Microvascular soft-tissue transplantation for reconstruction of acute open tibial fractures: timing of coverage and long-term functional results.

Seventy-two patients with Gustilo grade IIIB open tibial fractures were treated with free-tissue transfers. If successful free-tissue transfer for soft-tissue reconstruction is performed within 15 days of injury, the risk of major complications is 3.6 percent. Long-term retrospective follow-up (mean 42 months) revealed successful limb salvage in 93 percent, good aesthetic results in 80 percent, and patient satisfaction in 96 percent. However, 66 percent of patients exhibited significantly decreased range of motion of the ankle, 44 percent experienced swelling and edema requiring elastic support and activity modification, and 50 percent occasionally required an assistance device for ambulation. The long-term employment rate was 28 percent, and no patient returned to work after 2 years of unemployment. In contrast, 68 percent of amputees after lower extremity trauma over the same period returned to work within 2 years. Patients need to realize the disruptive nature of this injury on their family, job, and future.     

Free-tissue transfer in patients with peripheral vascular disease: a 10-year experience

Advances in free-tissue transfer have allowed for lower limb salvage in patients with significant peripheral vascular disease and limb-threatening soft-tissue wounds. The authors retrospectively reviewed their 10-year experience with free flaps for limb salvage in patients with peripheral vascular disease to assess postoperative complication rates and long-term functional outcome. They identified all patients undergoing free-tissue transfer with significant peripheral vascular disease and otherwise unreconstructible soft-tissue defects. Charts were reviewed for perioperative and long-term outcome. Parameters studied included perioperative morbidity and mortality, flap success, bypass graft patency, ambulatory results, and long-term limb and patient survival. Survival data were analyzed using life-table analysis, Kaplan-Meier survival analysis, and Cox testing. A total of 79 flaps were examined in 75 patients with peripheral vascular disease from July of 1990 to November of 1999. All patients would have required a major amputation had free-tissue transfer not been performed. Mean age was 60 years, average hospital stay was 32 days, and perioperative mortality was 5 percent. Within the first 30 days after operation, there were four cases of primary flap loss, and another two were lost as the result of bypass graft failure (8 percent); five of these cases resulted in amputation. There were no primary flap failures after 30 days. Follow-up ranged to 91 months (mean, 24 months). During this time, another 14 limbs were lost, most commonly because of progressive gangrene and/or infection in sites remote from the still-viable free flap. Using Kaplan-Meier survival analysis, 5-year flap survival was 77 percent, limb salvage 63 percent, and patient survival 67 percent. Sixty-six percent of patients were able to ambulate independently with the use of their reconstructed limb at least 1 year after hospital discharge, although some of these later went on to amputation. Free-tissue transfer for lower extremity reconstruction can be performed with acceptable morbidity and mortality in patients with peripheral vascular disease. Flap loss is low, and limb salvage, ambulation, and long-term survival rates in these patients are excellent.     

The role of free-tissue transfers in lower-extremity reconstruction

Eighty-five free flaps were performed in 76 patients for defects in the lower extremity. A new classification of lower-extremity defects was devised to help define the role of free-tissue transfers: group 1, soft-tissue defects; group 2, soft-tissue and bone loss less than 8 cm; group 3, massive soft-tissue and bone loss greater than 8 cm; and group 4, bone defect only. Each group was further divided into clean (A) and infected (B) wounds. Our overall results include resolution of the presenting problem in 82 percent; there were 17 flap losses (20 percent), persistent osteomyelitis in 8, and 10 amputations. This review has prompted us to limit our indications for limb salvage, particularly in group 3B, in patients with compound injuries that include loss of plantar sensation, and in patients with large segments of infected bone.     

Coverage of bilateral lower extremity calcaneal fractures with osteomyelitis using a single split free gracilis muscle transfer

A case is presented in which a single gracilis muscle was split and used for free-tissue coverage of two sites in a patient with bilateral calcaneal fractures and posttraumatic osteomyelitis. Muscle-flap coverage of osteomyelitis and the use of the gracilis muscle for free-tissue transfer are discussed.     

