Experience with the distally based sural flap: a review of 25 cases.

The reconstruction of soft tissue defects in the distal areas of the lower extremity remains a challenge. The distally based sural neurocutaneous flap based on the sural nerve and the superficial sural artery has been used for skin defect reconstruction of the distal third of the leg, the hindfoot, ankle, and heel. We describe our experience and evaluate the reliability of this surgical technique. From 2004-2010, 25 patients with an average age of 32.5 (6 to 70) years were treated using the distally based sural flap for reconstruction of skin defects of the lower third of the leg, the heel, the ankle, and the hindfoot. The skin defect was secondary to trauma in 20 patients (80%) and compromised tendon or bone in all cases. One venous congestion and 2 partial flap necroses were observed. The mean follow-up was 25 (9 to 46) months. The plastic result was assessed as satisfactory in all patients. The donor site morbidity was minimal. The sural flap is a good way to reconstruct soft tissue defects of the lower extremity; this surgical technique provides an alternative to microsurgical reconstruction.

Progressive correction of severe spinal deformities with halo-gravity traction.

Treatment of rigid and severe spinal deformities is challenging and risky. Preoperative halo-gravity traction can be used to progressively reduce the deformity before spinal fusion. The aim of this study was to evaluate the effectiveness of halo-gravity traction for the correction of severe spinal deformities. Fifteen patients were reviewed retrospectively. Their mean age at the beginning of traction was 13.5 years. The mean duration of traction was 64 days. The main curve in the coronal plane improved from +/- 95 degrees to +/- 67 degrees, a gain of +/- 28 degrees (range 0 degrees-50 degrees) or +/- 30%. The curve in the sagittal plane improved from +/- 96 degrees to +/- 78 degrees, a gain of +/- 18 degrees (range 0 degrees-45 degrees) or +/- 19%. Other authors report gains up to 46% and 43%, respectively in the coronal and in the sagittal plane, but this might be due to different conditions, techniques, and evaluations. One patient with a pre-existing neurological deficit developed paraplegia. According to the literature congenital curves with associated kyphosis are exposed to paraplegia. Halo-gravity traction is effective and is usually tolerated better than other techniques of traction using the halo device.

Does endoscopic piriformis tenotomy provide safe and complete tendon release? A cadaver study.

BACKGROUND: Endoscopic piriformis release (EPR) is among the available treatments for piriformis syndrome. This procedure typically involves dividing the muscle near the sciatic nerve in the sub-gluteal space, which contains numerous blood vessels and nerves. The objectives of this prospective cadaver study were: 1) to assess the reproducibility and quality of endoscopic piriformis tenotomy near the greater trochanter; 2) to detect iatrogenic injuries to the lateral hip rotators, nerves, and vessels; 3) and to define the surgical safety margins relative to the sciatic nerve and inferior gluteal bundle. HYPOTHESIS: EPR at the greater trochanter ensures full release of the muscle with a limited risk of neuro-vascular injury. MATERIAL AND METHODS: EPR was performed via two portals on 10 cadaver hips preserved in zinc chloride and placed in the prone position. A third, ancillary portal was required in 7 cases. The area was then dissected with the Kocher-Langenbeck approach to allow an assessment of the tenotomy, detect iatrogenic injuries, and measure the distances separating the tenotomy site from the sciatic nerve and inferior gluteal artery. RESULTS: Complete tenotomy was achieved in 9 (90%) cases. The tendon adhered to the capsule in 2 (20%) cases and showed acquired avulsion in 1 case. No injuries to the sciatic nerve or inferior gluteal artery occurred. Mean distances from the tenotomy site were 5.21±0.59cm (range, 4.5-6.6cm) for the sciatic nerve and 7.1±0.89cm (range, 5.4-8.5cm) for the inferior gluteal artery. DISCUSSION: EPR by a tenotomy at the greater trochanter without sciatic nerve release provides full release of the muscle with satisfactory safety margins and a short learning curve. LEVEL OF EVIDENCE: III, prospective cadaver case-control study.