ABSTRACT
Reconstruction of lower limb defects is a constant challenge for surgeons, the etiology of the defect can be very variable from diabetic ulcers, traffic accidents, fall from height, oncological resections and many others. Free flaps have always been an important option because it has great results in complex reconstructions in lower limbs, it is a microvascular technique, so it has a higher level of complexity. This technique is usually reserved for extensive perilesional wide defects. On the other hand, the propeller flap, which is considered less invasive and easier as it does not involve microvascular surgery. An 18-year-old patient who had a fracture of the right tibial pylon due to a 7-meter drop, who after orthopedic treatment had a defect with exposure of ostesynthesis material of 3 cm in circumference in the medial malleolus. This defect was first managed with a propeller flap complicated with necrosis at 48 hours which was treated with sub atmospheric pressure system for 5 days and later with an ultra-thin anterolateral flap of the pelvic limb. Complete pedicled propeller flap failure is very rare but, because necrosis develops distally, even partial necrosis can expose bone, tendons, or other tissue. Some surgeons consider that propeller flap placement is risky in this location, especially the distal third of the lower leg a prefer to use free flaps. Whenever any pelvic member reconstruction plan fails in the distal third, the best and safest is the use of microsurgery even with the failure of a previous micro vascular flap.
ABSTRACT
Acute pulmonary damage caused by transfusion is characterized by the sudden onset of respiratory distress in newly transfused patients within 6 hours after the transfusion, bilateral infiltrative changes in chest X-ray, PaO2/FIO2 <300 mmHg, absence of other risk factors for acute lung injury and absence of signs suggesting cardiogenic origin of pulmonary edema. Being one of the most serious complications of blood transfusion, plasma is the most involved factor, although all blood components can cause it, and is caused by antigen reactions/leukocyte antibody and lipid activity with ability to modify the biological response on primitive leukocytes. The diagnosis is based on the integration of clinical, radiological and gasometric elements, ruling out the rest of the possible causes of acute lung injury. Its differential diagnosis should include hemodynamic overload, anaphylactic reaction, bacterial contamination of transfused blood products and transfusion hemolytic reaction. The treatment is supportive measures based on the needs and does not differ from the treatment of acute lung injury secondary to other etiologies, severe cases require endotracheal intubation and mechanical ventilation while the non-severe can be managed with oxygen therapy.
ABSTRACT
Tissue engineering has been widely used for its great variety of functions. It has been seen as a solution to satisfy the need for vascular substitutes like small diameter vessels, veins, and nerves. One of the most used methods is electrospinning, due to the fact that it allows the use of various polymers, sizes, mandrels and it can adjust the conditions to create personalized scaffolds. For the creation of scaffolds is fundamental to understand the advantages and disadvantages of each polymer, of this, will depend the biodegradability, biocompatibility, porosity, cellular adhesion, and cell proliferation as it is essential to mimic the extracellular matrix and provide structural support for the cells. The aim of this review was to investigate which materials are being used for the creation of tubular scaffolds by electrospinning. Here we selected only in vivo evaluation to demonstrate remodeling of the grafts into native-like tissues, in vitro evaluations had been excluded from this review. We analyze the conditions like speed, distance and voltage and the modifications like growth factors and combinations of natural and synthetic polymers that allow the authors to have a functional scaffold that will suit its purpose.