$Multi-neuronal refractory period adapts centrally generated behaviour to reward.$

Multi-neuronal refractory period adapts centrally generated behaviour to reward.

Oscillating neuronal circuits, known as central pattern generators (CPGs), are responsible for generating rhythmic behaviours such as walking, breathing and chewing. The CPG model alone however does not account for the ability of animals to adapt their future behaviour to changes in the sensory envi...

Full description

Bibliographic Details
Main Authors:	Christopher A Harris, Christopher L Buckley, Thomas Nowotny, Peter A Passaro, Anil K Seth, György Kemenes, Michael O'Shea
Format:	Article
Language:	English
Published:	Public Library of Science (PLoS) 2012-01-01
Series:	PLoS ONE
Online Access:	http://europepmc.org/articles/PMC3409166?pdf=render

Similar Items

Refractoriness about adaptation
by: Robert P. O'shea, et al.
Published: (2015-02-01)

Role of tonic inhibition in associative reward conditioning in Lymnaea
by: Vincenzo Marra, et al.
Published: (2010-09-01)

A two-neuron system for adaptive goal-directed decision-making in Lymnaea
by: Michael Crossley, et al.
Published: (2016-06-01)

Multi-electrode analysis of pattern generation and its adaptation to reward
by: Harris, Christopher
Published: (2012)

Evidence that the delay-period activity of dopamine neurons corresponds to reward uncertainty rather than backpropagating TD errors
by: Tobler Philippe N, et al.
Published: (2005-06-01)

Coding of reward probability and risk by single neurons in animals
by: Christopher J Burke, et al.
Published: (2011-10-01)

Non-equilibrium diffusive fluxes of ions and their impact on the refractory period of tightly packed neurons
by: Oprisan Sorinel A, et al.
Published: (2011-07-01)

The relationship of the neurokinin-1 receptor to reward and learning and memory behaviours in the mouse
by: Gadd, Christopher Andrew
Published: (2003)

Sensitivity and stability: A signal propagation sweet spot in a sheet of recurrent centre crossing neurons
by: Buckley, Christopher L, et al.
Published: (2008)

Reward, Context, and Human Behaviour
by: Clare L. Blaukopf, et al.
Published: (2007-01-01)

Suppression of Dopamine Neurons Mediates Reward.
by: Nobuhiro Yamagata, et al.
Published: (2016-12-01)

Behavioural aspects of senior executive reward systems
by: Pepper, A. A. W.
Published: (2010)

The behaviour of multiple channel adaptive systems for the control of periodic sound
by: Bouucher, Christopher Charles
Published: (1992)

Leptin modulates nutrient reward via inhibitory galanin action on orexin neurons
by: Amanda Laque, et al.
Published: (2015-10-01)

Correction to: Computing reward prediction errors and learning valence in the insect mushroom body
by: James Bennett, et al.
Published: (2019-01-01)

The cost of obtaining rewards enhances the reward prediction error signal of midbrain dopamine neurons
by: Shingo Tanaka, et al.
Published: (2019-08-01)

Central mechanisms in the perception of reward
by: Kentridge, Robert William
Published: (1998)

Time dependent differential regulation of a novel long non-coding natural antisense RNA during long-term memory formation
by: Sergei Korneev, et al.
Published: (2021-02-01)

VTA GABA Neurons at the Interface of Stress and Reward
by: Chloé Bouarab, et al.
Published: (2019-12-01)

Coding of basic reward parameters by dopamine neurons
by: Tobler, Philippe Nicolas
Published: (2004)

Neuronal coding of reward during social interactions
by: Báez Mendoza, Raymundo
Published: (2014)

Transient dynamics between displaced fixed points: an alternate nonlinear dynamical framework for olfaction
by: Nowotny Thomas, et al.
Published: (2011-07-01)

Taking a Gamble for High Rewards? Management Perspectives on the Value of Mental Health Peer Workers
by: Louise Byrne, et al.
Published: (2018-04-01)

Collective behavioural responses and decision-making in the ant Temnothorax albipennis
by: O'Shea-Wheller, Thomas A.
Published: (2016)

Re-defining risk behaviours among gay men : what has changed?
by: O'Shea, Joseph.
Published: (2005)

Optogenetic mimicry of the transient activation of dopamine neurons by natural reward is sufficient for operant reinforcement.
by: Kyung Man Kim, et al.
Published: (2012-01-01)

Optogenetic Mimicry of the Transient Activation of Dopamine Neurons by Natural Reward Is Sufficient for Operant Reinforcement
by: Kim, Kyung Man, et al.
Published: (2012)

Serotonergic versus Nonserotonergic Dorsal Raphe Projection Neurons: Differential Participation in Reward Circuitry
by: Ross A. McDevitt, et al.
Published: (2014-09-01)

Central melanocortins regulate the motivation for sucrose reward.
by: Rahul Pandit, et al.
Published: (2015-01-01)

Serotonergic neurons signal reward and punishment on multiple timescales
by: Jeremiah Y Cohen, et al.
Published: (2015-02-01)

Externalising behaviour and the neural correlates of reward in adolescence
by: Sheffield, J. G.
Published: (2017)

Assessment and mechanism of the refractory period in asthma
by: Ruddick, Andrew
Published: (2015)

Some observations on the refractory period of the heart
by: Tso, T. M.
Published: (1929)

Functional heterogeneity in brain reward circuitry : characterization of a subpopulation of reward neurons linked to energy balance
by: Fulton, Stephanie E
Published: (2003)

Distinct populations of cortical pyramidal neurons mediate drug reward and aversion
by: A. F. Garcia, et al.
Published: (2021-01-01)

Chronic social stress induces peripheral and central immune activation, blunted mesolimbic dopamine function, and reduced reward-directed behaviour in mice
by: Giorgio Bergamini, et al.
Published: (2018-02-01)

Reward processing in health harming behaviour : neural and behavioural responding in obesity
by: Cambridge, Victoria Charlotte
Published: (2013)

The regulation of central noradrenergic neurones by 5-hydroxytryptamine
by: Done, Christopher John Gregers
Published: (1993)

Learning from delayed rewards
by: Watkins, Christopher John Cornish Hellaby
Published: (1989)

Icodextrin as salvage therapy in peritoneal dialysis patients with refractory fluid overload
by: Watt Rhonda, et al.
Published: (2001-12-01)