The Cortical Representation of Taste and Smell

Edmund T. Rolls

doi:10.1017/CBO9780511546389.031

23 - The Cortical Representation of Taste and Smell

Published online by Cambridge University Press: 21 September 2009

Edited by

Rémi Gervais and

Edmund T. Rolls: Affiliation:
Department of Experimental Psychology, University of Oxford, South Parks Road, Oxford OX1 3UD, England
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

The aims of this chapter are to describe the rules that appear to govern the cortical processing of taste and smell, how taste and smell inputs combine with each other to form flavor, how visual and oral somatosensory inputs also converge with taste and smell, and how hunger affects the representations in different cortical areas. Particular attention is paid to investigations in a non-human primate, the macaque, because they have provided fundamental evidence relevant to understanding information processing in the same areas in humans, and to neuroimaging studies in humans to complement the primate studies. A broad perspective on the brain processing involved in emotion and motivation is provided elsewhere (Rolls, 1999a).

Taste Pathways in Primates

A diagram of the taste and related pathways in primates is shown in Figure 23.1. Of particular interest is that in primates there is a direct projection from the rostral part of the nucleus of the solitary tract (NTS) to the taste thalamus and thus to the primary taste cortex in the frontal operculum and adjoining insula (Figure 23.2), with no pontine taste area and associated subcortical projections as in rodents (Norgren, 1984; Pritchard et al., 1986). The emphasis on cortical processing of taste in primates appears to be related to the extensive development of the cerebral cortex in primates and to the advantage of using similar cortical analyses of inputs from every sensory modality before the analyzed representations from all modalities are brought together in multimodal regions, as will be documented here.

Type: Chapter
Information: Olfaction, Taste, and Cognition , pp. 367 - 388

DOI: https://doi.org/10.1017/CBO9780511546389.031 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2002

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References

, Aggleton J P & , Passingham R E (1981). Syndrome Produced by Lesions of the Amygdala in Monkeys (Macaca mulatta). Journal of Comparative Physiology and Psychology 95:961–77CrossRef Google Scholar

, Baylis L L & , Gaffan D (1991). Amygdalectomy and Ventromedial Prefrontal Ablation Produce Similar Deficits in Food Choice and in Simple Object Discrimination Learning for an Unseen Reward. Experimental Brain Research 86:617–22Google Scholar

, Baylis L L & , Rolls E T (1991). Responses of Neurons in the Primate Taste Cortex to Glutamate. Physiology and Behavior 49:973–9CrossRef Google Scholar

, Baylis L L, , Rolls E T, & , Baylis G C (1994). Afferent Connections of the Orbitofrontal Cortex Taste Area of the Primate. Neuroscience 64:801–12Google Scholar

, Burton M J, , Rolls E T, & , Mora F (1976). Effects of Hunger on the Responses of Neurones in the Lateral Hypothalamus to the Sight and Taste of Food. Experimental Neurology 51:668–77CrossRef Google Scholar

, Cabanac M (1971). Biological Role of Pleasure. Science 173:1103–7CrossRef Google Scholar

, Cabanac M & , Duclaux R (1970). Specificity of Internal Signals in Producing Satiety for Taste Stimuli. Nature 227:966–7CrossRef Google Scholar

, Cabanac M & , Fantino M (1977). Origin of Olfacto-gustatory Alliesthesia: Intestinal Sensitivity to Carbohydrate Concentration?Physiology and Behavior 10:1039–45Google Scholar

, Carmichael S T, , Clugnet M C, & , Price J L (1994). Central Olfactory Connections in the Macaque Monkey. Journal of Comparative Neurology 346:403–34CrossRef Google Scholar

, Chaudhari N & , Roper S D (1998). Molecular and Physiological Evidence for Glutamate (Umami) Taste Transduction via a G-Protein-coupled Receptor. Annals of the New York Academy of Sciences 855:398–406CrossRef Google Scholar

, Chaudhari N, , Yang H, , Lamp C, , Delay E, , Cartford C, , Than T, & , Roper S (1996). The Taste of Monosodium Glutamate: Membrane Receptors in Taste Buds. Journal of Neuroscience 16:3817–26CrossRef Google Scholar

, Critchley H D & , Rolls E T (1996a). Olfactory Neuronal Responses in the Primate Orbitofrontal Cortex: Analysis in an Olfactory Discrimination Task. Journal of Neurophysiology 75:1659–72CrossRef Google Scholar

