Abstract is: Richard Graham Michael Morris, CBE FRS FRSE (born 27 June 1948), is a British neuroscientist. He is known for developing the Morris water navigation task, for proposing the concept of synaptic tagging (along with Uwe Frey), and for his work on the function of the hippocampus. He is the director of the Centre for Cognitive and Neural Systems (Edinburgh) and the Wolfson Professor of Neuroscience at the University of Edinburgh. Since 1994 he has been a fellow of the Royal Society of Edinburgh and since 1997, he has been a fellow of the Royal Society. Morris was appointed a Commander of the Order of the British Empire in 2007. Morris, together with Tim Bliss (Francis Crick Institute) and Graham Collingridge (University of Bristol) were named as winners of the 2016 Brain Prize for their discoveries about the way synaptic connections in the hippocampus are strengthened by stimulation. The process, known as long-term potentiation (LTP), forms the basis of the ability to learn and to remember. He was elected Member of the National Academy of Sciences in April 2020.
human | Q5 |
P2381 | Academic Tree ID | 3369 |
P268 | Bibliothèque nationale de France ID | 14643202j |
P8179 | Canadiana Name Authority ID | ncf11362590 |
P11496 | CiNii Research ID | 1140563741683217792 |
P7902 | Deutsche Biographie (GND) ID | 104607072X |
P6178 | Dimensions author ID | 016400336552.63 |
P9985 | EMBO member ID | richard-gm-morris |
P2070 | Fellow of the Royal Society ID | 11978 |
P646 | Freebase ID | /m/0nd31z_ |
P227 | GND ID | 104607072X |
P269 | IdRef ID | 083067957 |
P213 | ISNI | 000000002791695X |
P409 | Libraries Australia ID | 35363714 |
P244 | Library of Congress authority ID | n88185121 |
P271 | NACSIS-CAT author ID | DA03879954 |
P949 | National Library of Israel ID (old) | 002306605 |
P8189 | National Library of Israel J9U ID | 987007447767405171 |
P7699 | National Library of Lithuania ID | LNB:CU2B;=vN |
P1006 | Nationale Thesaurus voor Auteursnamen ID | 08007961X |
P691 | NL CR AUT ID | jo2014809460 |
P1315 | NLA Trove people ID | 507879 |
P1015 | NORAF ID | 90542276 |
P1207 | NUKAT ID | n2014136502 |
P856 | official website | http://www.ccns.sbms.mvm.ed.ac.uk/people/academic/morris.html |
P496 | ORCID iD | 0000-0001-8661-1520 |
P7293 | PLWABN ID | 9812426100005606 |
P1153 | Scopus author ID | 7404059483 |
P3430 | SNAC ARK ID | w6p28cnt |
P10861 | Springer Nature person ID | 016400336552.63 |
P214 | VIAF ID | 2728709 |
P10832 | WorldCat Entities ID | E39PBJhCF6gDDQcFWVjV9JfDv3 |
P166 | award received | Commander of the Order of the British Empire | Q12201477 |
Fellow of the Royal Society | Q15631401 | ||
Neuronal Plasticity Prize | Q1266070 | ||
Feldberg Foundation | Q1402356 | ||
The Brain Prize | Q18357422 | ||
EMBO Membership | Q26268243 | ||
P1477 | birth name | Richard Graham Michael Morris | |
P27 | country of citizenship | United Kingdom | Q145 |
P69 | educated at | University of Sussex | Q1161297 |
Trinity Hall | Q1244704 | ||
P108 | employer | British Museum | Q6373 |
Wellcome Trust | Q326276 | ||
University of Edinburgh | Q160302 | ||
Durham University Faculty of Science | Q86005113 | ||
BBC Radio London | Q4834838 | ||
P734 | family name | Morris | Q2780710 |
Morris | Q2780710 | ||
Morris | Q2780710 | ||
P735 | given name | Richard | Q1249148 |
Richard | Q1249148 | ||
P1412 | languages spoken, written or signed | English | Q1860 |
P463 | member of | American Association for the Advancement of Science | Q40358 |
Royal Society | Q123885 | ||
American Academy of Arts and Sciences | Q463303 | ||
Royal Norwegian Society of Sciences and Letters | Q1201052 | ||
P106 | occupation | biologist | Q864503 |
university teacher | Q1622272 | ||
neuroscientist | Q6337803 | ||
P21 | sex or gender | male | Q6581097 |
