Alfred J. Casillan

Bowel necrosis caused by water in jejunal feeding.

BACKGROUND Fifteen reports of bowel necrosis in patients receiving jejunal feeding have been reported. Etiology remains unexplained. METHODS A patient with a 60% burn receiving jejunostomy tube feeding developed hypernatremia and was given distilled water in the jejunum, 400 mL every 2 hours. One week later, he developed an acute abdomen with abdominal distention. At operation, he had 4 L of cloudy fluid containing jejunal feeding. Three large duodenal perforations were present. The jejunostomy site was normal. In an animal study, water or normal saline (0.85% NaCl) were infused into the mid small bowel, and sections of bowel were taken 5 minutes later for histologic study. RESULTS Animal study of the effect of water in the rat intestine revealed disruption of intestinal epithelium. It is suggested that disruption of epithelium by electrolyte-free water may permit digestion of the bowel wall and result in perforation, as was observed in this patient. This mechanism may have been responsible for some of the cases reported in the literature. CONCLUSIONS Tap or distilled water may injure intestinal epithelium and should not be infused directly into the small bowel as jejunal feeding.

Deferoxamine mimics the pattern of hypoxia-related injury at the microvasculature

Oxygen is essential for the maintenance of life, and when oxygen levels decline to critical levels, a program of complex mechanisms exists to i) sense hypoxia, ii) respond to minimize acute tissue injury, and iii) result in adaptations that offer protection against further hypoxia challenges. Alternative adaptation-related protection may also be inducible through the increased activity of hypoxia-inducible factors activated by hypoxia mimics such as iron chelation with deferoxamine (DFA). We have characterized a set of hypoxia-related responses at the microvasculature and postulated that microvascular injury in response to hypoxia could be reproduced by the reduction of bioavailable iron through chelation by DFA. We were able to induce a similar degree of leukocyte adherence and emigration and vascular leak with DFA infusion as compared with hypoxia exposure in an intact physiological rodent model. However, in contrast to hypoxia-exposed groups, we were unable to detect reactive oxygen species or alter the injury pattern with reactive oxygen species scavenger in the groups treated with DFA. Thus, we demonstrate that DFA mimics the pattern and intensity of hypoxia-related injury on the microvasculature; however, differences in the time course and mechanism of injury were identified. In addition, DFA saturated with iron did not completely reverse the effects of DFA, suggesting a mechanism(s) beyond a reduction in the bioavailability of iron. These findings may have importance in the targeting of iron for the development of hypoxia mimics that may offer protection against subsequent hypoxia exposure in clinical setting such as myocardial infarction and stroke.

Acclimatization of the systemic microcirculation to alveolar hypoxia is mediated by an iNOS-dependent increase in nitric oxide availability

Rats breathing 10% O2 show a rapid and widespread systemic microvascular inflammation that results from nitric oxide (NO) depletion secondary to increased reactive O2 species (ROS) generation. The inflammation eventually resolves, and the microcirculation becomes resistant to more severe hypoxia. These experiments were directed to determine the mechanisms underlying this microvascular acclimatization process. Intravital microscopy of the mesentery showed that after 3 wk of hypoxia (barometric pressure ~380 Torr; partial pressure of inspired O2 ~68-70 Torr), rats showed no evidence of inflammation; however, treatment with the inducible NO synthase (iNOS) inhibitor L-N6-(1-iminoethyl) lysine dihydrochloride led to ROS generation, leukocyte-endothelial adherence and emigration, and increased vascular permeability. Mast cells harvested from normoxic rats underwent degranulation when exposed in vitro to monocyte chemoattractant protein-1 (MCP-1), the proximate mediator of mast cell degranulation in acute hypoxia. Mast cell degranulation by MCP-1 was prevented by the NO donor spermine-NONOate. MCP-1 did not induce degranulation of mast cells harvested from 6-day hypoxic rats; however, pretreatment with either the general NOS inhibitor L-NG-monomethyl arginine citrate or the selective iNOS inhibitor N-[3-(aminomethyl) benzyl] acetamidine restored the effect of MCP-1. iNOS was demonstrated in mast cells and alveolar macrophages of acclimatized rats. Nitrate + nitrite plasma levels decreased significantly in acute hypoxia and were restored after 6 days of acclimatization. The results support the hypothesis that the microvascular acclimatization to hypoxia results from the restoration of the ROS/NO balance mediated by iNOS expression at key sites in the inflammatory cascade.NEW & NOTEWORTHY The study shows that the systemic inflammation of acute hypoxia resolves via an inducible nitric oxide (NO) synthase-induced restoration of the reactive O2 species/NO balance in the systemic microcirculation. It is proposed that the acute systemic inflammation may represent the first step of the microvascular acclimatization process.