How to Transform a Perforator Propeller Flap into a Keystone Flap in Case of Unsatisfying Perforator Vessel Local Perforator Flap Coverage in Limbs.

Moderate soft-tissue defects need stable coverage, ideally with tissue of similar characteristics and low donor site morbidity. We propose a simple technique for the coverage of moderate skin defects in the limbs. It allows intraoperative transformation of a propeller perforator flap (PPF) into a keystone design perforator flap (KDPF) in cases of unsatisfying perforator vessel or in cases of unpredictable intraoperative events. Between March 2013 and July 2019, nine patients with moderate soft-tissue defects (mean defect size 4.5 × 7.6 cm) in the limbs (two on the upper limbs and seven on the lower limbs) were covered using this technique. We performed four PPFs and five KDPFs. The mean follow-up was 5 months. There was one complication, partial distal tip necrosis in a PPF located in the leg, which healed by secondary intention within 3 weeks. The donor site was closed directly in all cases. No functional impairments were noted regardless of the perforator flap utilized. This technique enables us to employ flexible surgical strategies and allows us to make adjustments based on the patient's vascular anatomy.

Autologous Gluteal Augmentation with Parasacral Perforator-Pedicled Propeller Flaps.

BACKGROUND: De-epithelialized flaps have been used in gluteal contouring over the last three decades, but most improve the projection rather than the upper quadrants. The authors provide a detailed description of their method of gluteal augmentation using parasacral perforator-pedicled propeller flaps. This technique achieves a volumetric increase and maximal buttock projection at the midlevel and in the medial half of the buttocks. METHODS: Between January and December of 2019, a series of 18 patients on whom a lower body lift with a parasacral perforator-pedicled propeller flap had been performed by the senior author (F.B.) were prospectively evaluated. Postoperatively, the satisfaction rate was assessed using a 10-point analog scale (1 = unsatisfied, 10 = very satisfied) by the patient and by two independent surgeons based on photographs taken 1 year after surgery. RESULTS: Eighteen patients underwent this procedure. Their mean age was 32.2 ± 5.6 years (range, 24 to 40 years). The mean flap length was 20.3 cm, their mean width was 10.4 cm, and the mean thickness was 3.4 cm. The authors noted only two minor complications, one seroma and two skin dehiscences that healed without surgery. The rate of satisfaction as assessed by the patients was 8.3 out of 10 (±1.1), and by surgeons, 7.9 and 8.1. CONCLUSION: This article describes a gluteal autoaugmentation flap technique using parasacral perforator-pedicled propeller flaps to increase projection and volume in the inferomedial gluteal region after lower body lift. CLINICAL QUESTION/LEVEL OF EVIDENCE: Therapeutic, IV.

Transplantation of mesenchymal stem cells cultured on biomatrix support induces repairing of digestive tract defects, in animal model.

Transplanted mesenchymal stem cells (MSCs) appear to play a significant role in adult tissue repair. The aim of this research was to obtain MSCs enriched, three dimensional (3D) patches for transplant, and to test their ability to induce repair of iatrogenic digestive tract defects in rats. MSCs were obtained from human and rat bone marrow, cultured in vitro, and seeded in a collagen-agarose scaffold, where they showed enhanced viability and proliferation. The phenotype of the cultured cells was representative for MSCs (CD105+, CD90+, and CD34-, CD45-, CD3-, CD14-). The 3D patch was obtained by laying the MSCs enriched collagen-agarose scaffold on a human or swine aortic fragment. After excision of small portions of the rat digestive tract, the 3D patches were sutured at the edge of the defect using micro-surgical techniques. The rats were sacrificed at time-points and the regeneration of the digestive wall was investigated by immunofluorescence, light and electron microscopy. The MSCs enriched 3D patches were biocompatible, biodegradable, and prompted the regeneration of the four layers of the stomach and intestine wall in rats. Human cells were identified in the rat regenerated digestive wall as a hallmark of the transplanted MSCs. For the first time we constructed 3D patches made of cultured bone marrow MSCs, embedded into a collagen-rich biomatrix, on vascular bio-material support, and transplanted them in order to repair iatrogenic digestive tract defects. The result was a complete repair with preservation of the four layered structure of the digestive wall.