Expanding the horizons in treatment of severe peripheral vascular disease using microsurgical techniques

The use of microvascular tissue transfer as an adjunct to arterial reconstruction has begun to have a positive impact on limb salvage in patients with advanced arteriosclerosis and nonhealing ischemic wounds. However, many patients with severe peripheral vascular insufficiency not amenable to conventional arterial reconstructive procedures eventually require limb amputation. We have treated 12 patients with advanced peripheral vascular disease and nonhealing ischemic wounds by three different methods. These included distal bypass alone, distal bypass done in conjunction with free-tissue transfer, and free-tissue transfer alone. All bypass grafts were done to vessels at or below the ankle using a reversed saphenous vein. In each case, the distal anastomosis was performed, using the operating microscope and standard microvascular technique. Mean follow-up for these patients is 18 months. Distal bypass alone resulted in limb salvage in three of five patients. In the combined bypass and free-flap group, three of five patients had salvage of their threatened extremity at a 1-year follow-up. Two patients with ischemic ulcers, rest pain, and unsuitable distal vessels for bypass were treated with free-tissue transfer alone. This resulted in healed wounds, limb salvage, and complete resolution of the rest pain symptoms in both patients. When advanced ischemia is complicated by large areas of tissue loss, combined bypass and microvascular free-issue transfer, performed in stages or simultaneously, is safe and can often result in limb salvage. In the rare instance of a completely obliterated distal runoff bed, free-tissue transfer alone may provide not only a healed wound, but also a means of "indirect" revascularization of the extremity and limb salvage.     

Free-tissue transfer for limb salvage in Purpura fulminans

A series of 13 patients is described to demonstrate the experience of the authors with free-tissue transfer for limb salvage in patients with purpura fulminans. A total of seven free-flap procedures were performed, with a loss of flap in one patient. The flaps were used for lower-extremity salvage in six patients and for upper-extremity salvage in one. Purpura fulminans is a devastating illness caused by endotoxin-producing bacteria such as meningococcus and pneumococcus. Clotting derangements and systemic vasculitis often lead to widespread tissue necrosis in the extremities. Local tissue is usually not available to cover vital structures in these complex wounds. In these situations, free-tissue transfer is necessary to achieve limb salvage. Microsurgical reconstruction in patients with purpura fulminans is a formidable challenge. Because of high platelet counts and systemic vasculitis, successful microvascular anastomosis is difficult. Abnormally high platelet counts persist well into the subacute and chronic phases of the illness. Pretreatment with antiplatelet agents before microvascular surgery may be beneficial. The systemic nature of the vascular injury does not permit microvascular anastomosis to be performed outside the "zone of injury." Extensive vascular exposure, even at a great distance from the wound, does not reveal a disease-free vessel. The friable intima is difficult to manage with a standard end-to-side anastomosis, but conversion to end-to-end anastomosis may salvage free-tissue transfers in cases in which intimal damage is too severe to sustain a patent anastomosis. Patients often have peripheral neuropathies caused by the underlying disease; however, this resolves with time and is not a contraindication to limb salvage.     

The outcome of failed free flaps in head and neck and extremity reconstruction: what is next in the reconstructive ladder?

The indications for free flaps have been more or less clarified; however, the course of reconstruction after the failure of a free flap remains undetermined. Is it better to insist on one's initial choice, or should surgeons downgrade their reconstructive goals? To establish a preliminary guideline, this study was designed to retrospectively analyze the outcome of failed free-tissue transfers performed in the authors hospital. Over the past 8 years (1990 through 1997), 3361 head and neck and extremity reconstructions were performed by free-tissue transfers, excluding toe transplantations. Among these reconstructions, 1235 flaps (36.7 percent) were transferred to the head and neck region, and 2126 flaps (63.3 percent) to the extremities. A total of 101 failures (3.0 percent total plus the partial failure rate) were encountered. Forty-two failures occurred in the head and neck region, and 59 in the extremities. Evaluation of the cases revealed that one of three following approaches to handling the failure was taken: (1) a second free-tissue transfer; (2) a regional flap transfer; or (3) conservative management with debridement, wound care, and subsequent closure by secondary intention, whether by local flaps or skin grafting. In the head and neck region, 17 second free flaps (40 percent) and 15 regional flaps (36 percent) were transferred to salvage the reconstruction, whereas conservative management was undertaken in the remaining 10 cases (24 percent). In the extremities, 37 failures were treated conservatively (63 percent) in addition to 17 second free flaps (29 percent) and three regional flaps (5 percent) used to salvage the failed reconstruction. Two cases underwent amputation (3 percent). The average time elapsed between the failure and second free-tissue transfer was 12 days (range, 2 to 60 days) in the head and neck region and 18 days (range, 2 to 56 days) in the extremities. In a total of 34 second free-tissue transfers at both localizations, there were only three failures (9 percent). However, in the head and neck region, seven of the regional flaps transferred (47 percent) and four cases that were conservatively treated (40 percent) either failed or developed complications that lengthened the reconstruction period because of additional procedures. Six other free-tissue transfers had to be performed to manage these complicated cases. Conservative management was quite successful in the extremities; most patients' wounds healed, although more than one skin-graft procedure was required in 10 patients (27 percent). In conclusion, a second free-tissue transfer is, in general, a relatively more reliable and more effective procedure for the treatment of flap failure in the head and neck region, as well as failed vascularized bone flaps in the reconstruction of the extremities. Conservative treatment may be a simple and valid alternative to second (free) flaps for soft-tissue coverage in extremities with partial and even total losses.     

