The effect of hypoxemic reperfusion on cerebral protection after a severe global ischemic brain insult.

BACKGROUND AND PURPOSE: Reactive oxygen species contribute to membrane lipid peroxidation and neuronal death and have been implicated in anoxic encephalopathy. We tested whether hypoxemic reperfusion (HR) after global cerebral ischemia would improve neurological recovery. METHODS: Two groups of pigs (n = 11 in each group) were subjected to a model of a 10-min global cerebral and systemic ischemia to compare the effect of hypoxemic reperfusion (group HR) with the classical hyperoxemic control (group C). A third group not subjected to ischemia served as control to the control group (n = 6, group CC), but received hyperoxygenation at the respective period of reperfusion. The outcome was evaluated by means of neurological assessment and the extent of lipid peroxidation measuring the plasma malonaldehyde (MDA) together with hydroxyalkenals (HALK). RESULTS: Animals of group HR exhibited a significantly superior neurological outcome compared with those of group C at all three consecutive assessments after reperfusion (post-resuscitation P = 0.006, at 8 h P = 0.003, and at 24 h P = 0.007). The levels of MDA and HALK are lower in the HR group than in group C (P = 0.029). Additionally, in the CC group these molecules increased significantly early at hyperoxygenation (P = 0.02). A faster lactate metabolism in the HR group was observed during reperfusion, though non-significant. CONCLUSIONS: Hypoxemic reperfusion during resuscitation from a severe global ischemic cerebral insult improves the neurological outcome compared with classic hyperoxemic reperfusion. This is additionally confirmed by the decreased production of the molecules of lipid peroxidation. In the absence of preceding ischemia, these molecules may increase by simple over-oxygenation.

Diurnal changes in glucocorticoid sensitivity in human peripheral blood samples.

The secretion of cortisol, a principle homeostatic regulator in humans, shows a circadian rhythm, with high concentrations in the morning and low levels in the evening and at night. Tissue response to hormones is dependent on hormone concentrations but also on a variety of cellular factors, such as hormone receptors, transcription factors, and activators. In this report, we evaluated whether cell sensitivity to glucocorticoids (GCs) is also subject to diurnal variation using a whole cell system (whole blood samples) stimulated by lipopolysacharide to induce the production of tumor necrosis factor (TNF-alpha); the induction of TNF-alpha is inhibited by dexamethasone. Blood samples obtained in the morning (08.30-09.00 h) and in the evening (22.30-23.00 h) from 37 healthy individuals (18 males, 19 females) aged 29+/-3 years were treated with lipopolysacharide in the presence or absence of 10(-6) M dexamethasone, and the percentage of inhibition of TNF-alpha production was used as an index of sensitivity to GCs. The mean +/- SD in morning samples was 43.5+/-13.8% for the general population, 42.3+/-14.0% for males and 44.6+/-13.8% for females, whereas that in the evening samples was 36.5+/-15.7%, 35.6+/-13.8% and 37.4+/-17.7%, respectively. The results support a significantly increased sensitivity to GCs in the morning hours compared with that in the evening in the general population (P<0.001) as well as in males (P<0.001) and in females (P<0.001). No sex related differences in sensitivity to GCs were observed in the morning or in the evening hours. The sensitive and reproducible assay utilized in this study could also be used to investigate the sensitivity to GCs in various diseases characterized by resistance to GCs and/or alterations in glucocorticoid receptor function.