Alexandros E. Beris

Vascularized fibula transfer for lower limb reconstruction

Massive bony defects of the lower extremity are usually the result of high‐energy trauma, tumor resection, or severe sepsis. Vascularized fibular grafts are useful in the reconstruction of large skeletal defects, especially in cases of scarred and avascular recipient sites, or in patients with combined bone and soft‐tissue defects. Microvascular free fibula transfer is considered the most suitable autograft for reconstruction of the middle tibia because of its long cylindrical straight shape, mechanical strength, predictable vascular pedicle, and hypertrophy potential. The ability to fold the free fibula into two segments or to combine it with massive allografts is a useful technique for reconstruction of massive bone defects of the femur or proximal tibia. It can also be transferred with skin, fascia, or muscle as a composite flap. Proximal epiphyseal fibula transfer has the potential for longitudinal growth and can be used in the hip joint remodeling procedures. Complications can be minimized by careful preoperative planning of the procedure, meticulous intraoperative microsurgical techniques, and strict postoperative rehabilitation protocols. This literature review highlights the different surgical techniques, indications, results, factors influencing the outcome, and major complications of free vascularized fibular graft for management of skeletal or composite defects of the lower limb.

Femoral head osteonecrosis: why choose free vascularized fibula grafting.

Osteonecrosis of the femoral head is a disease in which bone death occurs and usually progresses to articular incongruity and subsequent osteoarthritis. To delay the process of the disease and the conversion to total hip arthroplasty, many surgical techniques have been described. Core decompression, nonvascularized autologous bone grafts, porous tantalum implant procedure, and various osteotomies have been used for the management of early precollapse stage osteonecrosis of the femoral head. However, none of these procedures is neither entirely effective nor can obtain predictable results. With the progress of microsurgery, the implantation of a free vascularized fibula graft to the necrotic femoral head has provided the most consistently successful results. Although the procedure is technically demanding, there is growing recognition that the use of free vascularized fibula graft may improve patient quality of life by functional improvement and pain alleviation. The success of the procedure is related to decompression of the femoral head, excision of the necrotic bone, and addition of cancellous bone graft with osteoinductive and osteoconductive properties, which augments revascularization and neoosteogenesis of the femoral head. Free vascularized fibula graft, especially in younger patients, is a salvaging procedure of the necrotic femoral head in early precollapse stages. In postcollapse osteonecrosis, the procedure appears to delay the need for total hip arthroplasty in the majority of patients. The purpose of this review article is to update knowledge about treatment strategies in femoral head osteonecrosis and to compare free vascularized fibula grafting to traditional and new treatment modalities.

The free vascularized fibular graft for bridging large skeletal defects of the upper extremity

Large skeletal defects of the upper extremity pose a serious clinical problem with potentially deleterious effects on both function and viability of the limb. Recent advances in the microsurgical techniques involved in free vascularized bone transfers for complex limb injuries have dramatically improved limb salvage and musculoskeletal reconstruction. This study evaluates the clinical and radiographic results of 18 patients who underwent reconstruction of large defects of the long bones of the upper extremity with free vascularized fibular bone grafts. Mean patient age was 27 years (7−43 years) and mean follow‐up was 4 years (1−10 years). The results confirm the value of vascularized fibular grafts for bridging large bone defects in the upper extremity.

Management of obstetrical brachial plexus palsy with early plexus microreconstruction and late muscle transfers

Birth brachial plexus injury usually affects the upper roots. In most cases, spontaneous reinnervation occurs in a variable degree. This aberrant reinnervation leaves characteristic deformities of the shoulder, elbow, forearm, wrist, and hand. Common sequelae are the internal rotation and adduction deformity of the shoulder, elbow flexion contractures, forearm supination deformity, and lack of wrist extension and finger flexion. Nowadays, the strategy in the management of obstetrical brachial plexus palsy focuses in close follow‐up of the baby up to 3–6 months and if there are no signs of recovery, microsurgical repair is indicated. Nonetheless, palliative surgery consisting of an ensemble of secondary procedures is used to further improve the overall function of the upper extremity in patients who present late or fail to improve after primary management. These secondary procedures include transfers of free vascularized and neurotized muscles. We present and discuss our experience in treating early and/or late obstetrical palsies utilizing the above‐mentioned microsurgical strategy and review the literature on the management of brachial plexus birth palsy.

Vascularized free fibular bone graft in the management of congenital tibial pseudarthrosis

Congenital pseudarthrosis of the tibia (CPT) remains one of the most challenging problems confronting the orthopaedic surgeon. The operative results are frequently less than successful; many cases require several surgical procedures, and a significant number of them ending in amputation. The purpose of this study was to access the surgical results, complications, secondary procedures, and long‐term results of free vascularized fibular graft (FVFG) in the treatment of congenital pseudarthrosis of the tibia. Between 1992 and 2007, nine patients with CPT were treated consecutively at our clinic with free fibula transfer. There were six females and three males. The mean age at the time of operation was 6.5 years (range, 1–12 years). Stability, after reconstruction with FVFG, was maintained with internal fixation in five patients, unilateral frame external fixation in three patients, and intramedullary pin in one patient. Average postoperative follow‐up time was 9 years (range, 2–15 years). In seven patients, both ends of the graft healed primarily within 3.7 months (range, 1.5–6 months). In one patient, the distal end of the graft did not unit. This patient required three subsequent operations to achieve union. Stress fracture occurred in the middle of the grafted fibula in one patient, who underwent four additional operations before union, was achieved. Despite the relatively high‐complication rate, FVFG remains a valid method for the treatment of CPT. However, even achieving union of pseudarthrosis is not enough for the resolution of the disease. This is only half of the problem; the other half is to maintain union. Long‐term follow‐up beyond skeletal maturity, if possible, is necessary to evaluate surgical results.

Functional assessment of the rat sciatic nerve following intraoperative expansion: The effect of recovery duration on behavioural, neurophysiological, and morphological measures

The purpose of this study was to investigate the feasibility of rapid intraoperative elongation of the rat sciatic nerve with the use of tissue expander and to assess its functional recovery. Out of 51 rats 43 had their right sciatic nerve expanded with a 5‐ml intraoperative expander over 1 hr and 8 were sham‐operated controls. The functional recovery of the nerve was assessed at intervals up to 4 months using the Sciatic Functional index (SFI), neurophysiological indices, and histology. Intraoperative expansion elongated the rat sciatic nerve by about 13%. SFI decreased on the first postoperative day and started to recover by Day 7, reaching almost preoperative values by Days 14 and 30 according to De Medinaceli and Bain‐Mackinnon‐Hunter formulas, respectively. Latency and motor conduction velocity demonstrated a deterioration after expansion which peaked on Day 1. Recovery started by Day 7 and reached preoperative levels by 60 days. The histological findings indicated minor aberrations immediately after expansion and maximal demyelination with minimal axonal disruption on Day 1. The reparative process started by Day 7 and continued till Day 120 when almost no histological changes were observed. In conclusion, intraoperative nerve expansion successfully elongates the rat sciatic nerve. It also causes functional and morphological abnormalities which are of low to moderate degree, have a short duration, and are reversible. Intraoperative nerve expansion might be a valuable solution in the treatment of short nerve gaps, but its clinical application still needs to be evaluated. MICROSURGERY 17:568–577 1996