PERFORM Publications

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Title		Authors	PubMed ID
1	Different behavioral measures of conditioned magazine activity can tell different stories about brain function	Volz S; Loewinger G; Marquez I; Fevola S; Kang M; Reverte I; Krishnan A; Gardner MPH; Iordanova MD; Esber GR;	41922165 CSBN
2	Reduction in reward-driven behaviour depends on the basolateral but not central nucleus of the amygdala in female rats	Lay BPP; Esber GR; Iordanova MD;	40925675 PSYCHOLOGY
3	Disentangling prediction error and value in a formal test of dopamine s role in reinforcement learning	Usypchuk AA; Maes EJP; Lozzi M; Avramidis DK; Schoenbaum G; Esber GR; Gardner MPH; Iordanova MD;	40738112 CSBN
4	The Rescorla-Wagner Model: It Is Not What You Think It Is	Esber G; Schoenbaum G; Iordanova MD;	39805526 CSBN
5	OFC neurons do not represent the negative value of a conditioned inhibitor	Esber GR; Usypchuk A; Saini S; Deroche M; Iordanova MD; Schoenbaum G;	38042330 CONCORDIA
6	Parvalbumin interneuron loss mediates repeated anesthesia-induced memory deficits in mice	Roque PS; Thörn Perez C; Hooshmandi M; Wong C; Eslamizade MJ; Heshmati S; Brown N; Sharma V; Lister KC; Goyon VM; Neagu-Lund L; Shen C; Daccache N; Sato H; Sato T; Mogil JS; Nader K; Gkogkas CG; Iordanova MD; Prager-Khoutorsky M; McBride HM; Lacaille JC; Wykes L; Schricker T; Khoutorsky A;	36394958 PSYCHOLOGY
7	The Recruitment of a Neuronal Ensemble in the Central Nucleus of the Amygdala During the First Extinction Episode Has Persistent Effects on Extinction Expression	Lay BPP; Koya E; Hope BT; Esber GR; Iordanova MD;	36336498 PSYCHOLOGY
8	Correction to: Persistent disruption of overexpectation learning after inactivation of the lateral orbitofrontal cortex in male rats	Lay BPP; Choudhury R; Esber GR; Iordanova MD;	36006415 PSYCHOLOGY
9	Experimental chambers Persistent disruption of overexpectation learning after inactivation of the lateral orbitofrontal cortex in male rats	Lay BPP; Choudhury R; Esber GR; Iordanova MD;	35932299 PSYCHOLOGY
10	Understanding Associative Learning Through Higher-Order Conditioning	Gostolupce D; Lay BPP; Maes EJP; Iordanova MD;	35517574 PSYCHOLOGY
11	Agency rescues competition for credit assignment among predictive cues from adverse learning conditions	Kang M; Reverte I; Volz S; Kaufman K; Fevola S; Matarazzo A; Alhazmi FH; Marquez I; Iordanova MD; Esber GR;	34376741 PSYCHOLOGY
12	Mechanisms of higher-order learning in the amygdala	Gostolupce D; Iordanova MD; Lay BPP;	34197867 PSYCHOLOGY
13	Threat perception: Fear and the retrorubal field	Bradfield LA; Iordanova MD;	34033766 CSBN
14	Neural substrates of appetitive and aversive prediction error.	Iordanova MD, Yau JO, McDannald MA, Corbit LH	33453307 CSBN
15	Adaptive behaviour under conflict: deconstructing extinction, reversal, and active avoidance learning.	Manning EE, Bradfield LA, Iordanova MD	33035525 CSBN
16	Different methods of fear reduction are supported by distinct cortical substrates.	Lay BP, Pitaru AA, Boulianne N, Esber GR, Iordanova MD	32589138 PSYCHOLOGY
17	A self-initiated cue-reward learning procedure for neural recording in rodents.	Reverte I, Volz S, Alhazmi FH, Kang M, Kaufman K, Chan S, Jou C, Iordanova MD, Esber GR	32135212 CSBN
18	Causal evidence supporting the proposal that dopamine transients function as temporal difference prediction errors.	Maes EJP, Sharpe MJ, Usypchuk AA, Lozzi M, Chang CY, Gardner MPH, Schoenbaum G, Iordanova MD	31959935 CSBN
19	Neural correlates of two different types of extinction learning in the amygdala central nucleus.	Iordanova MD, Deroche ML, Esber GR, Schoenbaum G	27531638 CSBN
20	Dopamine Signaling Is Critical for Supporting Cue-Driven Behavioral Control.	Iordanova MD	31103706 PSYCHOLOGY
21	Thought control with the dopamine transient.	Iordanova MD	30338459 CSBN
22	Dissociation of Appetitive Overexpectation and Extinction in the Infralimic Cortex.	Lay BPP, Nicolosi M, Usypchuk AA, Esber GR, Iordanova MD	30371757 CSBN
23	Corrigendum: Dissociation of Appetitive Overexpectation and Extinction in the Infralimbic Cortex.	Lay BPP, Nicolosi M, Usypchuk AA, Esber GR, Iordanova MD	30590441 CSBN
24	The serial blocking effect: a testbed for the neural mechanisms of temporal-difference learning.	Mahmud A; Petrov P; Esber GR; Iordanova MD;	30979910 CSBN

