Evidence for an early free radical-mediated reperfusion injury in frostbite.

Frostbite is characterized by acute tissue injury induced by freezing and thawing. Initial complete ischemia is followed by reperfusion and later, tissue necrosis. These vascular events support the hypothesis that free radical-mediated reperfusion injury at thawing might contribute to tissue necrosis after frostbite in a manner similar to that seen after normothermic ischemia. To test this hypothesis, rabbit ears were frozen at -21 degrees C for 30, 60, 90, or 120 s and rewarmed at room temperature (22 degrees C). Rabbits were treated "blindly" with saline alone, highly purified, pharmaceutical grade superoxide dismutase (SOD), allopurinol, or deferoxamine. The area of ear necrosis was determined 3 weeks after frostbite by "blinded" morphometry. The administration of SOD at the time of thawing significantly improved viability in ears frozen for 60 and 90 s, but not in those frozen for 30 or 120 s. Deferoxamine also improved viability in ears frozen for 60 s. Allopurinol did not significantly affect ear survival. Electron micrographs showed the appearance of severe endothelial cell injury beginning during freezing and extending through early reperfusion. Later, neutrophil adhesion, erythrocyte aggregation, and microvascular stasis were seen. These findings suggest that free radical-mediated reperfusion injury has a role in frostbite, and quantitate the proportion of the injury that is due to this mechanism.

Morphologic characterization of acute injury to vascular endothelium of skin after frostbite.

Cyclo-oxygenase inhibitors and free-radical scavengers protect the skin against necrosis induced by frostbite. However, the tissue component(s) that determine the evolution of skin necrosis and the mechanism of this pharmacologic protection are not precisely defined. We have studied freezing injury to rabbit ears by serial biopsies examined by light and electron microscopy. The morphologic evidence of skin injury due to freezing was localized exclusively in the endothelial cells, particularly in the arterioles. Within 1 hour, the entire microvasculature demonstrated endothelial damage. Intravascular platelet aggregation occurred just after thawing and closely paralleled the endothelial cell injury. Very few neutrophils were seen initially (at 10 minutes). By 1 hour, leukocyte aggregates were present, and they further increased at 6 hours. Swelling of the interstitium started 10 minutes after thawing, while extravasation of erythrocytes began to appear by 6 hours. Parenchymal elements of skin were relatively free of damage. In the ear cartilage, the chondrocytes showed evidence of damage immediately after freezing. The administration of superoxide dismutase (SOD) during thawing (reperfusion) did not qualitatively alter any of the initial morphologic changes induced by freezing. We conclude that the endothelial cell is the initial target of injury induced by freezing, an initial injury that is mediated by a non-free-radical-mediated mechanism. It is likely that this acute injury ultimately compromises blood flow and leads to skin necrosis.

Functional and structural evaluation of the vasculature of skin flaps after ischemia and reperfusion.

Free radicals and other toxic oxygen species play a role in the pathogenesis of ischemic organ damage. The abdominal skin flap has been used as a model to study the effects of superoxide dismutase on the survival of ischemic skin. We have evaluated the evolution of functional and structural injury to the vasculature after ischemic injury in superoxide dismutase-treated and control skin flaps. Ischemia was induced by creating abdominal skin flaps and occluding either the venous or both the venous and arterial blood supplies. Superoxide dismutase was administered immediately after the occlusion was released. At 1 hour of reflow, erythrocyte stasis, platelet deposition, neutrophil adherence, and injury to the endothelium of the large vessels and of the microvasculature were evident. The blood flow in the ischemic skin was only 3 percent of normal. Superoxide dismutase caused no change in the ultrastructure of the vasculature and a marginal decrease in vascular permeability in the ischemic skin at 1 hour of reflow. Increased fluorescent staining of the skin was evident after 24 hours of reflow in the superoxide dismutase-treated flaps. These findings indicate that injury to vascular endothelium by ischemia and reperfusion plays a role in the evolution of skin necrosis.