Gut protein uptake and mechanisms of meal-induced cortisol release.

The enhanced cortisol release after protein-rich meals might represent a neuroendocrine response to food allergens. We tested whether the antigenicity of proteins contributes to this effect. Twelve healthy men nasogastrically received casein, its less allergenic hydrolysate, and placebo. Contrary to expectations, secretion of cortisol (area under the curve, 742.70 +/- 73.48 vs. 542.95 +/- 70.31 micromol/liter.min, P < 0.03) and ACTH (2020.21 +/- 251.10 vs. 1649.82 +/- 241.23 micromol/liter.min, P < 0.05) was stronger on casein-hydrolysate than casein. Systemic immune activity remained unaffected as indicated by unchanged IL-6 plasma concentrations. This finding indicates that the grade of hydrolysis of a protein and the presence of particular amino acids, rather than its antigenicity, are crucial for the pituitary-adrenal response to nutrients. To further examine whether this response is triggered at the gastrointestinal mucosa or after the substance has reached the circulation, in a supplementary experiment, amino acids were given either nasogastrically or iv to healthy men (n = 4). Only the nasogastric infusion of amino acids induced a significant rise in cortisol concentrations. Serum concentrations of tryptophan, which is known to directly excite the hypothalamo-pituitary-adrenal axis, were comparable for both conditions. We conclude that the meal-related hypothalamo-pituitary-adrenal axis response to amino acids results from a signal that rather acts at the gastrointestinal mucosa than directly via the circulating blood.

Melatonin acutely improves the neuroendocrine architecture of sleep in blind individuals.

In blind individuals, the absence of light cues results in disturbances of sleep and sleep-related neuroendocrine patterns. The Zeitgeber influence of light on the timing of sleep is assumed to be mediated by melatonin, a hormone of the pineal gland, whose secretion is inhibited by light and enhanced during darkness. Here, we investigated whether a single administration of melatonin improves sleep and associated neuroendocrine patterns in blind individuals. In a double-blind crossover study, 12 totally blind subjects received 5 mg melatonin and placebo orally 1 h before bedtime starting at 2300 h. The dose used enhanced blood melatonin concentrations to clearly supraphysiological levels. Melatonin increased total sleep time and sleep efficiency (P < 0.05, respectively) and reduced time awake (P < 0.05). The increment in total sleep time was primarily due to an increase in stage 2 sleep (P < 0.01) and a slight increase in rapid eye movement sleep (P < 0.06). Most important, melatonin normalized in parallel the temporal pattern of ACTH and cortisol plasma concentration. While after placebo, ACTH and cortisol levels did not differ between early and late sleep, melatonin induced the typical suppression of pituitary-adrenal activity during early sleep and a distinct rise during late sleep (P < 0.01, respectively). Cortisol nadir values were also decreased after melatonin (P < 0.05). We conclude from these data that in totally blind individuals the single administration of a clearly pharmacological dose of melatonin can improve sleep function by synchronizing in time the inhibition of pituitary-adrenal activity with central nervous sleep processes.

EEG theta synchronization conjoined with alpha desynchronization indicate intentional encoding.

The involvement of different oscillating neuronal systems activated during intentional learning was investigated by measuring ongoing EEG activity. In 17 subjects, the EEG was recorded while learning pairs of words and faces. Subjective task difficulty was rated and a control condition of mental relaxation was also run. Spontaneous EEG activity during epochs which subsequently resulted in efficient encoding was associated with upper alpha desynchronization (10-12 Hz) and theta synchronization (4-8 Hz) when compared with spontaneous EEG activity during epochs of poor recall performance. The combined measure of theta synchronization plus upper alpha desynchronization was enhanced selectively over left frontotemporal cortical regions during efficient learning of words and over right parietal cortical regions during efficient learning of faces (P < 0.001). This striking topographical dissociation between learning materials for the combined measure of theta and upper alpha EEG activity suggests that the mode of intentional learning relies essentially on an interdependent regulation of two neuronal circuits: the thalamo-cortical circuit and the hippocampo-cortical circuit.