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21 - Experience-induced Changes Reveal Functional Dissociation within Olfactory Pathways

Published online by Cambridge University Press:  21 September 2009

By
Nadine Ravel ,
Anne-Marie Mouly ,
Pascal Chabaud  and
Rémi Gervais
Edited by
Catherine Rouby ,
Benoist Schaal ,
Danièle Dubois ,
Rémi Gervais  and
A. Holley
Nadine Ravel
Affiliation:
Institut des Sciences Cognitives, CNRS/Université Claude Bernard, Lyon 1, 69675, Bron, France
Anne-Marie Mouly
Affiliation:
Institut des Sciences Cognitives, CNRS/Université Claude Bernard, Lyon 1, 69675, Bron, France
Pascal Chabaud
Affiliation:
Institut des Sciences Cognitives, CNRS/Université Claude Bernard, Lyon 1, 69675, Bron, France
Rémi Gervais
Affiliation:
Research Director CNRS, Institut des Sciences Cognitives, Lyon
Catherine Rouby
Affiliation:
Université Lyon I
Benoist Schaal
Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
Danièle Dubois
Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
Rémi Gervais
Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
A. Holley
Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris
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Summary

Learning more about the neural basis of olfactory cognition should greatly improve our understanding of how different brain structures deal with information. Progress can be facilitated by simultaneous advances with animal models and human studies, for in the olfactory system, conservatism across mammalian species in the organization of olfactory pathways allows integration of data obtained in animals and humans. In each species, output neurons from the olfactory bulb (OB) monosynaptically reach the piriform cortex (PC), the peri-amygdaloid cortex, and the lateral entorhinal cortex (LEC). The LEC provides massive input to the hippocampus, and the PC sends information to the orbitofrontal neocortical area, both directly and after a relay in the dorsomedial thalamic nuclei (Haberly, 1998). As in other sensory systems, two strategies have been developed thus far in order to identify hierarchical organization: collecting information from one structure at a time, and looking at the system as a network of interconnected structures. The first strategy is typical for most animal studies and is implemented through single-cell recordings in anesthetized animals (Mori, Nagao, and Yoshiara, 1999) and active animals (Schoenbaum, Chiba, and Gallagher, 1999; Weibe and Staubli, 1999; Wood, Dudchenko, and Eichenbaum, 1999) or through surface EEG recordings in awake restrained animals (Freeman and Skarda, 1985). When using anesthetized animals, most studies have focused on the OB, and fewer on the PC. When using active rats, such studies have investigated hippocampal, amygdalar, and orbitofrontal electrophysiological characteristics.

Type
Chapter
Information
Olfaction, Taste, and Cognition , pp. 335 - 349
Publisher: Cambridge University Press
Print publication year: 2002

