Human olfactory-auditory integration requires phase synchrony between sensory cortices

Zhou, Guangyu; Lane, Gregory; Noto, Torben; Arabkheradmand, Ghazaleh; Gottfried, Jay A.; Schuele, Stephan; Rosenow, Joshua M.; Olofsson, Jonas; Wilson, Donald A.; Zelano, Christina

doi:10.1038/s41467-019-09091-3

Cited by 54 publications

(48 citation statements)

References 71 publications

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“…In line with recent reports on phase synchrony required for olfactory-auditory integration (Zhou et al, 2019), each trial began with an audio-recorded label (2 s), followed by presentation of an odor A (6 s). Subsequently, participants heard a different label (2 s) before odor B (6 s), and then another label (2 s) before odor X (6 s).…”

Section: Methodsmentioning

confidence: 85%

Consistent verbal labels promote odor category learning

2021

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Section: Methodsmentioning

confidence: 85%

Consistent verbal labels promote odor category learning

2021

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“…We also did not observe a reset of the phase of beta oscillations by the sound in the olfactory structures. We cannot exclude that in our data, the way our stimuli are presented masks phase resetting, as it has recently been shown that phase synchrony occurs in an olfactory-auditory integration in human when the two modality did not arrive simultaneously 35 . However, using PCI analysis we detect sharper strips for the OS− condition compared to the S+ condition (Suppl.…”

Section: Discussionmentioning

confidence: 85%

Multisensory learning between odor and sound enhances beta oscillations

Gnaedinger

Gurden

Gourévitch

et al. 2019

Sci Rep

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Multisensory interactions are essential to make sense of the environment by transforming the mosaic of sensory inputs received by the organism into a unified perception. Brain rhythms allow coherent processing within areas or between distant brain regions and could thus be instrumental in functionally connecting remote brain areas in the context of multisensory interactions. Still, odor and sound processing relate to two sensory systems with specific anatomofunctional characteristics. How does the brain handle their association? Rats were challenged to discriminate between unisensory stimulation (odor or sound) and the multisensory combination of both. During learning, we observed a progressive establishment of high power beta oscillations (15–35 Hz) spanning on the olfactory bulb, the piriform cortex and the perirhinal cortex, but not the primary auditory cortex. In the piriform cortex, beta oscillations power was higher in the multisensory condition compared to the presentation of the odor alone. Furthermore, in the olfactory structures, the sound alone was able to elicit a beta oscillatory response. These findings emphasize the functional differences between olfactory and auditory cortices and reveal that beta oscillations contribute to the memory formation of the multisensory association.

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“…A human fMRI study by Gottfried et al(2003) showed that visual facilitation of olfactory detection enhanced activity in the OFC which is distinct from, but interconnected with, the POC [66]. Using phase synchrony, Zhou et al (2019) showed that primary olfactory cortical areas support multisensory integration within the olfactory system [67]. Additionally, simultaneous presentation of pure trigeminal and pure olfactory stimuli led to higher cortical activation in the OFC and insula (INS), although this study did not demonstrate the integration of olfactory and trigeminal stimuli in the POC [68].…”

Section: Discussionmentioning

confidence: 99%

Olfactory-Trigeminal Integration in the Primary Olfactory Cortex

Karunanayaka

Elyan

et al. 2020

Preprint

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Humans naturally integrate signals from the olfactory and intranasal trigeminal systems. A tight interplay has been demonstrated between these two systems, and yet the underlying neural circuitry that mediate olfactory-trigeminal integration remains unclear. Using functional magnetic resonance imaging (fMRI), this study investigated the neural mechanisms underlying olfactory-trigeminal integration. Fifteen subjects with normal olfactory function performed a localization task with weak or strong air-puff stimuli, phenylethyl alcohol (PEA; rose odor), or a combination. Although the ability to localize PEA to either nostril was at chance, its presence significantly improved the localization accuracy of weak, but not strong, air-puffs, relative to the localization of air-puffs without concomitant PEA, when both stimuli were delivered concurrently to the same nostril. This enhancement in localization accuracy was directly correlated with the magnitude of multisensory activity in the primary olfactory cortex (POC). Changes in orbitofrontal cortex (OFC) multisensory activity alone could not predict task performance, but changes in OFC and POC connectivity could. Similar activity and connectivity patterns were observed in the superior temporal cortex (STC), inferior parietal cortex (IPC) and the cerebellum.Taken together, these results suggest that olfactory-trigeminal integration is occurring across multiple brain regions. These findings can be interpreted as an indication that the POC is part of a distributed brain network that mediate the integration between olfactory and trigeminal systems.that multisensory effects in the OFC, STS and posterior parietal cortex (known higher-order multisensory brain regions) contribute to olfactory-trigeminal integration. Lastly, we tested the hypothesis that the effects of multisensory interaction in the POC is, in fact, driven by its connectivity with the OFC, STS and IPC.

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Human olfactory-auditory integration requires phase synchrony between sensory cortices

Cited by 54 publications

References 71 publications

Consistent verbal labels promote odor category learning

Consistent verbal labels promote odor category learning

Multisensory learning between odor and sound enhances beta oscillations

Olfactory-Trigeminal Integration in the Primary Olfactory Cortex

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