bone grafts in the control group revealed necrotic marrow, empty lacunae, and necrotic cellular debris. Circulation to the bone in the experimental group was also demonstrated by India ink injection studies, which revealed staining within the blood vessels in the bone marrow. Based on this experimental study, a clinical technique was developed in which a pedicled split-inner cortex iliac crest bone flap is elevated and implanted under the medial groin skin in the first stage. After a neovascularization period of 4 weeks, prefabricated composite flap is harvested based on the deep circumflex iliac vessels and transferred to the defect. Using this clinical technique, two cases are presented in which the composite bone and soft-tissue defects were reconstructed with the prefabricated iliac osteomyocutaneous flap. This technique offers the following advantages over the traditional method of osteocutaneous flap prefabrication. Rich vascularity of the bony component of the flap is preserved following transfer (i.e. (ABSTRACT     

Vastus medialis myocutaneous and myocutaneous-tendinous composite flaps

This report describes a new myocutaneous territory and introduces a new myocutaneous flap based on the vastus medialis muscle. Dissection, arterial dye perfusion, and specimen angiography of 32 fresh cadaver legs defined a vastus medialis myocutaneous territory directly overlying the muscle and also defined a segment of quadriceps femoris tendon vascularized by the muscle. This vascular unit provides a myocutaneous flap for closure of anterior knee defects. This flap can also be designed as a composite myocutaneous-tendinous flap by inclusion of the vascularized quadriceps femoris tendon segment, which allows reconstruction of missing patellar tendon segments. The distal advancement flap design with retention of motor innervation preserves vastus medialis contribution to knee extension. Clinical applications of vastus medialis myocutaneous and myocutaneous-tendinous flaps are illustrated by their use in three patients with knee defects and patellar tendon losses. The potential value of vascularized tendon (versus vascular free tendon grafts) for patellar tendon reconstruction is discussed.     

Comparison of three different supercharging procedures in a rat skin flap model

A significant clinical problem in reconstructive surgery is partial loss of a pedicled flap. To resolve this problem, various methods of vascular augmentation have been developed; "supercharging" is one of those techniques. A new rat flap model was developed for investigation of the supercharging procedure, and the efficacy of the arterial supercharging method was examined. The purpose of this study was to investigate how an arterial supercharging procedure could generate large flap survival areas with different supercharging positions in rats. On the basis of the vascular anatomical features of rats, a circumferential skin flap from the lower abdomen to the back, measuring 4 x 12 cm, was marked. The flap was divided along the dorsal midline. Forty rats were divided into four experimental groups, as follows: group 1 (control), flaps based only on the deep circumflex iliac artery and vein; group 2, flaps supercharged with the ipsilateral superficial inferior epigastric artery; group 3, flaps supercharged with the contralateral superficial inferior epigastric artery; group 4, flaps supercharged with the contralateral deep circumflex iliac artery. On the fourth postoperative day, the flaps were evaluated with measurements of necrosis and survival areas. Microfil (Flow Tech, Inc., Carver, Mass.) was then injected manually throughout the body, and the vascular changes produced by supercharging were angiographically evaluated. Compared with group 1 (control), the flap survival areas were significantly greater in distally supercharged flaps in groups 3 and 4 (mean flap survival, 91.2 +/- 5.2 percent and 90.5 +/- 10.6 percent, respectively; p < 0.001) and in proximally supercharged flaps in group 2 (45.9 +/- 4.1 percent, p < 0.05). Angiographic assessment of the flaps that survived completely revealed marked dilation of the choke veins among the territories and reorientation of dilated veins along the axes of the flaps. This study suggests that distal arterial supercharging (contralateral superficial inferior epigastric artery or contralateral deep circumflex iliac artery) is more effective than proximal arterial supercharging (ipsilateral superficial inferior epigastric artery) in increasing flap survival. Although the rat skin flap may not be analogous to human flaps, distal arterial supercharging might have useful therapeutic potential in increasing flap survival in clinical practice.     

Myocutaneous free-flap transfer. Anatomical and experimental considerations.

If there is a strongly dominant vascular pedicle, a muscle may be suitable for transfer as a free myocutaneous flap. The minor vascular pedicle(s) may contribute significantly to the arterial blood flow to the overlying skin, however. The concept of doing a delay procedure (ligating the dominant pedicle) to increase the survival of the skin component of a free myocutaneous flap is explored.