Limb salvage for soft-tissue malignancies of the foot: an evaluation of free-tissue transfer.

Free flaps may safely allow meaningful ambulation, durable limb preservation, and better quality of life in patients undergoing resections of soft-tissue cancers of the foot. To prove this, the records of a series of patients at The University of Texas M. D. Anderson Cancer Center (n = 67) who underwent limb salvage following tumor-related resection (n = 71 procedures) from 1989 to 1999 were retrospectively reviewed. Eighteen patients who were not candidates for local flaps or skin grafts received a total of 20 free flaps to preserve their limbs. Most defects (mean size, 78 cm2; range, 20 to 150 cm2) were on a weight-bearing surface of the foot (nine on a weight-bearing heel, three on a plantar foot); the remainder were on a non-weight-bearing surface (six on dorsum, two on a non-weight-bearing heel). Melanoma was diagnosed in nine cases (50 percent); soft-tissue sarcoma, in seven (39 percent); and squamous cell carcinoma, in two (11 percent). Fasciocutaneous and skin-grafted muscle flaps were used on both weight-bearing and non-weight-bearing surfaces. Free-tissue transfer was successful in 17 of 20 cases (85 percent); the three flap losses occurred in two patients. Minor complications (i.e., small hematoma, partial skin graft loss, and delayed wound healing) occurred in five patients. In all cases of successful free-tissue transfer, patients began partial weight bearing at a mean of 7.4 weeks (range, 2 to 12 weeks), and all ultimately achieved full weight bearing. Sixty-seven percent still required special footwear. In one patient, an ulceration on the weight-bearing portion of the flap resolved after a footwear adjustment. Only one patient was lost to follow-up (mean, 23 months). In the 17 remaining patients, limb salvage succeeded in 15 (88 percent). Of these, nine (60 percent) were alive without evidence of disease, three (20 percent) were alive with disease, and three (20 percent) had died of disease. Local recurrence developed in two patients but was successfully treated by excision and closure. No late amputations were required for local control. Thus, it seems that free flaps help facilitate limb salvage and that they may preserve meaningful limb function in patients who undergo resection of soft-tissue malignancies of the foot.     