Title:	Adaptive behaviour under conflict: deconstructing extinction, reversal, and active avoidance learning.
Authors:	Manning EE, Bradfield LA, Iordanova MD
Link:	https://www.ncbi.nlm.nih.gov/pubmed/33035525
DOI:	10.1016/j.neubiorev.2020.09.030
Publication:	Neuroscience and biobehavioral reviews
Keywords:	Active avoidance; Amygdala; Conflict; Extinction; Prefrontal cortex; Reversal;
PMID:	33035525	Category:	Neurosci Biobehav Rev	Date Added:	2020-10-10
Dept Affiliation:	CSBN 1 Department of Psychiatry, University of Pittsburgh, Suite 223, 450 Technology Drive, Pittsburgh, PA, 15224, USA; School of Biomedical Sciences and Pharmacy, University of Newcastle, MS306, University Drive, Callaghan, NSW, 2308, Australia. Electronic address: lizzie.manning@newcastle.edu.au. 2 Centre for Neuroscience and Regenerative Medicine, University of Technology Sydney (St. Vincent's Campus), 405 Liverpool St, Darlinghurst, NSW, 2010, Australia; St. Vincent's Centre for Applied Medical Research, St. Vincent's Hospital Sydney Limited, 405 Liverpool St, Darlinghurst, NSW, 2010, Australia. Electronic address: Laura.Bradfield@uts.edu.au. 3 Department of Psychology/Centre for Studies in Behavioural Neurobiology, Concordia University, Montreal, Canada. Electronic address: mihaela.iordanova@concordia.ca.

Description:

Adaptive behaviour under conflict: deconstructing extinction, reversal, and active avoidance learning.

Neurosci Biobehav Rev. 2020 Oct 06; :

Authors: Manning EE, Bradfield LA, Iordanova MD

Abstract

In complex environments, organisms must respond adaptively to situations despite conflicting information. Under natural (i.e. non-laboratory) circumstances, it is rare that cues or responses are consistently paired with a single outcome. Inconsistent pairings are more common, as are situations where cues and responses are associated with multiple outcomes. Such inconsistency creates conflict, and a response that is adaptive in one scenario may not be adaptive in another. Learning to adjust responses accordingly is important for species to survive and prosper. Here we review the behavioural and brain mechanisms of responding under conflict by focusing on three popular behavioural procedures: extinction, reversal learning, and active avoidance. Extinction involves adapting from reinforcement to non-reinforcement, reversal learning involves swapping the reinforcement of cues or responses, and active avoidance involves performing a response to avoid an aversive outcome, which may conflict with other defensive strategies. We note that each of these phenomena relies on somewhat overlapping neural circuits, suggesting that such circuits may be critical for the general ability to respond appropriately under conflict.

PMID: 33035525 [PubMed - as supplied by publisher]

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