Keyword search (4,163 papers available)

"Shizgal P" Authored Publications:

Title Authors PubMed ID
1 Discriminative properties of rewarding electrical brain stimulation Pacheco-Gomez BL; Zepeda-Ruiz WA; Velazquez-Lopez D; Shizgal P; Velazquez-Martinez DN; 40015584
CSBN
2 Does phasic dopamine release cause policy updates? Carter F; Cossette MP; Trujillo-Pisanty I; Pallikaras V; Breton YA; Conover K; Caplan J; Solis P; Voisard J; Yaksich A; Shizgal P; 38039083
PSYCHOLOGY
3 Dopamine and Beyond: Implications of Psychophysical Studies of Intracranial Self-Stimulation for the Treatment of Depression Pallikaras V; Shizgal P; 36009115
PSYCHOLOGY
4 The Convergence Model of Brain Reward Circuitry: Implications for Relief of Treatment-Resistant Depression by Deep-Brain Stimulation of the Medial Forebrain Bundle Pallikaras V; Shizgal P; 35431828
PSYCHOLOGY
5 The trade-off between pulse duration and power in optical excitation of midbrain dopamine neurons approximates Bloch's law Pallikaras V; Carter F; Velazquez-Martinez DN; Arvanitogiannis A; Shizgal P; 34864162
PSYCHOLOGY
6 Dopamine neurons do not constitute an obligatory stage in the final common path for the evaluation and pursuit of brain stimulation reward. Trujillo-Pisanty I, Conover K, Solis P, Palacios D, Shizgal P 32502210
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7 The priming effect of food persists following blockade of dopamine receptors. Evangelista C, Hantson A, Shams WM, Almey A, Pileggi M, Voisard JR, Boulos V, Al-Qadri Y, Gonzalez Cautela BV, Zhou FX, Duchemin J, Habrich A, Tito N, Koumrouyan RA, Patel S, Lorenc V, Gagne C, El Oufi K, Shizgal P, Brake WG 31350860
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8 Learning to use past evidence in a sophisticated world model. Ahilan S, Solomon RB, Breton YA, Conover K, Niyogi RK, Shizgal P, Dayan P 31233559
CSBN
9 Ventral Midbrain NMDA Receptor Blockade: From Enhanced Reward and Dopamine Inactivation. Hernandez G, Cossette MP, Shizgal P, Rompré PP 27616984
PSYCHOLOGY
10 Valuation of opportunity costs by rats working for rewarding electrical brain stimulation. Solomon RB, Conover K, Shizgal P 28841663
PSYCHOLOGY
11 17β-estradiol locally increases phasic dopamine release in the dorsal striatum. Shams WM, Cossette MP, Shizgal P, Brake WG 29175028
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12 Some work and some play: microscopic and macroscopic approaches to labor and leisure. Niyogi RK, Shizgal P, Dayan P 25474151
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13 Robust optical fiber patch-cords for in vivo optogenetic experiments in rats. Trujillo-Pisanty I, Sanio C, Chaudhri N, Shizgal P 26150997
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14 The neural substrates for the rewarding and dopamine-releasing effects of medial forebrain bundle stimulation have partially discrepant frequency responses. Cossette MP, Conover K, Shizgal P 26477378
CSBN
15 The Effects of Electrical and Optical Stimulation of Midbrain Dopaminergic Neurons on Rat 50-kHz Ultrasonic Vocalizations. Scardochio T, Trujillo-Pisanty I, Conover K, Shizgal P, Clarke PB 26696851
CSBN

 

Title:Learning to use past evidence in a sophisticated world model.
Authors:Ahilan SSolomon RBBreton YAConover KNiyogi RKShizgal PDayan P
Link:https://www.ncbi.nlm.nih.gov/pubmed/31233559?dopt=Abstract
DOI:10.1371/journal.pcbi.1007093
Publication:PLoS computational biology
Keywords:
PMID:31233559 Category:PLoS Comput Biol Date Added:2019-06-25
Dept Affiliation: CSBN
1 Gatsby Computational Neuroscience Unit, University College London, London, United Kingdom.
2 Center for Studies in Behavioral Neurobiology, Concordia University, Montreal, Canada.
3 Department of Experimental Psychology, University of Oxford, Oxford, United Kingdom.
4 Max Planck Institute for Biological Cybernetics, Tübingen, Germany.

Description:

Learning to use past evidence in a sophisticated world model.

PLoS Comput Biol. 2019 Jun 24;15(6):e1007093

Authors: Ahilan S, Solomon RB, Breton YA, Conover K, Niyogi RK, Shizgal P, Dayan P

Abstract

Humans and other animals are able to discover underlying statistical structure in their environments and exploit it to achieve efficient and effective performance. However, such structure is often difficult to learn and use because it is obscure, involving long-range temporal dependencies. Here, we analysed behavioural data from an extended experiment with rats, showing that the subjects learned the underlying statistical structure, albeit suffering at times from immediate inferential imperfections as to their current state within it. We accounted for their behaviour using a Hidden Markov Model, in which recent observations are integrated with evidence from the past. We found that over the course of training, subjects came to track their progress through the task more accurately, a change that our model largely attributed to improved integration of past evidence. This learning reflected the structure of the task, decreasing reliance on recent observations, which were potentially misleading.

PMID: 31233559 [PubMed - as supplied by publisher]




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