@prefix p66: <http://data.loterre.fr/ark:/67375/P66> .
@prefix dc: <http://purl.org/dc/terms/> .
@prefix skos: <http://www.w3.org/2004/02/skos/core#> .
@prefix uneskos: <http://purl.org/umu/uneskos#> .
@prefix xsd: <http://www.w3.org/2001/XMLSchema#> .
@prefix isothes: <http://purl.org/iso25964/skos-thes#> .

p66:-M5ZF8Z68-8
  dc:creator "Frank Arnould" ;
  dc:bibliographicCitation """<span class ="replaced2">	•	 Ólafsdóttir, H. F., Bush, D., & Barry, C. (2018). The role of hippocampal replay in memory and planning. Current Biology, 28(1), R37–R50.  <a href="https://doi.org/10.1016/j.cub.2017.10.073">https://doi.org/10.1016/j.cub.2017.10.073</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Document type</span>: <span class="versal">literature review</span></p> <p><span class="tooltip-prop">• Access</span>: <span class="versal">open</span></p>"""@en, """<span class ="replaced2">	•	 Genzel, L., Dragoi, G., Frank, L., Ganguly, K., de la Prida, L., Pfeiffer, B., & Robertson, E. (2020). A consensus statement: Defining terms for reactivation analysis. Philosophical Transactions of the Royal Society B: Biological Sciences, 375(1799), 20200001.  <a href="https://doi.org/10.1098/rstb.2020.0001">https://doi.org/10.1098/rstb.2020.0001</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Document type</span>: <span class="versal">conceptual analysis</span></p> <p><span class="tooltip-prop">• Access</span>: <span class="versal">open</span></p>"""@en, """<span class ="replaced2">	•	 Kaefer, K., Stella, F., McNaughton, B. L., & Battaglia, F. P. (2022). Replay, the default mode network and the cascaded memory systems model. Nature Reviews Neuroscience, 23(10), Art. 10.  <a href="https://doi.org/10.1038/s41583-022-00620-6">https://doi.org/10.1038/s41583-022-00620-6</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Type de document</span> : <span class="versal">revue de la littérature</span></p> <p><span class="tooltip-prop">• Accès</span> : <span class="versal">fermé</span></p>"""@fr, """<span class ="replaced2">	•	 Kaefer, K., Stella, F., McNaughton, B. L., & Battaglia, F. P. (2022). Replay, the default mode network and the cascaded memory systems model. Nature Reviews Neuroscience, 23(10), Art. 10.  <a href="https://doi.org/10.1038/s41583-022-00620-6">https://doi.org/10.1038/s41583-022-00620-6</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Document type</span>: <span class="versal">literature review</span></p> <p><span class="tooltip-prop">• Access</span>: <span class="versal">closed</span></p>"""@en, """<span class ="replaced2">	•	 Foster, D. J. (2017). Replay comes of age. Annual Review of Neuroscience, 40(1), 581–602.  <a href="https://doi.org/10.1146/annurev-neuro-072116-031538">https://doi.org/10.1146/annurev-neuro-072116-031538</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Type de document</span> : <span class="versal">revue de la littérature</span></p> <p><span class="tooltip-prop">• Accès</span> : <span class="versal">ouvert</span></p>"""@fr, """<span class ="replaced2">	•	 Genzel, L., Dragoi, G., Frank, L., Ganguly, K., de la Prida, L., Pfeiffer, B., & Robertson, E. (2020). A consensus statement: Defining terms for reactivation analysis. Philosophical Transactions of the Royal Society B: Biological Sciences, 375(1799), 20200001.  <a href="https://doi.org/10.1098/rstb.2020.0001">https://doi.org/10.1098/rstb.2020.0001</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Type de document</span> : <span class="versal">analyse conceptuelle</span></p> <p><span class="tooltip-prop">• Accès</span> : <span class="versal">ouvert</span></p>"""@fr, """<span class ="replaced2">	•	 Ólafsdóttir, H. F., Bush, D., & Barry, C. (2018). The role of hippocampal replay in memory and planning. Current Biology, 28(1), R37–R50.  <a href="https://doi.org/10.1016/j.cub.2017.10.073">https://doi.org/10.1016/j.cub.2017.10.073</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Type de document</span> : <span class="versal">revue de la littérature</span></p> <p><span class="tooltip-prop">• Accès</span> : <span class="versal">ouvert</span></p>"""@fr, """<span class ="replaced2">	•	 Foster, D. J. (2017). Replay comes of age. Annual Review of Neuroscience, 40(1), 581–602.  <a href="https://doi.org/10.1146/annurev-neuro-072116-031538">https://doi.org/10.1146/annurev-neuro-072116-031538</a></span> <span class="reified-property-value xl-pref-label tooltip-html"><p><img src="resource/pics/infoBlue.png"/>	</p><div class="reified-tooltip tooltip-html-content"><p><span class="tooltip-prop">• Document type</span>: <span class="versal">literature review</span></p> <p><span class="tooltip-prop">• Access</span>: <span class="versal">open</span></p>"""@en ;
  skos:prefLabel "récapitulation"@fr, "replay"@en ;
  skos:related p66:-T4Q5ZL53-C, p66:-DP4NMT2L-9, p66:-X1M4BRNP-Z, p66:-ZVCQF82G-P, p66:-PLLK6NVV-Z, p66:-MZP94WL9-J, p66:-RG2FNC5H-B, p66:-C98CQ8QN-Z, p66:-Z24RK3Z6-C, p66:-J39HHJ6N-2, p66:-SFND5BWF-V, p66:-S1WG2Q31-4, p66:-F2HG9RZP-D ;
  skos:definition "“a specific form of reactivation that includes sequential (temporal and/or spatial) information. The sequence does not have to be a perfect replicate of the original” (Genzel et al., 2020)."@en, "« une forme spécifique de réactivation qui comprend des informations séquentielles (temporelles et/ou spatiales). Il n’est pas nécessaire que la séquence soit une réplique parfaite de la séquence originale. » (Genzel et al., 2020)."@fr ;
  skos:broader p66:-RZ2X1NZ0-K ;
  skos:altLabel "neuronal replay"@en, "récapitulation neuronale"@fr ;
  skos:inScheme p66: ;
  uneskos:memberOf p66:-Homme, p66:-Animal, p66:-Neurophysiologie ;
  dc:created "2022-06-07"^^xsd:date ;
  dc:modified "2023-09-04"^^xsd:date ;
  a skos:Concept .

