Physiology in microgravity.

Studies of physiology in microgravity are remarkably recent, with almost all the data being obtained in the past 40 years. The first human spaceflight did not take place until 1961. Physiological measurements in connection with the early flights were crude, but, in the past 10 years, an enormous amount of new information has been obtained from experiments on Spacelab. The United States and Soviet/Russian programs have pursued different routes. The US has mainly concentrated on relatively short flights but with highly sophisticated equipment such as is available in Spacelab. In contrast, the Soviet/Russian program concentrated on first the Salyut and then the Mir space stations. These had the advantage of providing information about long-term exposure to microgravity, but the degree of sophistication of the measurements in space was less. It is hoped that the International Space Station will combine the best of both approaches. The most important physiological changes caused by microgravity include bone demineralization, skeletal muscle atrophy, vestibular problems causing space motion sickness, cardiovascular problems resulting in postflight orthostatic intolerance, and reductions in plasma volume and red cell mass. Pulmonary function is greatly altered but apparently not seriously impaired. Space exploration is a new frontier with long-term missions to the moon and Mars not far away. Understanding the physiological changes caused by long-duration microgravity remains a daunting challenge.     

Physiology of avian circadian pacemakers.

The pineal gland plays a cental role in the circadian organization of birds, although it is clearly only one component in a system with other components that have not yet been positively identified. The relative importance of the pineal and other components may vary from one group of birds to another. In the most thoroughly studied species, the house sparrow, pineal removal abolishes circadian rhythmicity; rhythmicity is restored by transplantation of a donor bird's pineal and the restored rhythm has the phase of the donor. This, and other evidence, argues convincingly that the pineal is a pacemaker in the sparrow circadian system. The pineal of the chicken has circadian rhythms in several biochemical parameters that result in the rhythmic synthesis of melatonin. The activity of one enzyme in this pathway is rhythmic for at least two cycles in organ culture. In view of this result it is interesting that pineal removal does not abolish circadian rhythmicity in chickens. The fact that lesions of the suprachiasmatic nuclei abolish circadian rhythms in sparrows, several mammalian species, and perhaps Japanese quail and reptiles, suggests that vertebrate circadian organization may be based on differentially weighted interactions between the pineal, the suprachiasmatic nuclei, and perhaps other brain regions.     

Physiology of the ECL cells.

The enterochromaffin-like (ECL) cells of the oxyntic mucosa (fundus) of the stomach produce, store and secrete histamine, chromogranin A-derived peptides such as pancreastatin, and an unanticipated but as yet unidentified peptide hormone. The cells are stimulated by gastrin and pituitary adenylate cyclase activating peptide and suppressed by somatostatin and galanin. Choline esters and histamine seem to be without effect on ECL cell secretion. The existence of a gastrin-ECL cell axis not only explains how gastrin stimulates acid secretion but also may help to explore the functional significance of the ECL cells with respect to the nature and bioactivity of its peptide hormone. From the results of studies of gastrectomized/fundectomized and gastrin-treated rats, it has been speculated that the anticipated ECL-cell peptide hormone acts on bone metabolism.