Factors affecting outcome in free-tissue transfer in the elderly

Free-tissue transfers have become the preferred surgical technique to treat complex reconstructive defects. Because these procedures typically require longer operative times and recovery periods, the applicability of free-flap reconstruction in the elderly continues to require ongoing review. The authors performed a retrospective analysis of 100 patients aged 65 years and older who underwent free-tissue transfers to determine preoperative and intraoperative predictors of surgical complications, medical complications, and reconstructive failures. The parameters studied included patient demographics, past medical history, American Society of Anesthesiology (ASA) status, site and cause of the defect, the free tissue transferred, operative time, and postoperative complications, including free-flap success or failure. The mean age of the patients was 72 years. A total of 46 patients underwent free-tissue transfer after head and neck ablation, 27 underwent lower extremity reconstruction in the setting of peripheral vascular disease, 10 had lower extremity traumatic wounds, nine had breast reconstructions, four had infected wounds, two had chronic wounds, and two underwent transfer for lower extremity tumor ablation. Two patients had an ASA status of 1, 49 patients had a status of 2, 45 patients had a status of 3, and four had a status of 4. A total of 104 flaps were transferred in these 100 patients. There were 49 radial forearm flaps, 34 rectus abdominis flaps, seven latissimus dorsi flaps, seven fibular osteocutaneous flaps, three omental flaps, three jejunal flaps, and one lateral arm flap. Four patients had planned double free flaps for their reconstruction. Mean operative time was 7.8 hours (range, 3.5 to 16.5 hours). The overall flap success rate was 97 percent, and the overall reconstructive success rate was 92 percent. There were six additional reconstructive failures related to flap loss, all of which occurred more than 1 month after surgery. Patients with a higher ASA designation experienced more medical complications (p = 0.03) but not surgical complications. Increased operative time resulted in more surgical complications (p = 0.019). All eight cases of reconstructive failure occurred in patients undergoing limb salvage surgery in the setting of peripheral vascular disease. Free-tissue transfer in the elderly population demonstrates similar success rates to those of the general population. Age alone should not be considered a contraindication or an independent risk factor for free-tissue transfer. ASA status and length of operative time are significant predictors of postoperative medical and surgical morbidity. The higher rate of reconstructive failure in the elderly peripheral vascular disease population compares favorably with other treatment modalities for this disease process.     

Operative management and outcome of complex wounds following total knee arthroplasty.

This study describes the treatment protocol for and the outcome of the management of complex wounds around total knee replacements. An analysis of 28 patients (29 knees) with complex defects who had surgery between January 1, 1986, and July 30, 1996, was performed. A specific management protocol was applied to each knee on the basis of the size and depth of the wound, the presence of infection, and the quality of soft tissue. Primary treatment included local wound care, debridement, and skin grafting or coverage with a fasciocutaneous flap, pedicled muscle flap, or free muscle transfer. Postoperatively, knees were evaluated using the Knee Society objective score. Successful salvage of the lower extremity was obtained in 28 knees (97 percent) and of the knee prosthesis in 24 of 29 knees (83 percent). Secondary plastic surgery procedures were necessary in five knees (17 percent), and secondary orthopedic procedures were necessary in four knees (14 percent). Successful salvage of total knee arthroplasty in the presence of a complex wound requires early identification of infection, aggressive irrigation and debridement, and early appropriate soft-tissue coverage. The use of our proposed algorithm will facilitate management of these complex wounds.     

The role of intrinsic muscle flaps of the foot for bone coverage in foot and ankle defects in diabetic and nondiabetic patients

Local muscle flaps, pioneered by Ger in the late 1960s, were extensively used for foot and ankle reconstruction until the late 1970s when, with the evolution of microsurgery, microsurgical free flaps became the reconstructive method of choice. To assess whether the current underuse of local muscle flaps in foot and ankle surgery is justified, the authors identified from the Georgetown Limb Salvage Registry all patients who underwent foot and ankle reconstruction with local muscle flaps and microsurgical free flaps from 1990 through 1998. By protocol, flap coverage was the reconstructive choice for defects with exposed tendons, joints, or bone. Local muscle flaps were selected over free flaps if the defect was small (3 x 6 cm or less) and within reach of the local muscle flap. During the same time frame, the authors performed 45 free flaps (96 percent success rate) in the same areas when the defects were too large or out of reach of local muscle flaps. Thirty-two consecutive patients underwent local muscle flap reconstruction for 19 diabetic wounds and 13 traumatic wounds. All wounds, after debridement, had exposed bone at their base, with osteomyelitis being present in 52 percent of the diabetic wounds and in 70 percent of the nondiabetic wounds. Wounds were located in the hindfoot (47 percent), midfoot (44 percent), and ankle (9 percent). Vascular disease was more prevalent in the diabetic group, in which 42 percent of the affected limbs required revascularization procedures before reconstruction (versus 7 percent in the nondiabetic group). Subsequently, 83 total operations were required to heal the wounds, of which 46 percent were limited to debridement only. Thirty-four pedicled muscle flaps were used: 19 abductor digiti minimi (56 percent), nine abductor hallucis (26 percent), three extensor digitorum brevis (9 percent), two flexor digitorum brevis (6 percent), and one flexor digiti minimi (3 percent). An additional skin graft for complete coverage was required in 18 patients (53 percent). One patient died and one flap developed distal necrosis, for a 96 percent success rate. The complication rate was 26 percent and included patient death, dehiscence, and partial flap or split-thickness skin graft loss. Twenty-nine of the 32 wounds healed. One patient died in the postoperative period; in two others the wounds failed to heal and required below-knee amputations, for an overall limb salvage rate of 91 percent. Diabetes did not significantly affect healing and limb salvage rates. Diabetes, however, did affect healing times (twofold increase), length of stay (2.7 times as long), and long-term survival (63 percent survival in diabetic patients versus 100 percent in the trauma group). Local muscle flaps provide a simpler, less expensive, and successful alternative to microsurgical free flaps for foot and ankle defects that have exposed bone (with or without osteomyelitis), tendon, or joint at their base. Diabetes does not appear to adversely affect the effectiveness of these flaps. Local muscle flaps should remain on the forefront of possible reconstructive options when treating small foot and ankle wounds that have exposed bone, tendon, or joint.     

