Modulation of Olfactory Perception by Visual Cortex Stimulation

Jadauji, Jahan B.; Djordjević, Jelena; Lundström, Johan N.; Pack, Christopher C.

doi:10.1523/jneurosci.6022-11.2012

Cited by 55 publications

(35 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, a decrease in grey matter volume of the fusiform gyrus, the middle temporal gyrus, and the middle occipital gyrus was demonstrated in previous voxel‐based morphometry studies in anosmics compared to healthy controls (Bitter et al, ; Peng et al, ), pointing to a possible role of these areas in olfactory processing. It has been suggested that during attempted identification of a smell, people might visualize the potential source of the odor (Jadauji et al, ). Thus, one might speculate whether patients scoring lower on the olfactory test in our study recruited the occipital network for visualization of the odor source less than patients achieving higher scores.…”

Section: Discussionmentioning

confidence: 99%

“…This is in line with previous evidence that patients with olfactory deficits show a reduced olfactory imagery capacity (Flohr et al, ; Kollndorfer et al, ). Furthermore, in a repetitive transcranial magnetic stimulation investigation, stimulation of the visual cortex led to improved odor discrimination performance as compared to sham stimulation, thus even pointing to a potential direct contribution of visual cortex to olfactory processing (Jadauji et al, ). The interconnection of the visual and olfactory system was also underlined by a recent study on olfactory‐visual conditioning (Hummel et al, ).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Severity of olfactory deficits is reflected in functional brain networks—An fMRI study

Reichert

Postma

Smeets

et al. 2018

Human Brain Mapping

View full text Add to dashboard Cite

Even though deficits in olfactory function affect a considerable part of the population, the neuronal basis of olfactory deficits remains scarcely investigated. To achieve a better understanding of how smell loss affects neural activation patterns and functional networks, we set out to investigate patients with olfactory dysfunction using functional magnetic resonance imaging (fMRI) and olfactory stimulation. We used patients' scores on a standardized olfactory test as continuous measure of olfactory function. 48 patients (mean olfactory threshold discrimination identification (TDI) score = 16.33, SD = 6.4, range 6 - 28.5) were investigated. Overall, patients showed piriform cortex activation during odor stimulation compared to pure sniffing. Group independent component analysis indicated that the recruitment of three networks during odor stimulation was correlated with olfactory function: a sensory processing network (including regions such as insula, thalamus and piriform cortex), a cerebellar network and an occipital network. Interestingly, recruitment of these networks during pure sniffing was related to olfactory function as well. Our results support previous findings that sniffing alone can activate olfactory regions. Extending this, we found that the severity of olfactory deficits is related to the extent to which neural networks are recruited both during olfactory stimulation and pure sniffing. This indicates that olfactory deficits are not only reflected in changes in specific olfactory areas but also in the recruitment of occipital and cerebellar networks. These findings pave the way for future investigations on whether characteristics of these networks might be of use for the prediction of disease prognosis or of treatment success.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Severity of olfactory deficits is reflected in functional brain networks—An fMRI study

Reichert

Postma

Smeets

et al. 2018

Human Brain Mapping

View full text Add to dashboard Cite

show abstract

“…Interestingly, Zellner and Whitten (1999) reported that while semantically congruent colors can enhance the intensity of a perceived odor (green for mint odor, red for strawberry odor), the effect was mainly due to the intensity of the color, while hue had little effect: The presence or absence of color in the concurrently presented solution seems to be an important factor (see also Zellner, Bartoli, & Eckard, 1991;Zellner & Kautz, 1990; but see , in addition to whether it was red or green. Going one step farther, recent imagery studies have suggested that vision contributes more generally to olfactory processing, as the mere stimulation of the visual cortex improves performance at the discrimination of different odor qualities (Jadauji, Djordjevic, Lundström, & Pack, 2012). In Seo, Arshamian, et al's (2010) study, the presentation of pairs of visual shapes and odors that had been rated as corresponding crossmodally in a previous task increased both the pleasantness (or unpleasantness) and intensity of the odors.…”

Section: Underevidenced Behavioral Effectsmentioning

confidence: 96%

Crossmodal correspondences between odors and contingent features: odors, musical notes, and geometrical shapes

2013

View full text Add to dashboard Cite

show abstract

“…However, it is also possible that the gustatory system directly influences olfactory processing at “earlier” processing levels. Given that recent work has revealed multisensory influences on primary sensory cortices (Ghazanfar et al, 2005; Lakatos et al, 2007; Iurilli et al, 2012)—including olfactory cortex (Gottfried and Dolan, 2003; Wesson and Wilson, 2010; Jadauji et al, 2012)—it is reasonable to ask whether the influence of taste on the olfactory system extends to primary cortical regions as well.…”

Section: Introductionmentioning

confidence: 99%

Chemosensory Convergence on Primary Olfactory Cortex

2012

View full text Add to dashboard Cite

Food perception and preference formation relies on the ability to combine information from both the taste and olfactory systems. Accordingly, psychophysical investigations in humans and behavioral work in animals has shown that the taste system plays an integral role in odor processing. However, the neural basis for the influence of taste (gustation) on odor (olfaction) remains largely unknown. Here we tested the hypothesis that gustatory influence on olfactory processing occurs at the level of primary olfactory cortex. We recorded activity from single neurons in posterior olfactory (piriform) cortex (pPC) of awake rats while presenting basic taste solutions directly to the tongue. A significant portion of pPC neurons proved to respond selectively to taste stimuli. These taste responses were significantly reduced by blockade of the gustatory epithelium, were unaffected by blockade of the olfactory epithelium and were independent of respiration behavior. In contrast, responses to olfactory stimuli, recorded from the same area, were reduced by nasal epithelial deciliation and phase-locked to the respiration cycle. These results identify pPC as a likely site for gustatory influences on olfactory processing, which play an important role in food perception and preference formation.

show abstract

Modulation of Olfactory Perception by Visual Cortex Stimulation

Cited by 55 publications

References 29 publications

Severity of olfactory deficits is reflected in functional brain networks—An fMRI study

Severity of olfactory deficits is reflected in functional brain networks—An fMRI study

Crossmodal correspondences between odors and contingent features: odors, musical notes, and geometrical shapes

Chemosensory Convergence on Primary Olfactory Cortex

Contact Info

Product

Resources

About