SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2766524975> ?p ?o ?g. }

Showing items 1 to 100 of ±141 with 100 items per page.

W2766524975 endingPage "11805" @default.
W2766524975 startingPage "11789" @default.
W2766524975 abstract "Hippocampal sharp-wave ripple (SWR) events occur during both behavior (awake SWRs) and slow-wave sleep (sleep SWRs). Awake and sleep SWRs both contribute to spatial learning and memory, thought to be mediated by the coordinated reactivation of behavioral experiences in hippocampal-cortical circuits seen during SWRs. Current hypotheses suggest that reactivation contributes to memory consolidation processes, but whether awake and sleep reactivation are suited to play similar or different roles remains unclear. Here we addressed that issue by examining the structure of hippocampal (area CA1) and prefrontal (PFC) activity recorded across behavior and sleep stages in male rats learning a spatial alternation task. We found a striking state difference: prefrontal modulation during awake and sleep SWRs was surprisingly distinct, with differing patterns of excitation and inhibition. CA1-PFC synchronization was stronger during awake SWRs, and spatial reactivation, measured using both pairwise and ensemble measures, was more structured for awake SWRs compared with post-task sleep SWRs. Stronger awake reactivation was observed despite the absence of coordination between network oscillations, namely hippocampal SWRs and cortical delta and spindle oscillations, which is prevalent during sleep. Finally, awake CA1-PFC reactivation was enhanced most prominently during initial learning in a novel environment, suggesting a key role in early learning. Our results demonstrate significant differences in awake and sleep reactivation in the hippocampal-prefrontal network. These findings suggest that awake SWRs support accurate memory storage and memory-guided behavior, whereas sleep SWR reactivation is better suited to support integration of memories across experiences during consolidation.SIGNIFICANCE STATEMENT Hippocampal sharp-wave ripples (SWRs) occur both in the awake state during behavior and in the sleep state after behavior. Awake and sleep SWRs are associated with memory reactivation and are important for learning, but their specific memory functions remain unclear. Here, we found profound differences in hippocampal-cortical reactivation during awake and sleep SWRs, with key implications for their roles in memory. Awake reactivation is a higher-fidelity representation of behavioral experiences, and is enhanced during early learning, without requiring coordination of network oscillations that is seen during sleep. Our findings suggest that awake reactivation is ideally suited to support initial memory formation, retrieval and planning, whereas sleep reactivation may play a broader role in integrating memories across experiences during consolidation." @default.
W2766524975 created "2017-11-10" @default.
W2766524975 creator A5005546626 @default.
W2766524975 creator A5041221751 @default.
W2766524975 creator A5060193294 @default.
W2766524975 creator A5072106624 @default.
W2766524975 date "2017-10-31" @default.
W2766524975 modified "2023-10-18" @default.
W2766524975 title "Hippocampal-Prefrontal Reactivation during Learning Is Stronger in Awake Compared with Sleep States" @default.
W2766524975 cites W1770958704 @default.
W2766524975 cites W1836583613 @default.
W2766524975 cites W1842212615 @default.
W2766524975 cites W1967456522 @default.
W2766524975 cites W1969003018 @default.
W2766524975 cites W1973490159 @default.
W2766524975 cites W1974367810 @default.
W2766524975 cites W1975136983 @default.
W2766524975 cites W1975958074 @default.
W2766524975 cites W1981998044 @default.
W2766524975 cites W1996714928 @default.
W2766524975 cites W2001257668 @default.
W2766524975 cites W2023924009 @default.
W2766524975 cites W2031459113 @default.
W2766524975 cites W2034379782 @default.
W2766524975 cites W2035466157 @default.
W2766524975 cites W2043106712 @default.
W2766524975 cites W2047057213 @default.
W2766524975 cites W2047999252 @default.
W2766524975 cites W2052576377 @default.
W2766524975 cites W2057410629 @default.
W2766524975 cites W2058819676 @default.
W2766524975 cites W2060671266 @default.
W2766524975 cites W2062205907 @default.
W2766524975 cites W2070368256 @default.
W2766524975 cites W2071290167 @default.
W2766524975 cites W2076167286 @default.
W2766524975 cites W2076327464 @default.
W2766524975 cites W2085256822 @default.
W2766524975 cites W2088046534 @default.
W2766524975 cites W2096698697 @default.
W2766524975 cites W2097456332 @default.
W2766524975 cites W2106011868 @default.
W2766524975 cites W2112616037 @default.
W2766524975 cites W2115107366 @default.
W2766524975 cites W2118168358 @default.
W2766524975 cites W2120574801 @default.
W2766524975 cites W2122833757 @default.
W2766524975 cites W2129217278 @default.
W2766524975 cites W2130377174 @default.
W2766524975 cites W2130378946 @default.
W2766524975 cites W2137172397 @default.
W2766524975 cites W2141348551 @default.
W2766524975 cites W2143853187 @default.
W2766524975 cites W2151577040 @default.
W2766524975 cites W2155654111 @default.
W2766524975 cites W2163233331 @default.
W2766524975 cites W2168101731 @default.
W2766524975 cites W2171273397 @default.
W2766524975 cites W2218418953 @default.
W2766524975 cites W2288876215 @default.
W2766524975 cites W2293146851 @default.
W2766524975 cites W2294068407 @default.
W2766524975 cites W2294886124 @default.
W2766524975 cites W2310925872 @default.
W2766524975 cites W2403111963 @default.
W2766524975 cites W2507425266 @default.
W2766524975 cites W2514749327 @default.
W2766524975 cites W2530440326 @default.
W2766524975 cites W2554866352 @default.
W2766524975 cites W2555205531 @default.
W2766524975 cites W2561545741 @default.
W2766524975 cites W2571848202 @default.
W2766524975 cites W2589540435 @default.
W2766524975 cites W2607419807 @default.
W2766524975 cites W2735243074 @default.
W2766524975 cites W301412097 @default.
W2766524975 doi "https://doi.org/10.1523/jneurosci.2291-17.2017" @default.
W2766524975 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/5719968" @default.
W2766524975 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/29089440" @default.
W2766524975 hasPublicationYear "2017" @default.
W2766524975 type Work @default.
W2766524975 sameAs 2766524975 @default.
W2766524975 citedByCount "110" @default.
W2766524975 countsByYear W27665249752018 @default.
W2766524975 countsByYear W27665249752019 @default.
W2766524975 countsByYear W27665249752020 @default.
W2766524975 countsByYear W27665249752021 @default.
W2766524975 countsByYear W27665249752022 @default.
W2766524975 countsByYear W27665249752023 @default.
W2766524975 crossrefType "journal-article" @default.
W2766524975 hasAuthorship W2766524975A5005546626 @default.
W2766524975 hasAuthorship W2766524975A5041221751 @default.
W2766524975 hasAuthorship W2766524975A5060193294 @default.
W2766524975 hasAuthorship W2766524975A5072106624 @default.
W2766524975 hasBestOaLocation W27665249751 @default.
W2766524975 hasConcept C111919701 @default.
W2766524975 hasConcept C148762608 @default.
W2766524975 hasConcept C15744967 @default.