Ilias Tachtsidis’s research while affiliated with University College London and other places

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Publications (5)


PRISMA flow-chart depicting the literature screening process, including number of articles found via keyword searches and additional sources, number of articles excluded, and number of articles retained.
Distribution of research methodologies employed for research into olfaction, olfactive imagery and crossmodal interactions.
Distribution of publications related to olfaction, odour imagery and crossmodal visual-olfactory integration by year. For the purposes of this review, the search range was restricted to 2003–2023.
A schematic view of the human olfactory system. The primary and secondary olfactory regions are represented in blue and green, respectively. Amy, amygdala; Ento, entorhinal cortex; Hipp, hippocampus; OFC, orbitofrontal cortex; PC, piriform cortex; Thal, thalamus. Retrieved from Saive et al. (2014).
A schematic view of the human olfactory system. The primary, secondary and tertiary olfactory regions are represented in blue, purple and green respectively.

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fNIRS a novel neuroimaging tool to investigate olfaction, olfactory imagery, and crossmodal interactions: a systematic review
  • Literature Review
  • Full-text available

January 2024

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578 Reads

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3 Citations

Eleanor Boot

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Andrew Levy

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[...]

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Ilias Tachtsidis

Olfaction is understudied in neuroimaging research compared to other senses, but there is growing evidence of its therapeutic benefits on mood and well-being. Olfactory imagery can provide similar health benefits as olfactory interventions. Harnessing crossmodal visual-olfactory interactions can facilitate olfactory imagery. Understanding and employing these cross-modal interactions between visual and olfactory stimuli could aid in the research and applications of olfaction and olfactory imagery interventions for health and wellbeing. This review examines current knowledge, debates, and research on olfaction, olfactive imagery, and crossmodal visual-olfactory integration. A total of 56 papers, identified using the PRISMA method, were evaluated to identify key brain regions, research themes and methods used to determine the suitability of fNIRS as a tool for studying these topics. The review identified fNIRS-compatible protocols and brain regions within the fNIRS recording depth of approximately 1.5 cm associated with olfactory imagery and crossmodal visual-olfactory integration. Commonly cited regions include the orbitofrontal cortex, inferior frontal gyrus and dorsolateral prefrontal cortex. The findings of this review indicate that fNIRS would be a suitable tool for research into these processes. Additionally, fNIRS suitability for use in naturalistic settings may lead to the development of new research approaches with greater ecological validity compared to existing neuroimaging techniques.

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fNIRS neuroimaging in olfactory research: A systematic literature review

December 2022

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154 Reads

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6 Citations

There are a number of key features which make olfaction difficult to study; subjective processes of odor detection, discrimination and identification, and individualistic odor hedonic perception and associated odor memories. In this systematic review we explore the role functional near-infrared spectroscopy (fNIRS) has played in understanding olfactory perception in humans. fNIRS is an optical neuroimaging technique able to measure changes in brain hemodynamics and oxygenation related to neural electrical activity. Adhering to PRISMA guidelines, results of this search found that generally the majority of studies involving healthy adult subjects observed increased activity in response to odors. Other population types were also observed, such as infants, individuals with autism, attention deficit hyperactivity disorder (ADHD), post-traumatic stress disorder (PTSD), mild cognitive impairment (MCI) and dysosmia. fNIRS coverage heavily favored the prefrontal cortex, temporal and parietal regions. This review finds that odor induced cortical activation is dependent on multiple factors, such as odorant type, gender and population type. This review also finds that there is room for improvement in areas such as participant diversity, use of wearable fNIRS systems, physiological monitoring and multi-distance channels.


FIGURE 1 | (A) Channel-specific locations of the 22-channel (eight sources & eight detectors) configuration overlaid onto a model brain mesh of the PFC. (B) Neurocognitive testing before and after exercise. (C) A 15-min bleep test of aerobic fitness to measure VO 2max . (D) Example of trials of the SOT (upper row) and SIT (lower row) tasks.
FIGURE 2 | HbR changes in the PFC as an acute effect of exercise (n = 92) collapsed across all executive function conditions. Greatest activation changes are represented in bright yellow and white, with little to no effects represented in dark red and black, respectively (t-values of the images are scaled from 0 to 5+).
FIGURE 3 | Higher depression scores on the MFQ (y-axis) predicted smaller changes in levels of activation in right IFG (BA44/45/47) as an effect of exercise (r = 0.36, p < 0.001, 95% CI [−0.07, −0.02]; 13% variance explained). The red line depicts the regression line, with black lines as confidence intervals.
FIGURE 4 | Higher levels of aerobic fitness (y-axis) predicted greater changes in the level of activation in right rostral PFC (BA10) as an effect of exercise (r = 0.30, p = 0.004, 95% CI [0.79, 3.97]; 9% variance explained). The red line depicts the regression line, with black lines as confidence intervals.
Channels, coordinates, and anatomical regions.
Decreased Exercise-Induced Changes in Prefrontal Cortex Hemodynamics Are Associated With Depressive Symptoms

