Pineal gland speaks to the brain.Pineal gland pineal gland (pĭn`eəl), small organ (about the size of a pea) situated in the brain. Long considered vestigial in humans, the structure, which is also called the pineal body or the epiphysis, is present in most vertebrates. speaks to brain The mammalian pineal gland, which sets the daily rhythm of hormone release that underlies many seasonal patterns of growth and behavior, keeps time in response to nerve signals received from the brain. Scientists have believed that the nerve signals go just one way--no nerve signals travel from the pineal gland back to the brain. But in the Feb. 14 SCIENCE, researchers at the National Institutes of Health (NIH "Not invented here." See digispeak. NIH - The United States National Institutes of Health. ) in Bethesda, Md., and at the Justus-Liebig University of Giessen The University of Gießen (German: Universität Gießen) is officially called Justus Liebig-Universität Gießen after its most famous member, Justus von Liebig, the founder of modern agricultural chemistry and inventor of artificial fertiliser. in West Germany West Germany: see Germany. report evidence of connections from the pineal pineal /pin·e·al/ (pin´e-il) 1. pertaining to the pineal body. 2. shaped like a pine cone. pin·e·al adj. 1. Having the form of a pine cone. 2. to the brain. The finding "dramatically cha ges our concept of the mammalian pineal gland," says David Klein of NIH. To search to pineal-to-brain connections, the scientists took advantage of recently discovered similarities between the pineal gland and the retina of the eye (SN: 11/9/85, p. 298). From vision researchers, they borrowed a fluorescently labeled antibody that binds to a protein called S-antigen, found in both the eye and the pineal but not in other parts of the brain. In experiments on hamsters, the antibody revealed thin nerve connections running from pineal cells to the regions called the posterior commissure and the habenula. These regions in turn send signals to brain areas that influence mood and sleep. Whether these pineal-to-brain connections exist in other mammals has not yet been established. But Klein suggests that such connections in the human brain might help explain the improvement that bright light provides for some patients who become depressed as the days shorten in winter (SN: 3/9/85, p. 152). In some reptiles the pineal gland acts as a light sensor, has direct neural connections with the brain and is though to help control daily rhythms of sleep wakefulness wakefulness believed to occur when the tonic flow of impulses from the reticular activating system exceeds the critical level for sustaining consciousness; reduction of reticular activating system activity is the basis of the pharmacological induction of sedation. . |
|
||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion