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Besin Motivasyonunun FarklıDüzeylerinde Sensomotor, Limbik ve Cerebral Kortekste Meydana Gelen Morfolojik Değişiklikler

MORPHOLOGICAL CHANGES IN SENSOMOTOR, LIMBIC AND ORBITAL CEREBRAL CORTEX UNDER DIFFERENT LEVELS OF FOOD MOTIVATION

Journal Name:

  • İstanbul Üniversitesi Veteriner Fakültesi Dergisi

Publication Year:

  • 2008

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
The aim of this study was to investigate the morphological changes in various sites of cerebral cortex at different levels of food motivation. In the study, the region controlling intentional movement has undergone alteration much earlier than the other regions. Such morphological changes can also be associated with the change in homoeostasis of the body. In case of the prolonged periods of hunger, morphological changes of sensomotor and limbic cortex become more intense. Such a change was also be observed in cerebral cortex. In conclusion, we have observed that the morphological changes in cerebral cortex are due to the food motivation and its stage
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Abstract (Original Language): 
Bu çalışmanın amacı, besin motivasyonunun farklıdüzeylerinde sensomotor, limbic ve cerebral kortekste meydana gelen morfolojik değişliklerin araştırılmasıdır. Çalışmada, maksatlı hareketleri kontrol eden bölge, diğer bölgelerden daha fazla değişikliğe uğramıştır. Böyle morfolojik değişiklikler vücut homeostazisindeki değişikliklerle ilgili de olabilir. Açlığın uzaması durumunda sensomotor ve limbic kortekste daha fazla değişiklikler gözlendi. Aynıdeğişiklikler cerebral kortekste de gözlendi. Sonuç olarak, açlık motivasyonuna ve süresine bağlıolarak cerebral kortekste morfolojik değişiklikler gözlendi.
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  • English

REFERENCES

References: 

. Brinkman, C.:Supplementary motor area of the monkey's cerebral cortex: short- and long-term after unilateral ablation and the effects ofsubsequent callosal section. J Neurosci, 1984;
4, 918-929.
2.David R, T.:Manual of Histological Demonstration Techniques. Nottingham. 1984.
Atilla TEMUR-Fahrettin ASKEROV-H. Bayram TEMUR-Hüseyin KARADAĞ 74
3.Gershtein, L.M.:Cytochemical peculiarities of recovery processes in the neurons of motor
and temporal brain cortex regions after early visual deprivation proceedings of scientific
issues of Brain researches. Academy of Med. Sci. 3, 1980; 115-119.
4.Gershtein, L.M.:Function-induced biochemical heterogeneity of neurons and their sub
cellular components as one of the possible regularities of brain biochemical organization.
Proceedings of Scientific issues of the Institute of brain researches. Moscow, 1982; 12, 73-76.
5.Gun, A.A.:Strychnino-neuronographic studies of the orbital cortex projections to the varolii
pons structures. Fiziologichemy journal, 12, 1976; 1760-1766.
6.Kaitz, S.S, Robertson, R.T.:. Thalamic connectionswith limbic cortex. II. Corticothalamic
projections. J Comp Neurol. Jan. 1981; 20;195 (3): 527-45.
7.Lehmann, J., Nagy, J.I., Atmadia, S., & Fibiger, H.C.:The nucleus basalis
agnocellularis: The origin of a cholinergic projection to the neocortex. of the rat.
Neuroscience, 1980; 5, 1161-1174.
8.Matsuzaka, Y., and Tanji, J.:Changing directions of forthcoming arm movements:
neuronal activity in the presupplementary and supplementary motor area of monkey cerebral
cortex. J Neurophysiol, 1996; 76, 2327-2342.
9.Popova, E.N., Lapin, S.K.: Destructive and reparative processes under local lesions of the
brain. J. Med. Moscow, 1976; 3, 203.
10. Rustamov, K.D.:Changes of activities of neutral and acidic peptide-hydrolyses in the
sensomotor, limbic and orbital brain cortex of rats under different terms of food deprivation
and saturation-proceedings of IV Conference of Caucasus physiologists. Tbilici, 1983; 10,
78-79.
11.Rustamov, K.D.:Morphological peculiarities of sensomotor, limbic and orbital cortex in
white rats after different terms of food deprivation, proceedings of IV conference of caucasus
morphologists. Tbilici, 1985; 4, 135-136.
12.Sadykhova, E.R.:Peculiarities of the morphocytochemical changes in the hypothalamus and
brain cortex during food regime rearrangements inwhite rats. Autoreferate of thesis for the
rank of candidate of Biological Sciences. Bakü, 1982; 13, 365-366.
13.Shima, K., and Tanji, J.:Both supplementary and presupplementary motor areas are crucial
for the temporal organization of multiple movements. J Neurophysiol, 1998; 80, 3427-3260.
14.Shuleikina, K.V.:Systemic organization of food seeking behavior. Nauka, Moscow, 1979;
280.
15.Sudakov, K.V.:Biological motivations. J. Med. Moscow, 1971; 3, 304.
16.Svetukhina, V.M.:Map of rat cortex areas. Archives of anatomy, histology and embryology,
1962; 2, 52-56.
17. Van Groen, T., Wyss, J.M.: Connections of the retrosplenial dysgranular cortex in the rat. J
Comp Neurol. Jan, 1992; 8; 315 (2): 200-16.
18.Witter, M.P., Groenewegen, H.J.: Connections of the parahippocampal cortex in the cat. III
Cortical and thalamic efferents. J CompNeurol. Oct. 1986; 1; 252 (1): 1-31.

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