Functional Mapping of Human Brain in Olfactory Processing:  A PET Study

Qureshy, Ahmad; Kawashima, Ryuta; Imran, Muhammad Babar; Sugiura, Motoaki; Goto, Ryoi; Okada, Ken; Inoue, Kentaro; Itoh, Masatoshi; Schormann, Thorsten; Zilles, Karl; Fukuda, Hiroshi

doi:10.1152/jn.2000.84.3.1656

Cited by 130 publications

(77 citation statements)

References 72 publications

(51 reference statements)

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“…The authors suggested that the participants used a strategy involving mental imagery to achieve the task. In a PET study of the cognitive component of olfactory processing, left cuneus was activated when participants named the odors (Qureshy et al, 2000). The authors suggest that the task involved some imagery to ascertain the name of the odor and indicated that the visual cortex is involved in mental imagery tasks (see also Kosslyn, 1988;Royet et al, 1999).…”

Section: Activation Of Posterior Regionsmentioning

confidence: 99%

Brain activation when hearing one's own and others' names

Carmody

Lewis

2006

Brain Research

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Using functional magnetic resonance imaging, brain activation patterns were examined in response to hearing one's own first name in contrast to hearing the names of others. There are several regions in the left hemisphere that show greater activation to one's own name, including middle frontal cortex, middle and superior temporal cortex, and cuneus. These findings provide evidence that hearing one's own name has unique brain functioning activation specific to one's own name in relation to the names of others.

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Section: Activation Of Posterior Regionsmentioning

confidence: 99%

Brain activation when hearing one's own and others' names

Carmody

Lewis

2006

Brain Research

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“…Analogously, neuroimaging studies have reported activation of visual cortical areas during the performance of various purely olfactory tasks (Royet et al, 1999;Qureshy et al, 2000;Zatorre et al, 2000;Dade et al, 2002). One possible explanation for these visual-olfactory interactions is that subjects decide upon the identity of the stimulus, based entirely on processing within olfactory brain regions, after which they visualize the corresponding object.…”

Section: Introductionmentioning

confidence: 97%

Modulation of Olfactory Perception by Visual Cortex Stimulation

Jadauji

Djordjević²,

Lundström³

et al. 2012

J. Neurosci.

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When attempting to identify an object based on smell alone, people often visualize the perceived source of the odorant. This close association between olfactory and visual functions is supported by neuroimaging studies demonstrating activation of visual cortex during performance of purely olfactory tasks. Such activation might simply reflect the correlation between olfactory percepts and the corresponding visual images, or it might reflect a causal contribution of visual processing to olfactory perception. Here we provide evidence in support of the latter possibility. Using repetitive transcranial magnetic stimulation, we show that stimulating human visual cortex improves performance on a task requiring discrimination among different odor qualities. No significant improvement is found for tasks involving discrimination between intensities of the same odor, from stimulation of auditory cortex, or from "sham" stimulation. These results are thus consistent with a specific visual cortical influence on high-level olfactory perception. They also demonstrate that unimodal perceptual tasks are influenced by processing within cortical areas of other, seemingly unrelated, sensory systems.

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“…Although the cerebellum is not traditionally considered part of the olfactory system, cerebellar activity has been consistently observed in functional imaging studies of olfaction (Small et al, 1997;Yousem et al, 1997;Sobel et al, 1998;Qureshy et al, 2000;Savic et al, 2000;Zatorre et al, 2000;Cerf-Ducastel and Murphy, 2001;Ferdon and Murphy, 2003). Despite this, the pathways through which olfactory information reaches the cerebellum and the functional role of the cerebellum in olfaction remain unknown.…”

Section: Introductionmentioning

confidence: 99%

Olfactory Impairments in Patients with Unilateral Cerebellar Lesions Are Selective to Inputs from the Contralesional Nostril

Mainland¹,

Johnson²,

Khan³

et al. 2005

J. Neurosci.

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Functional imaging studies of olfaction have consistently reported odorant-induced activation of the cerebellum. However, the cerebellar role in olfaction remains unknown. We examined the olfactory and olfactomotor abilities of patients with unilateral cerebellar lesions, comparing performance within subjects across nostrils, as well as between subjects with age-matched and young controls. Regarding olfactory performance, initial testing revealed that patients had a contralesional impairment in olfactory identification but not olfactory detection threshold. However, when tested under conditions that prevented compensatory sniffing strategies, the patients also exhibited a contralesional olfactory detection impairment. Regarding olfactomotor function, a healthy olfactomotor system generates sniffs that are (1) sufficiently vigorous and (2) inversely proportional to odorant concentration in sniff mean airflow velocity, maximum airflow velocity, volume, and duration. Patients' sniffs were lower in overall airflow velocity and volume in comparison with control participants. Furthermore, reduced sniff velocity predicted poorer detection thresholds in patients. Finally, whereas young controls used concentration-dependent sniffs, there was a trend in that direction only for age-matched controls. Patients used sniffs that were concentration invariant. In conclusion, cerebellar lesions impacted olfactory and olfactomotor performance. These findings strongly implicate an olfactocerebellar pathway prominent in odor identification and detection that functionally connects each nostril primarily to the contralateral cerebellum.

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Functional Mapping of Human Brain in Olfactory Processing: A PET Study

Cited by 130 publications

References 72 publications

Brain activation when hearing one's own and others' names

Brain activation when hearing one's own and others' names

Modulation of Olfactory Perception by Visual Cortex Stimulation

Olfactory Impairments in Patients with Unilateral Cerebellar Lesions Are Selective to Inputs from the Contralesional Nostril

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