| Reference |
Sentence |
Publish Date |
Extraction Date |
Species |
| Bente Jacobsen, Heidi Kleven, Wairimu Gatome, Liora Las, Nachum Ulanovsky, Menno P Witte. Organization of projections from the entorhinal cortex to the hippocampal formation of the Egyptian fruit bat Rousettus aegyptiacus. Hippocampus vol issue 2023 36869437 |
the hippocampal formation and entorhinal cortex are crucially involved in learning and memory as well as in spatial navigation. |
2023-03-04 |
2023-03-06 |
Not clear |
| Morgan B Jude, Christine R Stran. Sex and season affect cortical volumes in free-living Western fence lizards, Sceloporus occidentalis. Brain, behavior and evolution vol issue 2023 36796337 |
differences in spatial navigation in these lizards may involve aspects of spatial memory related to breeding other than territoriality that affect plasticity of the dorsal cortex. |
2023-02-16 |
2023-03-06 |
Not clear |
| Isabel I C Low, Lisa M Giocomo, Alex H William. Remapping in a recurrent neural network model of navigation and context inference. bioRxiv : the preprint server for biology vol issue 2023 36747825 |
we show that these combined task constraints (navigation and context inference) produce activity patterns that are qualitatively similar to population-wide remapping in the entorhinal cortex, a navigational brain region. |
2023-02-07 |
2023-03-06 |
Not clear |
| Isabella C Wagner, Luise P Graichen, Boryana Todorova, Andre L\\xc3\\xbcttig, David B Omer, Matthias Stangl, Claus Lam. Entorhinal grid-like codes and time-locked network dynamics track others navigating through space. Nature communications vol 14 issue 1 2023 36720865 |
grid cells in the entorhinal cortex are a central component of self-related navigation but whether they also track others' movement is unclear. |
2023-01-31 |
2023-03-06 |
human |
| Taiping Zeng, Bailu Si, Xiaoli L. Entorhinal-hippocampal interactions lead to globally coherent representations of space. Current research in neurobiology vol 3 issue 2023 36685760 |
we propose a navigation model containing a path integration system in the entorhinal cortex and a cognitive map system in the hippocampus. |
2023-01-23 |
2023-01-31 |
Not clear |
| Osman Akan, Anne Bierbrauer, Lukas Kunz, Patrick D Gajewski, Stephan Getzmann, Jan G Hengstler, Edmund Wascher, Nikolai Axmacher, Oliver T Wol. Chronic stress is associated with specific path integration deficits. Behavioural brain research vol issue 2023 36682499 |
the entorhinal cortex is a brain region in the medial temporal lobe, which contains multiple cell types involved in spatial navigation (and episodic memory), and a high number of corticosteroid receptors, predisposing it as a potential target of cortisol effects. |
2023-01-22 |
2023-01-31 |
human |
| Nichole R Bouffard, Ali Golestani, Iva K Brunec, Buddhika Bellana, Jun Young Park, Morgan D Barense, Morris Moscovitc. Single voxel autocorrelation uncovers gradients of temporal dynamics in the hippocampus and entorhinal cortex during rest and navigation. Cerebral cortex (New York, N.Y. : 1991) vol issue 2022 36573396 |
single voxel autocorrelation uncovers gradients of temporal dynamics in the hippocampus and entorhinal cortex during rest and navigation. |
2022-12-27 |
2023-01-30 |
Not clear |
| Xiao Fu, Zhenglin Zhang, Yanfei Zhou, Qi Chen, Li-Zhuang Yang, Hai L. The Split-Half Reliability and Construct Validity of the Virtual Reality-Based Path Integration Task in the Healthy Population. Brain sciences vol 12 issue 12 2022 36552095 |
the present study investigates the relationship between task indicators and brain structures in a healthy population using a vr-based navigation task, particularly the entorhinal cortex (ec) and hippocampus. |
2022-12-23 |
2023-01-30 |
Not clear |
| Miriam H A Bopp, Felix Corr, Benjamin Sa\\xc3\\x9f, Mirza Pojskic, Andr\\xc3\\xa9 Kemmling, Christopher Nimsk. Augmented Reality to Compensate for Navigation Inaccuracies. Sensors (Basel, Switzerland) vol 22 issue 24 2022 36559961 |
in all cases, with detected misalignment, a successful spatial compensation was performed (mean correction: bone (6.27 \xc2\xb1 7.31 mm), vascular (3.00 \xc2\xb1 1.93 mm, 0.38\xc2\xb0 \xc2\xb1 1.06\xc2\xb0), and cortex (5.31 \xc2\xb1 1.57 mm, 1.75\xc2\xb0 \xc2\xb1 2.47\xc2\xb0)) increasing navigation accuracy. |
2022-12-23 |
2023-01-30 |
Not clear |
| Jose A Fernandez-Leon, Ahmet Kerim Uysal, Daoyun J. Place cells dynamically refine grid cell activities to reduce error accumulation during path integration in a continuous attractor model. Scientific reports vol 12 issue 1 2022 36509873 |
during spatial navigation, grid cells in the medial entorhinal cortex process speed and direction of the animal to map the environment. |
