Biology Reference
In-Depth Information
34. Aschoff J. Circadian rhythms in man. Science . 1965;148:1427-1432.
35. Richter CP. Biological Clocks in Medicine and Psychiatry. Springfield, IL: C.C. Thomas;
1965.
36. Daan S. A history of chronobiological concepts. In: Albrecht U, ed. The Circadian Clock .
New York: Springer; 2010:1-36.
37. Halberg F, CornĀ“lissen G, Katinas G, et al. Transdisciplinary unifying implications of
circadian findings in the 1950s. J Circadian Rhythms . 2003;1:2.
38. Pittendrigh C, Bruce VG. An oscillator model for biological clocks. In: Rudnick D, ed.
Rhythmic and Synthetic Processes in Growth . Princeton: Princeton University Press;
1957:75-109.
39. Heller A, Moore RY. Effect of central nervous system lesions on brain monoamines in
the rat. J Pharmacol Exp Ther . 1965;150:1-9.
40. Hayhow WR, Webb C, Jervie A. The accessory optic fiber system in the rat. J Comp
Neurol . 1960;115:187-215.
41. Nauta WJH, Gygax PA. Silver impregnation of degenerating axons in the central ner-
vous system: a modified technique. Stain Technol . 1954;29:91-93.
42. IngramWR. Nuclear organization and chief connections of the primate hypothalamus.
Res Publ Assoc Res Nerv Ment Dis . 1940;20:195-244.
43. Kiernan JA. On the probable absense of retino-hypothalamic connections in five mam-
mals and an amphibian. J Comp Neurol . 1967;131:405-408.
44. Nauta JHW, Haymaker W. Hypothalamic nuclei and fiber connections. In:
Haymaker W, Anderson E, Nauta WJH, eds. The Hypothalamus . Springfield, IL:
Charles C. Thomas; 1969:136-209.
45. FinkRP, Heimer L. Twomethods for selective silver impregnation of degenerating axons
and their synaptic endings in the central nervous system. Brain Res . 1967;4:369-374.
46. Droz B, Leblond CP. Axonal migration of proteins in the central nervous system and
peripheral nerves as shown by radioautogaphy. J Comp Neurol . 1963;121:325-346.
47. GrafsteinB. Transport of protein by goldfishoptic nerve fibers. Science . 1967;157:1986-1988.
48. Moore RY, Lenn NJ. A retinohypothalamic projection in the rat.
J Comp Neurol .
1972;146:1-14.
49. Hendrickson AE, Wagoner N, Cowan WM. An autoradiographic and electron micro-
scopic study of retinohypothalamic connections. Z Zellforsch . 1972;135:1-26.
50. Moore RY. Retinohypothalamic projection in mammals: a comparative study. Brain
Res . 1973;51:403-409.
51. Halasz B, Pupp L. Hormone secretion of the anterior pituitary gland after physical
interruption of all nervous pathways to the hypophysiotrophic area. Endocrinology .
1965;77:553-562.
52. Moore RY, Eichler VB. Loss of a circadian adrenal corticosterone rhythm following
suprachiasmatic lesions in the rat. Brain Res . 1972;42:201-206.
53. Stephan FK, 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.
54. Rusak B, Zucker
Physiol Rev .
I. Neural
regulation of circadian rhythms.
1979;59:449-526.
55. van Esseveldt KE, Lehman MN, Boer GJ. The suprachiasmatic nucleus and the circa-
dian time-keeping system revisited. Brain Res Rev . 2000;33:34-77.
56. Van den Pol AN, Powley T. A fine-grained anatomical analysis of the role ofthe rat
suprachiasmatic nucleus in circadian rhythms of feeding and drinking. Brain Res .
1979;160:307-326.
57. Schwartz WJ, Gainer H. Suprachiasmatic nucleus: use of 14C-labeled deoxyglucose
uptake as a functional marker. Science . 1977;197:1089-1091.
58. Schwartz W, Davidsen LC, Smith CB. In vivo metabolic activity of a putative circadian
oscillator, the rat suprachiasmatic nucleus.
J Comp Neurol . 1980;189:157-167.
 
 
 
 
 
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