Odorant differentiated pattern of cerebral activation: Comparison of acetone and vanillin

Whether different odorous compounds (odorants) are processed by different cerebral circuits is presently unknown. A first step to address this complicated issue is to investigate how the cerebral regions mediating signals from olfactory (i.e., unimodal) odorants, differ from those mediating the olfactory + trigeminal (i.e., bimodal) odorants. [15O]‐H2O‐PET scans were conducted in 12 healthy females during three separate conditions: birhinal, passive smelling of: 1) the unimodal odorant vanillin; 2) the bimodal odorant acetone; and 3) odorless air. Significant activations were calculated contrasting vanillin to air, acetone to air, and deactivations, running these contrasts in the opposite direction. Smelling of vanillin activated bilaterally the amygdala and piriform cortex. These regions were only engaged slightly by acetone. Instead, strong activations were found in the anterior and central insula and claustrum, the posterior portion of anterior cingulate, the somatosensory cortex (SI for face), cerebellum, ventral medial (VMPo) and dorsal medial (MDvc) thalamus, the lateral hypothalamus, and pons/medulla. In parallel, the somatosensory (SI, below central representation of face), secondary visual and auditory cortices, as well as the supplementary motor area and the parahippocampal gyri were deactivated. No deactivations were observed with vanillin, although the odor components of acetone and vanillin were rated similarly intense (75 ± 17 mm vs. 61 ± 22 mm, NS). The differentiated pattern of cerebral activation during odorant perception seems to be dependent on the signal transducing cranial nerves involved. In contrast to vanillin, which solely activates the olfactory cortex, acetone engages predominantly trigeminal projections from the nasal mucosa. Acetone's limited activation of the olfactory cortex may result from a cross‐modal interaction, with inhibition of acetone's odor component by its trigeminal component. Hum. Brain Mapping 17:17–27, 2002. © 2002 Wiley‐Liss, Inc.

[1]  J. Snow,et al.  Convergence of olfactory and nasotrigeminal inputs and possible trigeminal contributions to olfactory responses in the rat thalamus , 2004, European Archives of Oto-Rhino-Laryngology.

[2]  B. Gulyás,et al.  Smelling of Odorous Sex Hormone-like Compounds Causes Sex-Differentiated Hypothalamic Activations in Humans , 2001, Neuron.

[3]  B. Gulyás,et al.  Brain activation during odor perception in males and females , 2001, Neuroreport.

[4]  E. C. Ritchie,et al.  Gender Differences , 1981, Language in Society.

[5]  N. Costes,et al.  Emotional Responses to Pleasant and Unpleasant Olfactory, Visual, and Auditory Stimuli: a Positron Emission Tomography Study , 2000, The Journal of Neuroscience.

[6]  I Savic,et al.  PET shows that odors are processed both ipsilaterally and contralaterally to the stimulated nostril , 2000, Neuroreport.

[7]  R. Zatorre,et al.  Neural mechanisms involved in odor pleasantness and intensity judgments , 2000, Neuroreport.

[8]  B. Gulyás,et al.  Olfactory Functions Are Mediated by Parallel and Hierarchical Processing , 2000, Neuron.

[9]  T. Hummel,et al.  Assessment of intranasal trigeminal function. , 2000, International journal of psychophysiology : official journal of the International Organization of Psychophysiology.

[10]  I. Savic,et al.  Male pheromone activates anterior hypothalamus in female subjects , 2000, NeuroImage.

[11]  P E Roland,et al.  Somatosensory areas in man activated by moving stimuli: cytoarchitectonic mapping and PET , 2000, Neuroreport.

[12]  G H Glover,et al.  Time course of odorant-induced activation in the human primary olfactory cortex. , 2000, Journal of neurophysiology.

[13]  N. Costes,et al.  Haemodynamic brain responses to acute pain in humans: sensory and attentional networks. , 1999, Brain : a journal of neurology.

[14]  M. Bushnell,et al.  Dissociation of sensory and affective dimensions of pain using hypnotic modulation , 1999, Pain.

[15]  Anthony K. P. Jones,et al.  The cortical representation of pain , 1999, PAIN.

[16]  P. Morosan,et al.  Observer-Independent Method for Microstructural Parcellation of Cerebral Cortex: A Quantitative Approach to Cytoarchitectonics , 1999, NeuroImage.

[17]  P. Roland,et al.  Estimation of the Probabilities of 3D Clusters in Functional Brain Images , 1998, NeuroImage.

[18]  Satoshi Minoshima,et al.  Gender differences in pain perception and patterns of cerebral activation during noxious heat stimulation in humans , 1998, Pain.

[19]  J. D. E. Gabrieli,et al.  Sniffing and smelling: separate subsystems in the human olfactory cortex , 1998, Nature.

[20]  Alan C. Evans,et al.  Flavor processing: more than the sum of its parts , 1997, Neuroreport.