Soft-tissue flap coverage maximizes limb salvage after allograft bone extremity reconstruction

Limb salvage after extremity tumor ablation may include the use of allograft bone. The primary complication of this method is infection of the allograft, which can lead to limb loss in up to 50 percent of cases. The purpose of this study is to evaluate the efficacy of primary muscle flap coverage in the setting of allograft bone limb salvage surgery. This study is a prospective review of all patients with flap coverage of extremity allografts over the 10-year period 1991 to 2001. There were 20 patients (11 male and nine female patients) with an average age of 28 years (range, 6 to 72 years). Flap coverage was primary in 16 patients and delayed in four. Delayed coverage was performed for failed wounds that did not have a primary soft-tissue flap. Pathologic findings included osteosarcoma in nine patients, Ewing sarcoma in five patients, malignant fibrohistiocytoma in two patients, chondrosarcoma in two patients, synovial sarcoma in one patient, and leiomyosarcoma in one patient. Allograft reconstruction was performed for the upper extremity in 12 patients and for the lower extremity in eight patients. Flap reconstruction was accomplished with 20 pedicle flaps in 17 patients (latissimus dorsi, 12; gastrocnemius, four; soleus, three; and fasciocutaneous flap, one) and four free flaps (rectus abdominis, three; latissimus dorsi, one) in four patients. All pedicled flaps survived. There was one flap failure in the entire series, which was a free rectus abdominis flap. This case resulted in the only limb loss noted. The follow-up period ranged from 1 to 50 months (average, 12.35 months). At the time of final follow-up, three patients were dead of disease and 17 were alive with intact extremities. The overall limb salvage rate in the setting of bone allograft and soft-tissue flap coverage was 95 percent (19 of 20). Reoperation for bone-related complications was required in 50 percent (two of four) of cases receiving delayed flap coverage compared with 19 percent (three of 16) of patients with primary flap coverage (statistically not significant). The results of this study support the use of soft-tissue flap coverage for allograft limb reconstruction. In this series, no limb was lost in the setting of a viable flap. Reoperation was markedly reduced in the setting of primary flap coverage. Pedicled or microvascular transfer of well-vascularized muscle can be used to wrap the allograft and minimize devastating wound complications potentially leading to loss of allograft and limb.     

The segmental rectus abdominis free flap for ankle and foot reconstruction.

The reconstruction of soft-tissue defects of the ankle and foot usually requires free-tissue transfer. Although certain local flaps have been described for the reconstruction of these injuries, their utility may be compromised by significant crush injury or the size and location of the defect. Part of the rectus abdominis muscle, the segmental rectus abdominis free flap, is ideally suited for this use because of the muscle's versatility, reliability, and negligible donor deformity when harvested through a low transverse abdominal incision. Seven patients reconstructed with this flap are presented, and the technique is discussed. All patients have been successfully reconstructed with preservation of the ankle and foot. At present, all patients are fully or partially weight-bearing. The segmental rectus abdominis free flap is recommended for the reconstruction of such wounds.     

Salvage after severe lower-extremity trauma: are the outcomes worth the means?

