References
- Bellinger L. L., Mendel V. E., Moberg G. P. Circadian insulin. GH, prolactin, corticosterone and glucose rhythms in fed and tasted rats. Horm Metab Res 1975; 7: 132–135
- Egawa M., Inoue S., Sato S., Takamura Y., Nagai K., Nakagawa H. Effects of ventromedial hypothalamic lesions on circadian rhythms in serum insulin, glucose, triglyceride and food intake in rats. Horm Metab Res [Suppl 1] 1985; 16: 21–23
- Fuller R. W., Diller E. R. Diurnal variation of liver glycogen and plasma free fatty acids in rats fed ad libitum or single daily meal. Metabolism 1970; 19: 226–229
- Nagai K., Nishio T., Nakagawa H., Nakamura S., Fukuda F. Effect of bilateral lesions of the suprachiasmatic nuclei on the circadian rhythm of food intake. Brain Res 1978; 142: 384–389
- Nagai K., Mori T., Nakagawa H. Application of an immunological technique to behavioral studies: antisuprachiasmatic nucleus γ-globulin induced loss of the circadian rhythm. Biomed Res 1982; 3: 294–302
- Yamamoto H., Nagai K., Nakagawa H. Role of the suprachiasmatic nucleus in glucose homeostasis. Biomed Res 1984; 5: 55–60
- Yamamoto H., Nagai K., Nakagawa H. Lesions involving the suprachiasmatic nucleus eliminate the glucagon response to intracranial injection of 2-deoxy-d-glucose. Endocrinology 1985; 117: 468–473
- Yamamoto H., Nagai K., Nakagawa H. Bilateral lesions of the SCN abolish lipolytic and hyperphagic responses to 2DG. Physiol Behav 1984; 32: 1017–1020
- Fifkova E., Marsala J. Stereotaxic atlases for cat, rabbit and rat. Electrophysiological Methods in Biological Research, J. Bures, M. Petran, J. Zacher. Academic Press, New York 1967; 653–695
- Stephan F. K., Zucker I. Circadian rhythms in drinking behavior and locomotor activity of rats are eliminated by hypothalamic lesions. Proc Natl Acad Sci USA 1972; 69: 1583–1586
- Steffens A. B. A method for frequent sampling of blood and continuous infusion of fluids in the rat without disturbing the animal. Physiol Behav 1969; 4: 833–836
- Moore R. Y., Eichler V. B. Loss of a circadian adrenal corticosterone rhythm following suprachiasmatic lesions in the rat. Brain Res 1972; 42: 201–206
- Rusak B., Zucker I. Neural regulation of circadian rhythm. Physiol Rev 1979; 59: 449–526
- Müller W. A., Faloona G. R., Aguilar-Parada E., Unger R. Abnormal alpha-cell function in diabetes, response to carbohydrate and protein ingestion. New Engl J Med 1970; 283: 109–115
- Woods S. C., Lotter E. C., McKay L. D., Porte D., Jr. Chonic intracerebroventricular infusion of insulin reduces food intake and body weight of baboon. Nature 1979; 283: 503–505
- Nagai K., Mori T., Nishio T., Nakagawa H. Effect of intracranial insulin infusion on the circadian feeding rhythm of rats. Biomedical Res 1982; 3: 175–180
- Oomura Y. Significance of glucose, insulin, and free fatty acid on the hypothalamic feeding and satiety neurons. Hunger—Basic Mechanisms and Clinical Implications, D. Novin, W. Wyrwicka, G. Bray. Raven Press, New York 1976; 145–157
- Le Magnen J., Devos M. Metabolic correlates of the meal onset in the free food intake of rats. Physiol Behav 1970; 5: 805–814
- Nagai K., Nishio T., Nakagawa H. Bilateral lesions of suprachiasmatic nucleus eliminate circadian rhythms of oxygen consumption and the respiratory quotient in rats. Esperientia 1985; 41: 1136–1138
- Nakagawa H., Nagai K., Kida K., Nishio T. Control mechanism of circadian rhythms of feeding behavior and metabolism influenced by food intake. Biological Rhythms and Their Central Mechanism, M. Suda, O. Hayaishi, H. Nakagawa. Elsevier. 1979; 283–294, /North-Holland Biomedical Press, Amsterdam
- Nishio T., Shiosaka S., Nakagawa H., Sakumoto T., Satoh K. Circadian feeding rhythm after hypothalamic knife-cut isolating suprachiasmatic nucleus. Physiol Behav 1979; 23: 763–769
- Frohman L. A., Bernardis L. L. Effect of hypothalamic stimulation on plasma glucose, insulin, and glucagon levels. Am J Physiol 1971; 221: 1596–4603
- Shimazu T., Fukuda A., Ban T. Reciprocal influence of the ventromedial and lateral hypothalamic nuclei on blood glucose level and liver glycogen content. Nature 1966; 210: 1178–1179
- Inouye S. T., Kawamura H. Persistence of circadian rhythmicity in a mammalian hypothalamic “island” containing the suprachiasmatic nucleus. Proc Natl Acad Sci USA 1979; 76: 5962–5966
- Schwartz W. J., Gainer H. Suprachiasmatic nucleus: use of 14C-labeled deoxyglucose uptake as a functional marker. Science 1977; 197: 1089–1091
- Kita H., Shibata S., Oomura Y., Ohki K. Excitatory effects of the suprachiasmatic nucleus on the ventromedial nucleus in the rat hypothalamic slice. Brain Res 1982; 235: 137–141
- Oomura Y., Ono T., Nishino H., Kita H., Shimizu S., Sasaki K. Hypothalamic control of feeding behavior: modulation by the suprachiasmatic nucleus. Biological Rhythms and Their Central Mechanism, M. Suda, O. Hayaishi, H. Nakagawa. Elsevier. 1979; 295–308, /North-Holland Biomedical Press, Amsterdam
- Yamamoto H., Nagai K., Nakagawa H. Bilateral lesions of the suprachiasmatic nucleus enhance glucose tolerance in rats. Biomedical Res 1984; 5: 47–54
- König J. F. R., Klippel R. A. The Rat Brain: a Stereotaxic Atlas of Forebrain and Lower Parts of the Brain Stem. Williams and Wilkins, Baltimore 1963