Q92685001 | A stable home-base promotes allocentric memory representations of episodic-like everyday spatial memory |
Q48250765 | Active beta-amyloid immunization restores spatial learning in PDAPP mice displaying very low levels of beta-amyloid |
Q47629578 | Angular Gyrus Involvement at Encoding and Retrieval Is Associated with Durable But Less Specific Memories |
Q42254693 | Anterior cingulate cortex in schema assimilation and expression |
Q51906403 | BACE1 gene deletion: impact on behavioral function in a model of Alzheimer's disease. |
Q37403067 | Behavioral deficits and subregion-specific suppression of LTP in mice expressing a population of mutant NMDA receptors throughout the hippocampus |
Q38432841 | Building on prior knowledge: schema-dependent encoding processes relate to academic performance |
Q43890700 | Chronic treatment with the antidepressant amitriptyline prevents impairments in water maze learning in aging rats. |
Q51995610 | Competing for memory: hippocampal LTP under regimes of reduced protein synthesis. |
Q34082941 | Competition between recently potentiated synaptic inputs reveals a winner-take-all phase of synaptic tagging and capture |
Q46610675 | Conditional inactivation of presenilin 1 prevents amyloid accumulation and temporarily rescues contextual and spatial working memory impairments in amyloid precursor protein transgenic mice. |
Q56920279 | Correction to 'Experiential contributions to social dominance in a rat model of fragile-X syndrome' |
Q34428656 | Distinct contributions of hippocampal NMDA and AMPA receptors to encoding and retrieval of one-trial place memory. |
Q37022585 | Does assimilation into schemas involve systems or cellular consolidation? It's not just time |
Q43174636 | Dopamine and memory: modulation of the persistence of memory for novel hippocampal NMDA receptor-dependent paired associates |
Q28582452 | Dopaminergic modulation of the persistence of one-trial hippocampus-dependent memory |
Q36974723 | Early detection of cryptic memory and glucose uptake deficits in pre-pathological APP mice |
Q36527016 | Elements of a neurobiological theory of hippocampal function: the role of synaptic plasticity, synaptic tagging and schemas |
Q35126365 | Elements of a neurobiological theory of the hippocampus: the role of activity-dependent synaptic plasticity in memory |
Q46979967 | Enhanced hippocampal long-term potentiation and spatial learning in aged 11beta-hydroxysteroid dehydrogenase type 1 knock-out mice. |
Q56920287 | Experiential contributions to social dominance in a rat model of fragile-X syndrome |
Q41809433 | Faster forgetting contributes to impaired spatial memory in the PDAPP mouse: deficit in memory retrieval associated with increased sensitivity to interference? |
Q35929124 | Festina lente: late-night thoughts on high-throughput screening of mouse behavior |
Q41882716 | Forget me not. |
Q24798819 | Forgetting, reminding, and remembering: the retrieval of lost spatial memory |
Q48285613 | Frequency-Dependent Gating of Hippocampal-Neocortical Interactions |
Q27330510 | From rapid place learning to behavioral performance: a key role for the intermediate hippocampus |
Q44994140 | Heterosynaptic co-activation of glutamatergic and dopaminergic afferents is required to induce persistent long-term potentiation |
Q37540059 | Hippocampal-neocortical interactions in memory formation, consolidation, and reconsolidation |
Q34984286 | Homeostatic shutdown of long-term potentiation in the adult hippocampus |
Q48245625 | Initial investigation of the effects of an experimentally learned schema on spatial associative memory in humans |
Q35124797 | Introduction. Long-term potentiation and structure of the issue |
Q40877168 | Long-term potentiation and memory |