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References

, Boeijinga P H & , Lopes da Silva F H (1989). Modulations of EEG Activity in the Entorhinal Cortex and Forebrain Olfactory Areas during Odour Sampling. Brain Research 478:257–68CrossRefGoogle Scholar
, Chabaud P, , Ravel N, , Wilson D A, & , Gervais R (1999). Functional Coupling in Rat Central Olfactory Pathways: A Coherence Analysis. Neuroscience Letters 273:1–4Google Scholar
, Chabaud P, , Ravel N, , Wilson D A, , Mouly A M, , Vigouroux M, , Farget V, & , Gervais R (2000). Exposure to Behaviourally Relevant Odour Reveals Differential Characteristics in Central Rat Olfactory Pathways as Studied through Oscillatory Activities. Chemical Senses 25:561–73CrossRefGoogle Scholar
, Edeline J M (1999). Learning-induced Physiological Plasticity in the Thalamo-cortical Sensory Systems: A Critical Evaluation of Receptive Field Plasticity, Map Changes and Their Potential Mechanisms. Progress in Neurobiology 57:165–224CrossRefGoogle Scholar
Freeman W J (1975). Mass Action in the Nervous System. New York: Academic Press
, Freeman W J & , Schneider W (1982). Changes in Spatial Patterns of Rabbit Olfactory EEG with Conditioning to Odors. Psychophysiology 19:44–56CrossRefGoogle Scholar
, Freeman W J & , Skarda C (1985). Spatial EEG Patterns, Nonlinear Dynamics and Perception: The Neo-Sherringhtonian View. Brain Research Reviews 10:147–75CrossRefGoogle Scholar
Gervais R (1993). Olfactory Processing Controlling Food and Fluid Intake. In: Neurophysiology of Ingestion, ed. D Booth, pp. 119–35. Oxford: Pergamon PressCrossRef
, Gervais R, , Holley A, & , Keverne E B (1988). The Importance of Central Noradrenergic Influences on the Rat Olfactory Bulb in the Processing of Learned Olfactory Cues. Chemical Senses 13:3–12CrossRefGoogle Scholar
, Haberly L B (1985). Neural Circuitry in Olfactory Cortex: Anatomy and Functional Implications. Chemical Senses 10:219–38CrossRefGoogle Scholar
Haberly L B (1998). Olfactory Cortex. In: The Synaptic Organization of the Brain, ed. G M Shepherd, pp. 377–416. Oxford University Press
, Jung M W, , Larson J, & , Lynch G (1990). Long-Term Potentiation of Monosynaptic EPSPs in Rat Piriform Cortex in vitro. Synapse 6:279–83CrossRefGoogle Scholar
, Kanter E D & , Haberly L B (1990). NMDA-dependent Induction of Long-Term Potentiation in Afferent and Association Fiber Systems of Piriform Cortex in vitro. Brain Research 525:175–9CrossRefGoogle Scholar
, Kay L M & , Freeman W J (1998). Bidirectional Processing in the Olfactory-Limbic Axis during Olfactory Behavior. Behavioral Neuroscience 112:541–53CrossRefGoogle Scholar
, Kay L M & , Laurent G (1999). Odor- and Context-dependent Modulation of Mitral Cell Activity in Behaving Rats. Nature Neuroscience 2:1003–9CrossRefGoogle Scholar
, Mathai P & , Cattarelli M (1996). Olfactory Bulb Repetitive Stimulations Reveal Non-homogeneous Distribution of the Inhibitory Processes in the Rat Piriform Cortex. European Journal of Neuroscience 8:21–9CrossRefGoogle Scholar
, Litaudon P, , Mouly A M, , Sullivan R, , Gervais R, & , Cattarelli M (1997). Learning-induced Changes in Piriform Cortex Evoked Activity Using Multisite Recordings with Voltage Sensitive Dye. European Journal of Neuroscience 9:1593–602CrossRefGoogle Scholar
, Lynch G & , Granger R (1989). Simulation and Analysis of a Simple Cortical Network. Psychology: Learning and Motivation 23:205–41Google Scholar
, Mori K, , Nagao H, & , Yoshiara Y (1999). The Olfactory Bulb: Coding and Processing of Odor Molecule Information. Science 286:711–15CrossRefGoogle Scholar
, Morris R G M, , Anderson E, , Lynch G S, & , Baudry M (1986). Selective Impairment of Learning and Blockade of Long-Term Potentiation by an N-methyl-d-aspartate Receptor Antagonist, AP5. Nature 319:774–6CrossRefGoogle Scholar
, Mouly A M, , Fort A, , Ben-Boutayab N, & , Gervais R (2001). Olfactory Learning Induces Differential Long-Lasting Changes in Rat Central Olfactory Pathways. Neuroscience 102:11–21CrossRefGoogle Scholar
, Mouly A M, , Kindermann U, , Gervais R, & , Holley A (1993). Evidence for the Involvement of the Olfactory Bulb in Consolidation Processes Associated with Long-Term Memory. Behavioral Neuroscience 107:451–7CrossRefGoogle Scholar
, Mouly A M, , Vigouroux M, & , Holley A (1985). On the Ability of Rats to Discriminate between Microstimulations of the Olfactory Bulb in Different Locations. Behavioral Brain Research 17:47–58Google Scholar
