| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Naoki Yamawaki, Jelena Radulovic, Gordon M G Shepher. A Corticocortical Circuit Directly Links Retrosplenial Cortex to M2 in the Mouse. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 36. issue 36. 2017-08-17. PMID:27605612. |
a particularly prominent projection extends rostrally to the posterior secondary motor cortex (m2), suggesting a functional corticocortical link from the rsc to m2 and thus a bridge between hippocampal and neocortical networks involved in mnemonic and sensorimotor aspects of navigation. |
2017-08-17 |
2023-08-13 |
mouse |
| Dmitriy Aronov, Rhino Nevers, David W Tan. Mapping of a non-spatial dimension by the hippocampal-entorhinal circuit. Nature. vol 543. issue 7647. 2017-08-10. PMID:28358077. |
during spatial navigation, neural activity in the hippocampus and the medial entorhinal cortex (mec) is correlated to navigational variables such as location, head direction, speed, and proximity to boundaries. |
2017-08-10 |
2023-08-13 |
rat |
| Kiah Hardcastle, Niru Maheswaranathan, Surya Ganguli, Lisa M Giocom. A Multiplexed, Heterogeneous, and Adaptive Code for Navigation in Medial Entorhinal Cortex. Neuron. vol 94. issue 2. 2017-08-08. PMID:28392071. |
a multiplexed, heterogeneous, and adaptive code for navigation in medial entorhinal cortex. |
2017-08-08 |
2023-08-13 |
Not clear |
| Hongjun Fu, Gustavo A Rodriguez, Mathieu Herman, Sheina Emrani, Eden Nahmani, Geoffrey Barrett, Helen Y Figueroa, Eliana Goldberg, S Abid Hussaini, Karen E Duf. Tau Pathology Induces Excitatory Neuron Loss, Grid Cell Dysfunction, and Spatial Memory Deficits Reminiscent of Early Alzheimer's Disease. Neuron. vol 93. issue 3. 2017-07-26. PMID:28111080. |
the medial entorhinal cortex (mec) contains specialized neurons called grid cells that form part of the spatial navigation system. |
2017-07-26 |
2023-08-13 |
mouse |
| Andrej Bicanski, Neil Burges. Environmental Anchoring of Head Direction in a Computational Model of Retrosplenial Cortex. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 36. issue 46. 2017-07-17. PMID:27852770. |
it provides a functional account of the anatomical distribution of head direction cells along papez' circuit, of place-by-direction coding in retrosplenial cortex, the anatomical connection from the anterior thalamic nuclei to retrosplenial cortex, and the involvement of retrosplenial cortex in navigation. |
2017-07-17 |
2023-08-13 |
Not clear |
| Yangfan Peng, Federico J Barreda Tomás, Constantin Klisch, Imre Vida, Jörg R P Geige. Layer-Specific Organization of Local Excitatory and Inhibitory Synaptic Connectivity in the Rat Presubiculum. Cerebral cortex (New York, N.Y. : 1991). vol 27. issue 4. 2017-04-27. PMID:28334142. |
the presubiculum is part of the parahippocampal spatial navigation system and contains head direction and grid cells upstream of the medial entorhinal cortex. |
2017-04-27 |
2023-08-13 |
rat |
| Anu Aggarwa. Neuromorphic VLSI realization of the hippocampal formation. Neural networks : the official journal of the International Neural Network Society. vol 77. 2016-12-13. PMID:26914394. |
the medial entorhinal cortex grid cells, aided by the subicular head direction cells, are thought to provide a matrix which is utilized by the hippocampal place cells for calculation of position of an animal during spatial navigation. |
2016-12-13 |
2023-08-13 |
Not clear |
| Aidan J Horner, James A Bisby, Ewa Zotow, Daniel Bush, Neil Burges. Grid-like Processing of Imagined Navigation. Current biology : CB. vol 26. issue 6. 2016-12-13. PMID:26972318. |
we used fmri to provide evidence for similar grid-like signals in human entorhinal cortex during both virtual navigation and imagined navigation of the same paths. |
2016-12-13 |
2023-08-13 |
human |
| Jan Sigurd Blackstad, Kirsten K Osen, Helen E Scharfman, Jon Storm-Mathisen, Theodor W Blackstad, Trygve B Leergaar. Observations on hippocampal mossy cells in mink (Neovison vison) with special reference to dendrites ascending to the granular and molecular layers. Hippocampus. vol 26. issue 2. 2016-10-13. PMID:26286893. |
detailed knowledge about the neural circuitry connecting the hippocampus and entorhinal cortex is necessary to understand how this system contributes to spatial navigation and episodic memory. |
2016-10-13 |
2023-08-13 |
rat |
| Charles V Vorhees, Michael T William. Reprint of "Value of water mazes for assessing spatial and egocentric learning and memory in rodent basic research and regulatory studies". Neurotoxicology and teratology. vol 52. issue Pt A. 2016-10-12. PMID:26071087. |
allocentric navigation involves the hippocampus, entorhinal cortex, and surrounding structures (e.g., subiculum); in humans this system encodes declarative memory (allocentric, semantic, and episodic, i.e., memory for people, places, things, and events). |
2016-10-12 |
2023-08-13 |
Not clear |