p66:-MZP94WL9-J
  skos:prefLabel "électroencéphalographie"@fr, "electroencephalography"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-ZVCQF82G-P
  skos:prefLabel "sommeil à ondes lentes"@fr, "slow wave sleep"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-Animal
  skos:prefLabel "Animal non humain"@fr, "Nonhuman animal"@en ;
  a isothes:ConceptGroup ;
  skos:member p66:-M5ZF8Z68-8 .

p66:-Neurophysiologie
  skos:prefLabel "Neurophysiologie"@fr, "Neurophysiology"@en ;
  a isothes:ConceptGroup ;
  skos:member p66:-M5ZF8Z68-8 .

p66:-SFND5BWF-V
  skos:prefLabel "réactivation ciblée du souvenir"@fr, "targeted memory reactivation"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-J39HHJ6N-2
  skos:prefLabel "cellule de grille"@fr, "grid cell"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-C98CQ8QN-Z
  skos:prefLabel "cellule de lieu"@fr, "place cell"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-RZ2X1NZ0-K
  skos:prefLabel "processus neurophysiologique"@fr, "neurophysiological process"@en ;
  a skos:Concept ;
  skos:narrower p66:-M5ZF8Z68-8 .

p66:-DP4NMT2L-9
  skos:prefLabel "episodic memory"@en, "mémoire épisodique"@fr ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-PLLK6NVV-Z
  skos:prefLabel "cortex préfrontal"@fr, "prefrontal cortex"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-X1M4BRNP-Z
  skos:prefLabel "consolidation"@fr, "consolidation"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-RG2FNC5H-B
  skos:prefLabel "spatial memory"@en, "mémoire spatiale"@fr ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-Homme
  skos:prefLabel "Human"@en, "Homme"@fr ;
  a isothes:ConceptGroup ;
  skos:member p66:-M5ZF8Z68-8 .

p66: a skos:ConceptScheme .
p66:-T4Q5ZL53-C
  skos:prefLabel "time cell"@en, "cellule de temps"@fr ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-S1WG2Q31-4
  skos:prefLabel "onde pointue-oscillation rapide"@fr, "sharp wave ripple"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-Z24RK3Z6-C
  skos:prefLabel "hippocampe"@fr, "hippocampus"@en ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .

p66:-F2HG9RZP-D
  skos:prefLabel "theta rhythm"@en, "rythme thêta"@fr ;
  a skos:Concept ;
  skos:related p66:-M5ZF8Z68-8 .