Q48225422 | Longitudinal axis of the hippocampus: both septal and temporal poles of the hippocampus support water maze spatial learning depending on the training protocol |
Q53708799 | Lost and found. |
Q48129686 | MSK1 regulates homeostatic and experience-dependent synaptic plasticity. |
Q37822273 | Making memories last: the synaptic tagging and capture hypothesis |
Q27021354 | Memorable trends |
Q34521946 | Memory reconsolidation: sensitivity of spatial memory to inhibition of protein synthesis in dorsal hippocampus during encoding and retrieval |
Q38370263 | Memory, modelling and Marr: a commentary on Marr (1971) 'Simple memory: a theory of archicortex' |
Q51936178 | Messing about in memory. |
Q43531670 | N-methyl-d-aspartate receptors, learning and memory: chronic intraventricular infusion of the NMDA receptor antagonist d-AP5 interacts directly with the neural mechanisms of spatial learning. |
Q38102828 | NMDA receptors and memory encoding |
Q48600831 | Neuroscience. The imaginary mind of a mouse |
Q48581361 | Neuroscience: Shedding light on a change of mind |
Q51942914 | Neurotoxic lesions of the thalamic reuniens or mediodorsal nucleus in rats affect non-mnemonic aspects of watermaze learning. |
Q34320443 | Relevance of synaptic tagging and capture to the persistence of long-term potentiation and everyday spatial memory |
Q34395207 | Retrograde amnesia: neither partial nor complete hippocampal lesions in rats result in preferential sparing of remote spatial memory, even after reminding |
Q49076920 | Schema-dependent gene activation and memory encoding in neocortex |
Q34616466 | Schemas and memory consolidation |
Q48524176 | Spatial learning is unimpaired in mice containing a deletion of the alpha-synuclein locus |
Q51989562 | Spatial learning with unilateral and bilateral hippocampal networks. |
Q41878262 | Spatial memory: behavioral determinants of persistence in the watermaze delayed matching-to-place task |
Q33400311 | State based model of long-term potentiation and synaptic tagging and capture |
Q28509691 | SynGAP regulates ERK/MAPK signaling, synaptic plasticity, and learning in the complex with postsynaptic density 95 and NMDA receptor |
Q42738539 | Synaptic plasticity in health and disease: introduction and overview |
Q39508345 | Synaptic tagging and capture in the living rat |
Q48246778 | Synaptic tagging and capture: differential role of distinct calcium/calmodulin kinases in protein synthesis-dependent long-term potentiation |
Q38919371 | The Kinase Function of MSK1 Regulates BDNF Signaling to CREB and Basal Synaptic Transmission, But Is Not Required for Hippocampal Long-Term Potentiation or Spatial Memory. |
Q48045299 | The mantle of the heavens: Reflections on the 2014 Nobel Prize for medicine or physiology |
Q50657400 | The memory paradox. |
Q41878130 | The role of rewarding and novel events in facilitating memory persistence in a separate spatial memory task |
Q38168197 | The synaptic plasticity and memory hypothesis: encoding, storage and persistence |
Q46216525 | Upstairs/downstairs revisited: spatial pretraining-induced rescue of normal spatial learning during selective blockade of hippocampal N-methyl-d-aspartate receptors |
Q48462545 | euroSCIENCE moves into sixth gear! |
Q1417562 | Morris water navigation task | named after | P138 |
Q118139284 | Fynn Comerford | student of | P1066 |
Richard G. Morris | wikipedia | |
Arabic (ar / Q13955) | ريتشارد موريس | wikipedia |
Richard G. Morris | wikipedia | |
Richard G. Morris | wikipedia | |
Richard G. Morris | wikipedia | |
en-simple | Richard G. Morris | wikipedia |
Richard G. Morris | wikipedia | |
Richard G. Morris | wikipedia | |
Richard G. Morris | wikipedia | |
Richard Morris | wikipedia | |
Richard G. Morris | wikipedia | |
理查德·G·莫里斯 | wikipedia |
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