, Critchley H D & , Rolls E T (1996b). Hunger and Satiety Modify the Responses of Olfactory and Visual Neurons in the Primate Orbitofrontal Cortex. Journal of Neurophysiology 75:1673–86CrossRef Google Scholar

, Francis S, , Rolls E T, , Bowtell R, , McGlone F, , O'Doherty J, , Browning A, , Clare S, & , Smith E (1999). The Representation of Pleasant Touch in the Brain and Its Relationship with Taste and Olfactory Areas. NeuroReport 10:453–9CrossRef Google Scholar

, Nishijo H, , Ono T, & , Nishino H (1988a). Single Neuron Responses in Amygdala of Alert Monkey during Complex Sensory Stimulation with Affective Significance. Journal of Neuroscience 8:3570–83CrossRef Google Scholar

, Nishijo H, , Ono T, & , Nishino H (1988b). Topographic Distribution of Modality-specific Amygdalar Neurons in Alert Monkey. Journal of Neuroscience 8:3556–69CrossRef Google Scholar

Norgren R (1984). Central Neural Mechanisms of Taste. In: Handbook of Physiology – The Nervous System III, Sensory Processes 1, ed. I Darien-Smith, pp. 1087–128. Washington, DC: American Physiological Society

, O'Doherty J, , Rolls E T, , 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 11:893–7CrossRef Google Scholar

, O'Doherty J, , Rolls E T, , Francis S, , McGlone F, & , Bowtell R (2001). The Representation of Pleasant and Aversive Taste in the Human Brain. Journal of Neurophysiology 85:1315–21CrossRef Google Scholar

, Pritchard T C, , Hamilton R B, , Morse J R, & , Norgren R (1986). Projections of Thalamic Gustatory and Lingual Areas in the Monkey, Macaca fascicularis. Journal of Comparative Neurology 244:213–28CrossRef Google Scholar

, Pritchard T C, , Hamilton R B, & , Norgren R (1989). Neural Coding of Gustatory Information in the Thalamus of Macaca mulatta. Journal of Neurophysiology 61:1–14CrossRef Google Scholar

Rolls B J (1990). The Role of Sensory-specific Satiety in Food Intake and Food Selection. In: Taste, Experience, and Feeding, ed. E D Capaldi & T L Powley, pp. 197–209. Washington, DC: American Psychological Association

Rolls B J & Hetherington M (1989). The Role of Variety in Eating and Body Weight Regulation. In: Handbook of the Psychophysiology of Human Eating, ed. R Shepherd, pp. 57–84. Chichester: Wiley

, Rolls B J, , Rolls E T, , Rowe E A, & , Sweeney K (1981a). Sensory Specific Satiety in Man. Physiology and Behavior 27:137–42CrossRef Google Scholar

, Rolls B J, , Rowe E A, & , Rolls E T (1982). How Sensory Properties of Foods Affect Human Feeding Behavior. Physiology and Behavior 29:409–17CrossRef Google Scholar

, Rolls B J, , Rowe E A, , Rolls E T, , Kingston B, & , Megson A (1981b). Variety in a Meal Enhances Food Intake in Man. Physiology and Behavior 26:215–21CrossRef Google Scholar

, Rolls B J, , Duijenvoorde P M, & , Rolls E T (1984). Pleasantness Changes and Food Intake in a Varied Four Course Meal. Appetite 5:337–48CrossRef Google Scholar

, Rolls B J, , Duijenvoorde P M, & , Rowe E A (1983b). Variety in the Diet Enhances Intake in a Meal and Contributes to the Development of Obesity in the Rat. Physiology and Behavior 31:21–7CrossRef Google Scholar

Rolls E T (1975). The Brain and Reward. Oxford: Pergamon

Rolls E T (1993). The Neural Control of Feeding in Primates. In: Neurophysiology of Ingestion, ed. D A Booth, pp. 137–69. Oxford: PergamonCrossRef

Rolls E T (1994). Neural Processing Related to Feeding in Primates. In: Appetite: Neural and Behavioural Bases, ed. C R Legg & D A Booth, pp. 11–53. Oxford University PressCrossRef