, O'Doherty J, , Rolls E, , Francis S, , Bowtell R, , McGlone F, , Kobal G, , Renner B, & , Ahne G (2000). Sensory-specific Satiety-related Olfactory Activation of the Human Orbitofrontal Cortex. NeuroReport 11:893–7CrossRefGoogle Scholar
, Pager J (1983). Unit Responses Changing with Behavioral Outcome in the Olfactory Bulb of Unrestrained Rats. Brain Research 289:87–98CrossRefGoogle Scholar
, Pager J, , Giachetti I, , Holley A, & , Magnen J (1972). A Selective Control of Olfactory Bulb Electrical Activity in Relation to Food Deprivation and Satiety in Rats. Physiology and Behavior 9:573–9CrossRefGoogle Scholar
, Qureshy A, , Kawashima R, , Imram M B, , Sugiura M, , Goto R, , Okada K, , Inoue K, , Itoh M, , Schormann T, , Zilles K, & , Fukuda H (2000). Functional Mapping of Human Brain in Olfactory Processing: A PET Study. Journal of Neurophysiology 84:1656–66CrossRefGoogle Scholar
Ravel N, Chabaud P, & Gervais R (1999). Learning Induces Specific Changes in Odor-evoked Oscillations in Beta and Gamma Bands in Rat Central Olfactory Pathways. Presented at a meeting of the Society for Neuroscience, Miami, 23–28 October (abstract)
, Ravel N, , Elaagouby A, & , Gervais R (1994). Scopolamine Injection into the Olfactory Bulb Impairs Short-Term Olfactory Memory. Behavioral Neuroscience 108:317–24CrossRefGoogle Scholar
, Roman F, , Staubli U, & , Lynch G (1987). Evidence for Synaptic Potentiation in a Cortical Network during Learning. Brain Research 418:221–6CrossRefGoogle Scholar
, Royet J P, , Koenig O, , Gregoire M C, , Cinotti L, , Lavenne F, , Bars D, , Costes N, , Vigouroux M, , Farget V, , Sicard G, , Holley A, , Mauguière F, , Comar D, & , Froment J C (1999). Functional Anatomy of Perceptual and Semantic Processing for Odors. Journal of Cognitive Neuroscience 11:94–109CrossRefGoogle Scholar
, Royet J P, , Zald D, , Versace R, , Costes N, , Lavenne F, , Koenig O, & , Gervais R (2000). Emotional Responses to Pleasant and Unpleasant Olfactory, Visual, and Auditory Stimuli: A PET Study. Journal of Neuroscience 20:7752–9CrossRefGoogle Scholar
, Savic I, , Gulyas B, , Larsson M, & , Roland P (2000). Olfactory Functions Are Mediated by Parallel and Hierarchical Processing. Neuron 26:735–45CrossRefGoogle Scholar
, Schoenbaum G, , Chiba A, & , Gallagher M (1999). Neural Encoding in Orbitofrontal Cortex and Basolateral Amydala during Olfactory Discrimination Learning. Journal of Neuroscience 19:1876–84CrossRefGoogle Scholar
, Singer W (1999). Neural Synchrony: A Versatile Code for the Definition of Relations?Neuron 24:49–65CrossRefGoogle Scholar
, Sobel N, , Prabhakaran V, , Desmond J E, , Glover G H, , Goodes R L, , Sullivan E, & , Gabrieli D E (1998). Sniffing and Smelling: Separate Subsystems in the Human Olfactory Cortex. Nature 392:282–6CrossRefGoogle Scholar
, Sobel N, , Prabhakaran V, , Zhao Z, , Desmond J, , Glover G H, , Sullivan E V, & , Gabrieli J D E (2000). Time Course of Odorant-induced Activation in Human Primary Olfactory Cortex. Journal of Neurophysiology 83:537–51CrossRefGoogle Scholar
, Stripling J S, , Patneau D K, & , Gramlich C A (1988). Selective Long-Term Potentiation in the Piriform Cortex. Brain Research 441:281–91CrossRefGoogle Scholar
, Weibe S P & , Staubli U (1999). Dynamic Filtering of Recognition Memory Codes in the Hippocampus. Journal of Neuroscience 19:10562–74CrossRefGoogle Scholar
, Wilson D A (1998). Habituation of Odor Responses in the Rat Anterior Piriform Cortex. Journal of Neurophysiology 79:1425–40CrossRefGoogle Scholar
Wilson M A & Bower J M (1988). A Computer Simulation of Olfactory Cortex with Functional Implications for Storage and Retrieval of Olfactory Information. In: Neural Information Processing Systems, ed. D Anderson, pp. 114–26. New York: AIP Press
, Wood E R, , Dudchenko P A, & , Eichenbaum H (1999). The Global Record of Memory in Hippocampal Neuronal Activity. Nature 397:613–16CrossRefGoogle Scholar
, Zald D H & , Pardo J V (2000). Functional Neuroimaging of the Olfactory System in Humans. International Journal of Psychophysiology 36:165–81CrossRefGoogle Scholar
, Zatore R J, , Jones-Gotman M, , Evans A, & , Meyer E (1992). Functional Localization and Lateralization of Human Olfactory Cortex. Nature 360:339–40CrossRefGoogle Scholar
, Zatore R, , Jones-Gotman M, & , Rouby C (2000). Neural Mechanisms Involved in Odor Pleasantness and Intensity Judgments. NeuroReport 11:2711–16CrossRefGoogle Scholar

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