[21]  Edward T. Bullmore,et al.  FMRI during "unpleasant" odour stimulation: Normative data , 1997 .

[22]  C. Wysocki,et al.  Acetone odor and irritation thresholds obtained from acetone-exposed factory workers and from control (occupationally unexposed) subjects. , 1997, American Industrial Hygiene Association journal.

[23]  H. Stefan,et al.  Multiple olfactory activity in the human neocortex identified by magnetic source imaging. , 1997, Chemical senses.

[24]  M J Brammer,et al.  Functional MR imaging during odor stimulation: preliminary data. , 1997, Radiology.

[25]  J. Pardo,et al.  Emotion, olfaction, and the human amygdala: amygdala activation during aversive olfactory stimulation. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[26]  Alan C. Evans,et al.  Functional imaging of an illusion of pain , 1996, Nature.

[27]  R. Koeppe,et al.  Comparison of human cerebral activation pattern during cutaneous warmth, heat pain, and deep cold pain. , 1996, Journal of neurophysiology.

[28]  M. Corbetta,et al.  Top-down modulation of early sensory cortex , 1996, NeuroImage.

[29]  S. Petersen,et al.  PET activation of posterior temporal regions during auditory word presentation and verb generation. , 1996, Cerebral cortex.

[30]  R Kawashima,et al.  Positron-emission tomography studies of cross-modality inhibition in selective attentional tasks: closing the "mind's eye". , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[31]  S. Perlman,et al.  Anterograde tracing of trigeminal afferent pathways from the murine tooth pulp to cortex using herpes simplex virus type 1 , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[32]  M. Raichle,et al.  Blood flow changes in human somatosensory cortex during anticipated stimulation , 1995, Nature.

[33]  M. Bushnell,et al.  A thalamic nucleus specific for pain and temperature sensation , 1994, Nature.

[34]  Leslie G. Ungerleider,et al.  The functional organization of human extrastriate cortex: a PET-rCBF study of selective attention to faces and locations , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[35]  H. Mayberg Brain Activation , 1994, Neurology.

[36]  K. Zilles,et al.  Human brain atlas: For high‐resolution functional and anatomical mapping , 1994, Human brain mapping.

[37]  Alan C. Evans,et al.  Functional localization and lateralization of human olfactory cortex , 1992, Nature.

[38]  J. Mazziotta,et al.  Rapid Automated Algorithm for Aligning and Reslicing PET Images , 1992, Journal of computer assisted tomography.

[39]  F. Anton,et al.  Central projections of trigeminal primary afferents innervating the nasal mucosa: A horseradish peroxidase study in the rat , 1991, Neuroscience.

[40]  R. Doty Olfactory Capacities in Aging and Alzheimer's Disease a , 1991 .

[41]  R. Doty Olfactory capacities in aging and Alzheimer's disease. Psychophysical and anatomic considerations. , 1991, Annals of the New York Academy of Sciences.

[42]  Robert J. Zatorre,et al.  Olfactory identification deficits in patients with focal cerebral excision , 1988, Neuropsychologia.

[43]  G Kobal,et al.  Cerebral chemosensory evoked potentials elicited by chemical stimulation of the human olfactory and respiratory nasal mucosa. , 1988, Electroencephalography and clinical neurophysiology.

[44]  A. Holley,et al.  Does the Trigeminal Nerve Control the Activity of the Olfactory Receptor Cells? a , 1987 .

[45]  G Kobal,et al.  Cortical responses to painful CO2 stimulation of nasal mucosa; a magnetoencephalographic study in man. , 1986, Electroencephalography and clinical neurophysiology.

[46]  M. Mintun,et al.  A Noninvasive Approach to Quantitative Functional Brain Mapping with H215O and Positron Emission Tomography , 1984, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[47]  J. A. Daubenspeck Influence of small mechanical loads of variability of breathing pattern. , 1981, Journal of applied physiology: respiratory, environmental and exercise physiology.

[48]  T. Greitz,et al.  Head fixation device for reproducible position alignment in transmission CT and positron emission tomography. , 1981, Journal of computer assisted tomography.

[49]  William S. Cain,et al.  Interaction between chemoreceptive modalities of odour and irritation , 1980, Nature.

[50]  P. Jurs,et al.  Intranasal trigeminal stimulation from odorous volatiles: Psychometric responses from anosmic and normal humans , 1978, Physiology & Behavior.

[51]  D. Tucker Nonolfactory Responses from the Nasal Cavity: Jacobson’s Organ and the Trigeminal System , 1971 .

[52]  R. Sperry,et al.  Lateralization of olfactory perception in the surgically separated hemispheres of man , 1969 .

[53]  G Raisman,et al.  The central olfactory connexions. , 1965, Journal of anatomy.

[54]  P. Karlson,et al.  ‘Pheromones’: a New Term for a Class of Biologically Active Substances , 1959, Nature.

[55]  M. Kaliner,et al.  Nasal Reflexes , 1988 .