Advances in reconstructive surgery have allowed for impressive salvage after severe lower-extremity trauma but not without complications when compared with immediate below-knee amputation. Several amputation index scores have been developed to help predict successful salvage as defined by a viable rather than a functional extremity. The purpose of this study was to evaluate retrospectively the predictive value of the amputation index scores and to assess prospectively overall health status and specific dysfunction in successful limb salvage and primary and secondary amputation by administering standardized generic and specific outcomes questionnaires (Medical Outcomes Study 36-Item Short-Form Health Survey, Western Ontario and MacMaster Universities Osteoarthritis Index). A retrospective chart review identified 55 severe lower-extremity injuries (Gustilo Type IIIB and IIIC) over a 12-year period (1984 to 1996). Forty-six severe open tibial fractures in 45 patients underwent attempted salvage. All required soft-tissue coverage by either local or free flap or vascular repair for leg salvage. The attempted-salvage group was subdivided into successful salvage and secondary amputation. The other nine patients underwent a primary amputation. There were no statistically significant differences in terms of patient demographics or other injuries (Injury Severity Score) in the three groups. Forty-eight of 54 patients with an average 5-year follow-up completed a validated generic and specific outcomes health questionnaire. In the attempted-salvage group, 89 percent of patients had a successful salvage and 11 percent came to a secondary amputation. The amputation index scores correctly predicted an amputation in 32 percent of patients. The magnitude of the amputation index scores did not correlate with the physical outcomes scores and were not found to add any significant value of information to the surgeon's decision making. Patients undergoing primary and secondary amputation had a worse physical outcomes score (28 versus 38) than successful salvage (p < 0.007). Even so, the SF-36 (physical component score) outcomes score for this group of injured extremities, regardless as to whether salvaged or amputated, was as low as or lower than that of many serious medical illnesses, suggesting that severe lower-extremity trauma impairs health as much as or more than being seriously ill. The mental component score in this group was comparable to that of a healthy population (49 versus 50), which implies the disability is primarily physical rather than psychological. Ninety-two percent of patients preferred their salvaged leg to an amputation at any stage of their injury, and none would have preferred a primary amputation.     

The relative roles of aggressive wound care versus revascularization in salvage of the threatened lower extremity in the renal failure diabetic patient

Current literature indicates poor survival and limb salvage rates in renal failure diabetic patients who present with ulcerated or gangrenous lower extremities. Even in those limbs that were successfully revascularized, the amputation rate was as high as 37 percent. This has led some to advocate immediate amputation when treating the threatened limb of a renal failure diabetic patient. The authors reviewed all renal failure diabetic patients in their wound registry to determine whether such pessimism was warranted. The authors then analyzed the relative roles of revascularization and aggressive wound care on long-term limb salvage. Forty-five consecutive renal failure diabetic patients with 71 wounds in 54 limbs were identified. Twenty-seven patients had chronic renal insufficiency, 15 patients had end-stage renal disease, and three patients received kidney transplants. The revascularization procedures (46 percent of all limbs) included angioplasty, femoral-popliteal, femoral-distal, and popliteal-distal bypasses. Forty-three amputations in combination with 67 soft-tissue repairs (delayed primary wound closure, skin grafts, local flaps, pedicled flaps, and free flaps) were necessary to close the defects. After a mean follow-up of over 3 years, the data indicate that 79 percent of wounds healed, 89 percent of all limbs were salvaged, and 49 percent of patients survived. Revascularization improved the threatened limb's salvage rate from negligible to a level similar to that of the adequately vascularized limb. Fifteen out of 71 wounds did not heal because of the patient's early postoperative death, ischemia not amenable to revascularization, or noncompliance. Six below-knee amputations were performed (one despite a patent bypass and five in adequately vascularized patients). The average time for wounds to heal in the revascularized patients was 79 days versus 71 days in adequately vascularized patients. There was an overall 43 percent complication rate. Of the patients who were alive after the 3-year follow-up, 73 percent were independently ambulating, whereas 27 percent were bound to wheelchair or bed. Eighty-two percent of patients were very satisfied with the salvage attempt, 18 percent were moderately satisfied, and all patients said they would go through the process again. The authors believe that salvaging the threatened extremity in the renal failure diabetic patient is justified whether or not the limb requires revascularization. Revascularization improved the limb salvage rate, patient survival, and days for wounds to heal to a level comparable to that of the adequately vascularized limb. The key to subsequently achieving high salvage rates is the quality of perioperative wound care (e.g., serial debridements, antibiotics, dressings) and the timing and selection of appropriate soft-tissue coverage.     