2022-12-12 |
2023-01-30 |
Not clear |
| Edmund T Rolls, Gustavo Deco, Chu-Chung Huang, Jianfeng Fen. Human Amygdala compared to Orbitofrontal Cortex Connectivity, and Emotion. Progress in neurobiology vol issue 2022 36442728 |
the orbitofrontal cortex has effective connectivity from gustatory, olfactory, and temporal visual, auditory and pole cortex, and to the pregenual anterior and posterior cingulate cortex, hippocampal system, and prefrontal cortex, and provides for rewards and punishers to be used in reported emotions, and memory and navigation to goals. |
2022-11-28 |
2023-01-30 |
human |
| Shalva Gurgenidze, Peter B\\xc3\\xa4uerle, Dietmar Schmitz, Imre Vida, Tengis Gloveli, Tamar Dugladz. Cell-Type Specific Inhibition Controls the High-Frequency Oscillations in the Medial Entorhinal Cortex. International journal of molecular sciences vol 23 issue 22 2022 36430563 |
the medial entorhinal cortex (mec) plays a critical role for spatial navigation and memory. |
2022-11-26 |
2023-01-30 |
Not clear |
| Laura Convertino, Daniel Bush, Fanfan Zheng, Rick A Adams, Neil Burges. Reduced grid-like theta modulation in schizophrenia. Brain : a journal of neurology vol issue 2022 36352511 |
both the entorhinal cortex and medial prefrontal cortex exhibit a six-fold (or 'hexadirectional') modulation of neural activity during virtual navigation that is indicative of grid cell populations and associated with accurate spatial navigation. |
2022-11-10 |
2023-01-30 |
human |
| Qunjun Liang, Jiajun Liao, Jinhui Li, Senning Zheng, Xiaoqian Jiang, Ruiwang Huan. The role of the parahippocampal cortex in landmark-based distance estimation based on the contextual hypothesis. Human brain mapping vol issue 2022 36066186 |
parahippocampal cortex (phc) is a vital neural bases in spatial navigation. |
2022-09-06 |
2023-01-30 |
human |
| Timothy Morello, Richard Kollmar, Mark Stewart, Rena Orma. The retrosplenial cortex of Carollia perspicillata, Seba's short-tailed fruit bat. Hippocampus vol issue 2022 36018284 |
retrosplenial cortex (rsc) is a brain region involved in critical cognitive functions including memory, planning, and spatial navigation and is commonly affected in neurodegenerative diseases. |
2022-08-26 |
2023-01-30 |
Not clear |
| Rifqi O Affan, Benjamin B Scot. Everything, everywhere, all at once: Functional specialization and distributed coding in the cerebral cortex. Neuron vol 110 issue 15 2022 35926451 |
in this issue of neuron, tseng and colleagues reveal functional gradients in the mouse posterior cortex that reconcile specialized and distributed processing during flexible, goal-directed navigation. |
2022-08-04 |
2023-01-30 |
mouse |
| Megha Ghosh, Fang-Chi Yang, Sharena P Rice, Vaughn Hetrick, Alcides Lorenzo Gonzalez, Danny Siu, Ellen K W Brennan, Tibin T John, Allison M Ahrens, Omar J Ahme. Running speed and REM sleep control two distinct modes of rapid interhemispheric communication. Cell reports vol 40 issue 1 2022 35793619 |
splines are strongest in superficial granular retrosplenial cortex, a region important for spatial navigation and memory. |
2022-07-06 |
2023-01-27 |
rat |
| Charlotte Arlt, Roberto Barroso-Luque, Shinichiro Kira, Carissa A Bruno, Ningjing Xia, Selmaan N Chettih, Sofia Soares, Noah L Pettit, Christopher D Harve. Cognitive experience alters cortical involvement in goal-directed navigation. eLife vol 11 issue 2022 35735909 |
we discovered that mice with distinct cognitive experiences, beyond sensory and motor learning, use different cortical areas and neural activity patterns to solve the same navigation decision task, revealing past learning as a critical determinant of whether cortex is necessary for goal-directed navigation. |
2022-06-23 |
2023-01-27 |
mouse |
| Charlotte Arlt, Roberto Barroso-Luque, Shinichiro Kira, Carissa A Bruno, Ningjing Xia, Selmaan N Chettih, Sofia Soares, Noah L Pettit, Christopher D Harve. Cognitive experience alters cortical involvement in goal-directed navigation. eLife vol 11 issue 2022 35735909 |
posterior parietal cortex and retrosplenial cortex were mostly dispensable for accurate performance of a simple navigation task. |
2022-06-23 |
2023-01-27 |
mouse |
| Shih-Yi Tseng, Selmaan N Chettih, Charlotte Arlt, Roberto Barroso-Luque, Christopher D Harve. Shared and specialized coding across posterior cortical areas for dynamic navigation decisions. Neuron vol issue 2022 35679861 |
we characterized encoding in approximately 90,000 neurons across the mouse posterior cortex during a virtual navigation task with rule switching. |
2022-06-09 |
2023-01-27 |
mouse |