, Rolls E T (1996). The Orbitofrontal Cortex. Philosophical Transactions of the Royal Society B 351:1433–44CrossRef Google Scholar

, Rolls E T (1997). Taste and Olfactory Processing in the Brain and Its Relation to the Control of Eating. Critical Reviews in Neurobiology 11:263–87CrossRef Google Scholar

Rolls E T (1999a). The Brain and Emotion. Oxford University Press

, Rolls E T (1999b). The Functions of the Orbitofrontal Cortex. Neurocase 5:301–12CrossRef Google Scholar

, Rolls E T (2000a). The Representation of Umami Taste in the Taste Cortex. Journal of Nutrition 130:S960–5CrossRef Google Scholar

, Rolls E T (2000b). The Orbitofrontal Cortex and Reward. Cerebral Cortex 10:284–94CrossRef Google Scholar

Rolls E T (2000c). Taste, Olfactory, Visual and Somatosensory Representations of the Sensory Properties of Foods in the Brain, and Their Relation to the Control of Food Intake. In: Neural and Metabolic Control of Macronutrient Intake, ed. H R Berthoud & R J Seeley, pp. 247–62. Boca Raton: CRC Press

Rolls E T (2000d). Neurophysiology and Functions of the Primate Amygdala, and the Neural Basis of Emotion. In: The A mygdala: A Functional Analysis, ed. J P Aggleton, pp. 447–78. Oxford University Press

, Rolls E T & , Baylis L L (1994). Gustatory, Olfactory and Visual Convergence within the Primate Orbitofrontal Cortex. Journal of Neuroscience 14:5437–52CrossRef Google Scholar

, Rolls E T, , Burton M J, & , Mora F (1976). Hypothalamic Neuronal Responses Associated with the Sight of Food. Brain Research 111:53–66CrossRef Google Scholar

, Rolls E T, , Critchley H D, , Browning A, & , Hernadi I (1998). The Neurophysiology of Taste and Olfaction in Primates, and Umami Flavor. Annals of the New York Academy of Sciences 855:426–37CrossRef Google Scholar

, Rolls E T, , Critchley H D, , Browning A S, , Hernadi A, & , Lenard L (1999). Responses to the Sensory Properties of fat of Neurons in the Primate Orbitofrontal Cortex. Journal of Neuroscience 19:1532–40CrossRef Google Scholar

, Rolls E T, , Critchley H, , Mason R, & , Wakeman E A (1996b). Orbitofrontal Cortex Neurons: Role in Olfactory and Visual Association Learning. Journal of Neurophysiology 75:1970–81CrossRef Google Scholar

, Rolls E T, , Critchley H, , Wakeman E A, & , Mason A (1996a). Responses of Neurons in the Primate Taste Cortex to the Glutamate Ion and to Inosine 5′-monophosphate. Physiology and Behavior 59:991–1000CrossRef Google Scholar

, Rolls E T, , Murzi E, , Yaxley S, , Thorpe S J, & , Simpson S J (1986). Sensory-specific Satiety: Food-specific Reduction in Responsiveness of Ventral Forebrain Neurons after Feeding in the Monkey. Brain Research 368:79–86CrossRef Google Scholar

Rolls E T & Rolls B J (1977). Activity of Neurons in Sensory, Hypothalamic and Motor Areas During Feeding in the Monkey. In: Food I ntake and Chemical Senses, ed. Y Katsuki, M Sato, S Takagi, & Y Oomura, pp. 525–49. University of Tokyo Press

Rolls E T & Rolls B J (1982). Brain Mechanisms Involved in Feeding. In: Psychobiology of Human Food Selection, ed. L M Barker, pp. 33–62. Westport, CT: AVI Publishing

, Rolls E T & , Rolls J H (1997). Olfactory Sensory-specific Satiety in Humans. Physiology and Behavior 61:461–73CrossRef Google Scholar

, Rolls E T, , Rolls B J, & , Rowe E A (1983c). Sensory-specific and Motivation-specific Satiety for the Sight and Taste of Food and Water in Man. Physiology and Behavior 30:185–92CrossRef Google Scholar

, Rolls E T, , Scott T R, , Sienkiewicz Z J, & , Yaxley S (1988). The Responsiveness of Neurones in the Frontal Opercular Gustatory Cortex of the Macaque Monkey is Independent of Hunger. Journal of Physiology 397:1–12CrossRef Google Scholar

