Related Content
Search Google Scholar for:
|
|
Science 21 October 1977:
Vol. 198. no. 4314, pp. 315 - 317
DOI: 10.1126/science.410102
|
|
Articles
Science, Vol 198, Issue 4314, 315-317
Copyright © 1977 by American Association for the Advancement of Science
Hippocampal efferents reach widespread areas of cerebral cortex and amygdala in the rhesus monkey
DL Rosene
and
GW Van Hoesen
The subiculum of the primate hippocampal formation stands at the end of a polarized sequence of intrinsic hippocampal efferents and is the source of efferents to the medial frontal cortex, the caudal cingulate gyrus, and the parahippocampal area and amygdala in the temporal lobe. In addition, the subiculum sends subcortical efferents to the septum and diencephalon.
THIS ARTICLE HAS BEEN CITED BY OTHER ARTICLES:
- The Frequency and Extent of Mammillary Body Atrophy Associated with Surgical Removal of a Colloid Cyst.
- C.E. Denby, S.D. Vann, D. Tsivilis, J.P. Aggleton, D. Montaldi, N. Roberts, and A.R. Mayes (2009)
AJNR Am. J. Neuroradiol.
30, 736-743
| Abstract »
| Full Text »
| PDF »
- Connectivity-Based Parcellation of Human Cingulate Cortex and Its Relation to Functional Specialization.
- M. Beckmann, H. Johansen-Berg, and M. F. S. Rushworth (2009)
J. Neurosci.
29, 1175-1190
| Abstract »
| Full Text »
| PDF »
- Dopamine Modulates Temporal Dynamics of Feedforward Inhibition in Rat Prefrontal Cortex In Vivo.
- P. L. Tierney, A. M. Thierry, J. Glowinski, J. M. Deniau, and Y. Gioanni (2008)
Cereb Cortex
18, 2251-2262
| Abstract »
| Full Text »
| PDF »
- Changing Frontal Contributions to Memory Before and After Medial Temporal Lobectomy.
- L. Maccotta, R. L. Buckner, F. G. Gilliam, and J. G. Ojemann (2007)
Cereb Cortex
17, 443-456
| Abstract »
| Full Text »
| PDF »
- Neuropathologic Substrate of Mild Cognitive Impairment.
- W. R. Markesbery, F. A. Schmitt, R. J. Kryscio, D. G. Davis, C. D. Smith, and D. R. Wekstein (2006)
Arch Neurol
63, 38-46
| Abstract »
| Full Text »
| PDF »
- The Aging Hippocampus: Cognitive, Biochemical and Structural Findings.
- I. Driscoll, D. A. Hamilton, H. Petropoulos, R. A. Yeo, W. M. Brooks, R. N. Baumgartner, and R. J. Sutherland (2003)
Cereb Cortex
13, 1344-1351
| Abstract »
| Full Text »
| PDF »
- Synaptic Influence of Hippocampus on Pyramidal Cells of the Rat Prefrontal Cortex: An In Vivo Intracellular Recording Study.
- E. Degenetais, A.-M. Thierry, J. Glowinski, and Y. Gioanni (2003)
Cereb Cortex
13, 782-792
| Abstract »
| Full Text »
| PDF »
- Significance of Dystonic Posturing With Unilateral Automatisms.
- P. Kotagal (1999)
Arch Neurol
56, 912-913
| Full Text »
| PDF »
- Association of Ipsilateral Motor Automatisms and Contralateral Dystonic Posturing: A Clinical Feature Differentiating Medial From Neocortical Temporal Lobe Epilepsy.
- S. Dupont, F. Semah, P. Boon, J.-M. Saint-Hilaire, C. Adam, D. Broglin, and M. Baulac (1999)
Arch Neurol
56, 927-932
| Abstract »
| Full Text »
| PDF »
- Organization of Corticostriatal and Corticoamygdalar Projections Arising from the Anterior Inferotemporal Area TE of the Macaque Monkey: A Phaseolus vulgaris Leucoagglutinin Study.
- K. Cheng, K. S. Saleem, and K. Tanaka (1997)
J. Neurosci.
17, 7902-7925
| Abstract »
| Full Text »
| PDF »
- Modulation of Forebrain Electroencephalographic Activity in Halothane-Anesthetized Rat via Actions of Noradrenergic beta -Receptors within the Medial Septal Region.
- C. W. Berridge, S. J. Bolen, M. S. Manley, and S. L. Foote (1996)
J. Neurosci.
16, 7010-7020
| Abstract »
| Full Text »
| PDF »
- Interictal Metabolic Anatomy of Mesial Temporal Lobe Epilepsy.
- T. R. Henry, J. C. Mazziotta, and J. Engel Jr (1993)
Arch Neurol
50, 582-589
| Abstract »
| PDF »
- Some Cytoarchitectural Abnormalities of the Entorhinal Cortex in Schizophrenia.
- s. E. Arnold, B. T. Hyman, G. W. Van Hoesen, and A. R. Damasio (1991)
Arch Gen Psychiatry
48, 625-632
| Abstract »
| PDF »
- A Quantitative Investigation of Hippocampal Pyramidal Cell Size, Shape, and Variability of Orientation in Schizophrenia.
- G. W. Christison, M. F. Casanova, D. R. Weinberger, R. Rawlings, and J. E. Kleinman (1989)
Arch Gen Psychiatry
46, 1027-1032
| Abstract »
| PDF »
- Multimodal Amnesic Syndrome Following Bilateral Temporal and Basal Forebrain Damage.
- A. R. Damasio, P. J. Eslinger, H. Damasio, G. W. Van Hoesen, and S. Cornell (1985)
Arch Neurol
42, 252-259
| Abstract »
| PDF »
- Amnesia Following Basal Forebrain Lesions.
- A. R. Damasio, N. R. Graff-Radford, P. J. Eslinger, H. Damasio, and N. Kassell (1985)
Arch Neurol
42, 263-271
| Abstract »
| PDF »
- Right-Hemisphere Language Dominance in Right-handed Epileptic Patients.
- R. Rausch and G. O. Walsh (1984)
Arch Neurol
41, 1077-1080
| Abstract »
| PDF »
- Alzheimer's disease: cell-specific pathology isolates the hippocampal formation.
- B. Hyman, G. Van Hoesen, A. Damasio, and C. Barnes (1984)
Science
225, 1168-1170
| Abstract »
| PDF »
- Dissociative States With Abnormal Temporal Lobe EEG: Multiple Personality and the Illusion of Possession.
- M-M. Mesulam (1981)
Arch Neurol
38, 176-181
| Abstract »
| PDF »
- Tracing Neural Connections of Human Brain With Selective Silver Impregnation: Observations on Geniculocalcarine, Spinothalamic, and Entorhinal Pathways.
- M-M. Mesulam (1979)
Arch Neurol
36, 814-818
| Abstract »
| PDF »
- Subicular input from temporal cortex in the rhesus monkey.
- G. Van Hoesen, D. Rosene, and M. Mesulam (1979)
Science
205, 608-610
| Abstract »
| PDF »
- Hippocampal afterdischarges: differential spread of activity shown by the [14C]deoxyglucose technique.
- M Kliot and C. Poletti (1979)
Science
204, 641-643
| Abstract »
| PDF »
- Thalamic and cortical afferents differentiate anterior from posterior cingulate cortex in the monkey.
- B. Vogt, D. Rosene, and D. Pandya (1979)
Science
204, 205-207
| Abstract »
| PDF »
- A Neurological Model for Childhood Autism.
- A. R. Damasio and R. G. Maurer (1978)
Arch Neurol
35, 777-786
| Abstract »
| PDF »
|
|