Lower extremity microsurgical reconstruction

LEARNING OBJECTIVES: After studying this article, the participant should be able to: 1. Understand the indications for the use of free-tissue transfer in lower extremity reconstruction. 2. Understand modalities to enhance the healing and care of soft tissue and bone before free-tissue transfer. 3. Understand the lower extremity reconstructive ladder and the place of free-tissue transfer on the ladder. 4. Understand the specific principles of leg, foot, and ankle reconstruction. 5. Understand the factors that influence the decision to perform an immediate versus a delayed reconstruction. Free-tissue transfer using microsurgical techniques is now routine for the salvage of traumatized lower extremities. Indications for microvascular tissue transplantation for lower extremity reconstruction include high-energy injuries, most middle and distal-third tibial wounds, radiation wounds, osteomyelitis, nonunions, and tumor reconstruction. The authors discuss the techniques and indications for lower extremity reconstruction.     

Complications after reconstruction by plate and soft-tissue free flap in composite mandibular defects and secondary salvage reconstruction with osteocutaneous flap

Reconstruction of composite defects of the mandible is a challenging problem. Although the use of an osteocutaneous free flap, alone or in combination with another soft-tissue free flap, is generally accepted to be optimal, the bony reconstruction is sometimes undervalued, especially when the cancer is advanced. In such situations, reconstruction is often performed with a reconstruction plate covered with a soft-tissue free flap. Between January of 1997 and July of 2000, 80 patients with composite or extensive composite oromandibular defects underwent treatment with a reconstruction plate and a soft-tissue free flap. All of the patients were male, and the ages of the patients at the time of treatment ranged from 32 to 78 years (mean, 51 years). Tumors were classified as stage IV in 56 patients (70 percent), whereas the remaining 24 patients (30 percent) had recurrent carcinomas. The titanium mandibular reconstruction system manufactured by Stryker (Freiburg, Germany) was used to bridge the mandibular defects. The soft-tissue free flaps used for wound and plate coverage were as follows: anterolateral thigh flap (n = 75), radial forearm flap (n = 3), transverse rectus abdominis myocutaneous flap (n = 1), and tensor fasciae latae flap (n = 1). Five patients with recurrent carcinomas and 10 with stage IV carcinomas (18.75 percent) died 2 to 6 months after the operation and were excluded from the study. The remaining 65 patients were monitored for an average follow-up period of 22 months (range, 6 to 40 months). During that period, one or more complications occurred for 45 patients (69.2 percent). Plate exposure was the most common complication and was observed for 30 patients (46.15 percent). Twenty of the 65 patients (30.8 percent) required secondary salvage reconstruction with a fibula osteoseptocutaneous flap. The decision to perform a secondary salvage procedure was based on the general health of the patient, the extent of local disease, and the severity of the complications. Patients underwent salvage operations after an average of 11.5 months (range, 6 to 26 months). The major reasons for the second operation were as follows: reconstruction plate exposure (n = 12), soft-tissue deficiency and mandibular contour deformation of the lateral face (n = 7), intraoral contracture and lack of a gingivobuccal sulcus (n = 6), trismus (n = 4), and osteoradionecrosis of the mandible (n = 2). The total flap survival rate was 90 percent (18 of 20 free flaps). In two cases, the skin paddles of the fibula osteoseptocutaneous flaps exhibited partial failure and were revised with pedicled pectoralis major and deltopectoral flaps. The reconstruction plate and free soft-tissue flap procedure for the reconstruction of composite defects of the oromandibular region has many late complications, which eventually necessitate reconstruction of the mandible with an osteocutaneous free flap.     

One-stage reconstruction of composite bone and soft-tissue defects in traumatic lower extremities