| E M Migo, O O'Daly, M Mitterschiffthaler, E Antonova, G R Dawson, C T Dourish, K J Craig, A Simmons, G K Wilcock, E McCulloch, S H D Jackson, M D Kopelman, S C R Williams, R G Morri. Investigating virtual reality navigation in amnestic mild cognitive impairment using fMRI. Neuropsychology, development, and cognition. Section B, Aging, neuropsychology and cognition. vol 23. issue 2. 2016-10-06. PMID:26234803. |
spatial navigation requires a well-established network of brain regions, including the hippocampus, caudate nucleus, and retrosplenial cortex. |
2016-10-06 |
2023-08-13 |
Not clear |
| Michaël Bernier, Claudie Gauvreau, Denis Theriault, Stéphanie Madrolle, Jean-François Lepage, Kevin Whittingstal. Increased BOLD activation in the left parahippocampal cortex after 1 year of medical school: an association with cumulative verbal memory learning. Neuroreport. vol 27. issue 1. 2016-08-30. PMID:26606418. |
using a common mental navigation task known to activate the bilateral parahippocampal cortex, this study aimed at determining how bold activation in these two areas changes after 1 year of medical school, a program characterized by intensive verbal learning. |
2016-08-30 |
2023-08-13 |
human |
| Joshua Jacobs, Sang Ah Le. Spatial Cognition: Grid Cells Support Imagined Navigation. Current biology : CB. vol 26. issue 7. 2016-08-24. PMID:27046812. |
grid cells in the entorhinal cortex represent an animal's current location during navigation. |
2016-08-24 |
2023-08-13 |
Not clear |
| Yael Benn, Ofer Bergman, Liv Glazer, Paris Arent, Iain D Wilkinson, Rosemary Varley, Steve Whittake. Navigating through digital folders uses the same brain structures as real world navigation. Scientific reports. vol 5. 2016-08-19. PMID:26423226. |
using fmri we provide an explanation for this phenomenon by demonstrating that folder navigation results in activation of the posterior limbic (including the retrosplenial cortex) and parahippocampal regions similar to that previously observed during real-world navigation in both animals and humans. |
2016-08-19 |
2023-08-13 |
Not clear |
| Martin Salaj, Rastislav Druga, Jiří Cerman, Hana Kubová, Filip Barink. Calretinin and parvalbumin immunoreactive interneurons in the retrosplenial cortex of the rat brain: Qualitative and quantitative analyses. Brain research. vol 1627. 2016-08-17. PMID:26449685. |
the retrosplenial cortex (rsc) is a mesocortical region broadly involved with memory and navigation. |
2016-08-17 |
2023-08-13 |
rat |
| Elke C Fuchs, Angela Neitz, Roberta Pinna, Sarah Melzer, Antonio Caputi, Hannah Monye. Local and Distant Input Controlling Excitation in Layer II of the Medial Entorhinal Cortex. Neuron. vol 89. issue 1. 2016-05-25. PMID:26711115. |
layer ii (lii) of the medial entorhinal cortex (mec) comprises grid cells that support spatial navigation. |
2016-05-25 |
2023-08-13 |
Not clear |
| Stephen Grossber. From brain synapses to systems for learning and memory: Object recognition, spatial navigation, timed conditioning, and movement control. Brain research. vol 1621. 2016-05-23. PMID:25446436. |
similar synaptic learning laws support qualitatively different behaviors: invariant object category learning in the inferotemporal cortex; learning of grid cells and place cells in the entorhinal and hippocampal cortices during spatial navigation; and learning of time cells in the entorhinal-hippocampal system during adaptively timed conditioning, including trace conditioning. |
2016-05-23 |
2023-08-13 |
Not clear |
| Katherine R Sherrill, Elizabeth R Chrastil, Robert S Ross, Uğur M Erdem, Michael E Hasselmo, Chantal E Ster. Functional connections between optic flow areas and navigationally responsive brain regions during goal-directed navigation. NeuroImage. vol 118. 2016-05-18. PMID:26054874. |
the results demonstrate that goal-directed navigation requiring updating of position and orientation in the first person perspective involves a cooperative interaction between optic flow sensitive regions v3a, v6, and hmt+ and the hippocampus, retrosplenial cortex, posterior parietal cortex, and medial prefrontal cortex. |
2016-05-18 |
2023-08-13 |
human |
| Lukas Kunz, Tobias Navarro Schröder, Hweeling Lee, Christian Montag, Bernd Lachmann, Rayna Sariyska, Martin Reuter, Rüdiger Stirnberg, Tony Stöcker, Paul Christian Messing-Floeter, Juergen Fell, Christian F Doeller, Nikolai Axmache. Reduced grid-cell-like representations in adults at genetic risk for Alzheimer's disease. Science (New York, N.Y.). vol 350. issue 6259. 2016-03-28. PMID:26494756. |
ad pathology starts in the entorhinal cortex, making it likely that local neural correlates of spatial navigation, particularly grid cells, are impaired. |
2016-03-28 |
2023-08-13 |
Not clear |
| Tobias Navarro Schröder, Koen V Haak, Nestor I Zaragoza Jimenez, Christian F Beckmann, Christian F Doelle. Functional topography of the human entorhinal cortex. eLife. vol 4. 2016-03-08. PMID:26052748. |
despite extensive research on the role of the rodent medial and lateral entorhinal cortex (mec/lec) in spatial navigation, memory and related disease, their human homologues remain elusive. |
2016-03-08 |
2023-08-13 |
human |