, Rolls E T, , Sienkiewicz Z J, & , Yaxley S (1989). Hunger Modulates the Responses to Gustatory Stimuli of Single Neurons in the Orbitofrontal Cortex. European Journal of Neuroscience 1:53–60CrossRef Google Scholar

, Rolls E T, , Yaxley S, & , Sienkiewicz Z J (1990). Gustatory Responses of Single Neurons in the Orbitofrontal Cortex of the Macaque Monkey. Journal of Neurophysiology 64:1055–66CrossRef Google Scholar

, Sanghera M K, , Rolls E T, & , Roper-Hall A (1979). Visual Responses of Neurons in the Dorsolateral Amygdala of the Alert Monkey. Experimental Neurology 63:610–26CrossRef Google Scholar

, Scott T R, , Karadi Z, , Oomura Y, , Nishino H, , Plata-Salaman C R, , Lenard L, , Giza B K, & , Aou S (1993). Gustatory Neural Coding in the Amygdala of the Alert Macaque Monkey. Journal of Neurophysiology 69:1810–20CrossRef Google Scholar

, Scott T R, , Yan J, & , Rolls E T (1995). Brain Mechanisms of Satiety and Taste in Macaques. Neurobiology 3:281–92Google Scholar

, Scott T R, , Yaxley S, , Sienkiewicz Z J, & , Rolls E T (1986a). Taste Responses in the Nucleus Tractus Solitarius of the Behaving Monkey. Journal of Neurophysiology 55:182–200CrossRef Google Scholar

, Scott T R, , Yaxley S, , Sienkiewicz Z J, & , Rolls E T (1986b). Gustatory Responses in the Frontal Opercular Cortex of the Alert Cynomolgus Monkey. Journal of Neurophysiology 56:876–90CrossRef Google Scholar

, Tanabe T, , Iino M, & , Takagi S F (1975a). Discrimination of Odors in Olfactory Bulb, Pyriform-Amygdaloid Areas, and Orbitofrontal Cortex of the Monkey. Journal of Neurophysiology 38:1284–96CrossRef Google Scholar

, Tanabe T, , Yarita H, , Iino M, , Ooshima Y, & , Takagi S F (1975b). An Olfactory Projection Area in Orbitofrontal Cortex of the Monkey. Journal of Neurophysiology 38:1269–83CrossRef Google Scholar

, Thorpe S J, , Rolls E T, & , Maddison S (1983). Neuronal Activity in the Orbitofrontal Cortex of the Behaving Monkey. Experimental Brain Research 49:93–115Google Scholar

, Wilson F A W & , Rolls E T (1993). The Effects of Stimulus Novelty and Familiarity on Neuronal Activity in the Amygdala of Monkeys Performing Recognition Memory Tasks. Experimental Brain Research 93:367–82Google Scholar

Wilson F A W & Rolls E T (in press). The Primate Amygdala and Reinforcement: A Dissociation between Rule-based and Associatively-mediated Memory Revealed in Amygdala Neuronal Activity

, Yan J & , Scott T R (1996). The Effect of Satiety on Responses of Gustatory Neurons in the Amygdala of Alert Cynomolgus Macaques. Brain Research 740:193–200CrossRef Google Scholar

, Yaxley S, , Rolls E T, & , Sienkiewicz Z J (1988). The Responsiveness of Neurones in the Insular Gustatory Cortex of the Macaque Monkey Is Independent of Hunger. Physiology and Behavior 42:223–9CrossRef Google Scholar

, Yaxley S, , Rolls E T, & , Sienkiewicz Z J (1990). Gustatory Responses of Single Neurons in the Insula of the Macaque Monkey. Journal of Neurophysiology 63:689–700CrossRef Google Scholar

, Yaxley S, , Rolls E T, , Sienkiewicz Z J, & , Scott T R (1985). Satiety Does Not Affect Gustatory Activity in the Nucleus of the Solitary Tract of the Alert Monkey. Brain Research 347:85–93CrossRef Google Scholar

, Zatorre R J, , Jones-Gotman M, , Evans A C, & , Meyer E (1992). Functional Localization and Lateralisation of the Human Olfactory Cortex. Nature 360:339–40CrossRef Google Scholar

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23 - The Cortical Representation of Taste and Smell

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