Management of bone loss that occurs after severe trauma of open lower extremity fractures continues to challenge reconstructive surgeons. Sixty-one patients who had 62 traumatic open lower extremity fractures and combined bone and composite soft-tissue defects were treated with the following protocol: extensive debridement of necrotic tissues, eradication of infection, and vascularization of osteocutaneous tissue for one-stage bone and soft-tissue coverage reconstruction. The mechanism of injury included 49 motorcycle accidents (80.3 percent), five falls (8.2 percent), three crush injuries (4.9 percent), two pedestrian-automobile accidents (3.3 percent), and two motor vehicle accidents (3.3 percent). The bone defects were located in the tibia in 49 patients (79 percent; one patient had bilateral open tibial fractures), in the femur in seven patients (11.3 percent), in the calcaneus bone in four patients (6.5 percent), and in the metatarsal bones in two patients (3.2 percent). The size of soft-tissue defects ranged from 5 x 9 cm to 30 x 17 cm. The average length of the preoperative bony defect was 11.7 cm. The average duration from injury to one-stage reconstruction was 27.1 days, and the average number of previous extensive debridement procedures was 3.4. Fifty patients had vascularized fibula osteoseptocutaneous flaps, six had vascularized iliac osteocutaneous flaps, and five patients had seven combined vascularized rib transfers with serratus anterior muscle and/or latissimus dorsi muscle transfers. One patient received a second combined rib flap because the first combined rib flap failed. The rate of complete flap survival was 88.9 percent (56 of 63 flaps). Two combined vascularized rib transfers with serratus anterior muscle and latissimus dorsi muscle flaps were lost totally (3.2 percent) because of arterial thrombosis and deep infection, respectively. Partial skin flap losses were encountered in the five fibula osteoseptocutaneous flaps (7.9 percent). Postoperative infection for this one-stage reconstruction was 7.9 percent. Excluding the failed flap and the infected/amputated limb, the primary bony union rate after successful free vascularized bone grafting was 88.5 percent (54 of 61 transfers). The average primary union time was 6.9 months. The overall union rate was 96.7 percent (59 of 61 transfers). The average time to overall union was 8.5 months after surgery. Seven transferred vascularized bones had stress fractures, for a rate of 11.5 percent. Donor-site problems were noted in six fibular flaps, in two iliac flaps, and in one rib flap. The fibular donor-site problems were foot drop in one patient, superficial peroneal nerve palsy in one patient, contracture of the flexor hallucis longus muscle in two patients, and skin necrosis after split-thickness skin grafting in two patients. The iliac flap donor-site problems were temporary flank pain in one patient and lateral thigh numbness in the other. One rib flap transfer patient had pleural fibrosis. Transfer of the appropriate combination of vascularized bone and soft-tissue flap with a one-stage procedure provides complex lower extremity defects with successful functional results that are almost equal to the previously reported microsurgical staged procedures and conventional techniques.     

The serratus anterior free-muscle flap: experience with 100 consecutive cases

We report free serratus transplantation in 100 consecutive patients, 10 in combination with the latissimus muscle and 2 with rib. Transplantation was performed for extremity soft-tissue coverage, contour correction, and facial reanimation. Twenty-two patients received serratus transplantation as part of complex reconstruction requiring multiple microvascular transplants. Overall success was 99 percent, with a single flap failure. Four patients suffered partial flap loss. Emergent reexploration for suspected vascular occlusion was infrequent, required in six flaps (6.0 percent), with an 83 percent salvage rate. Significant complications occurred in 18 percent of recipient sites and 12 percent of donor sites, with eight patients developing seroma/hematoma. No scapular winging was noted, and all patients retained full shoulder range of motion. The serratus muscle flap is a highly reliable flap characterized by a consistently long pedicle, excellent malleability, and multipennate anatomy permitting coverage of complex three-dimensional wounds and consistent performance as a functional transplant. Underlying rib can be included as a myo-osseous flap to expand the versatility of this flap.     

Salvage of amputation stumps by secondary reconstruction utilizing microsurgical free-tissue transfer

During a 2-year period, 15 lower and upper extremity amputees were treated by microsurgical free-tissue transfer in an effort to salvage their amputation stumps. Salvage of length and restoration of contour to aid in prosthetic rehabilitation were the two main indications for reconstruction. Included in the 15 transfers were 3 scapular free flaps, 11 latissimus dorsi musculocutaneous flaps, and 1 groin flap. Thirteen of the patients in this group were refitted with prostheses following reconstruction and did well with no pain or skin breakdown of the resurfaced stumps. The follow-up period on these patients averaged 16 months. One patient, in whom the flap succeeded, underwent stump soft-tissue revision and myodesis. One patient, in whom the flap failed, continued to develop recurrent ulceration in his stump. This clinical experience followed an extensive laboratory study of 12 above-knee amputation patients using noninvasive Doppler ultrasound measurements to determine weight-loading and interface-pressure distribution between the stump and the socket of the prostheses and their relation to stump length and circumference.