May 2022

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161 Reads

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4 Citations

Frontiers in Neuroergonomics

People with a depressed mood tend to perform poorly on executive function tasks, which require much of the prefrontal cortex (PFC), an area of the brain which has also been shown to be hypo-active in this population. Recent research has suggested that these aspects of cognition might be improved through physical activity and cognitive training. However, whether the acute effects of exercise on PFC activation during executive function tasks vary with depressive symptoms remains unclear. To investigate these effects, 106 participants were given a cardiopulmonary exercise test (CPET) and were administered a set of executive function tests directly before and after the CPET assessment. The composite effects of exercise on the PFC (all experimental blocks) showed bilateral activation changes in dorsolateral (BA46/9) and ventrolateral (BA44/45) PFC, with the greatest changes occurring in rostral PFC (BA10). The effects observed in right ventrolateral PFC varied depending on level of depressive symptoms (13% variance explained); the changes in activation were less for higher levels. There was also a positive relationship between CPET scores (VO2peak) and right rostral PFC, in that greater activation changes in right BA10 were predictive of higher levels of aerobic fitness (9% variance explained). Since acute exercise ipsilaterally affected this PFC subregion and the inferior frontal gyrus during executive function tasks, this suggests physical activity might benefit the executive functions these subregions support. And because physical fitness and depressive symptoms explained some degree of cerebral upregulation to these subregions, physical activity might more specifically facilitate the engagement of executive functions that are typically associated with hypoactivation in depressed populations. Future research might investigate this possibility in clinical populations, particularly the neural effects of physical activity used in combination with mental health interventions.


Facial and neural mechanisms during interactive disclosure of biographical information

February 2021

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228 Reads

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19 Citations

NeuroImage

Pairs of participants mutually communicated (or not) biographical information to each other. By combining simultaneous eye-tracking, face-tracking and functional near-infrared spectroscopy, we examined how this mutual sharing of information modulates social signalling and brain activity. When biographical information was disclosed, participants directed more eye gaze to the face of the partner and presented more facial displays. We also found that spontaneous production and observation of facial displays was associated with activity in the left SMG and right dlPFC/IFG, respectively. Moreover, mutual information-sharing increased activity in bilateral TPJ and left dlPFC, as well as cross-brain synchrony between right TPJ and left dlPFC. This suggests that a complex long-range mechanism is recruited during information-sharing. These multimodal findings support the second-person neuroscience hypothesis, which postulates that communicative interactions activate additional neurocognitive mechanisms to those engaged in non-interactive situations. They further advance our understanding of which neurocognitive mechanisms underlie communicative interactions.


Figure and Table legends:
The role of anterior prefrontal cortex (area 10) in face-to-face deception measured with fNIRS

June 2020

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180 Reads

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26 Citations

Social Cognitive and Affective Neuroscience

Anterior prefrontal cortex (PFC; Brodmann area 10) activations are often, but not always, found in neuroimaging studies investigating deception, and the precise role of this area remains unclear. To explore the role of PFC in face-to-face deception, we invited pairs of participants to play a card game involving lying and lie detection while we used functional near infrared spectroscopy (fNIRS) to record brain activity in PFC. Participants could win points for successfully lying about the value of their cards or for detecting lies. We contrasted patterns of brain activation when the participants either told the truth or lied, when they were either forced into this or did so voluntarily, and when they either succeeded or failed to detect a lie. Activation in anterior PFC was found in both lie production and detection, unrelated to reward. Analysis of cross-brain activation patterns between participants identified areas of PFC where the lead player's brain activity was synchronized their partner's later brain activity. These results suggest that during situations that involve close interpersonal interaction, anterior PFC supports processing widely involved in deception, possibly relating to the demands of monitoring one's own, and other people's behaviour.

Citations (5)


... Turning now to the case of olfaction, Wiesmann et al. (2001, p. 237) note that: "Olfactory information is projected from the olfactory bulb to the primary olfactory cortex, which is composed of the anterior olfactory nucleus, the olfactory tubercle, the piriform cortex, the amygdala, the periamygdaloid region, and the entorhinal cortex. From there, the primary olfactory cortex projects to secondary olfactory regions including the hippocampus, ventral striatum and pallidum, hypothalamus, thalamus, orbitofrontal cortex, agranular insular cortex, and cingulate gyrus" (see also Boot et al., 2024). ...

Reference:

What is the Relation between Chemosensory Perception and Chemosensory Mental Imagery?
fNIRS a novel neuroimaging tool to investigate olfaction, olfactory imagery, and crossmodal interactions: a systematic review

... Despite its flexibility and ability to operate in extremely different research contexts, to date, fNIRS has not been widely exploited in the fragrance industry, or more generally, in olfactory research [28]. Moreover, the only significant contributions in the field have been made either in clinical settings [29,30], or in lab-based settings [31]. ...

fNIRS neuroimaging in olfactory research: A systematic literature review

... Secondly, the neurophysiological effects of physical exercise also contribute to its moderating influence. Extensive research indicates that chronic physical exercise is a promising strategy for enhancing critical executive functions such as inhibitory control and working memory (71), by augmenting the structure and function of the brain (72), particularly the prefrontal cortex, which plays a pivotal role in emotion regulation (73). Furthermore, acute exercise triggers activation in the medial prefrontal cortex and medial temporal lobe, associated with episodic memory function, a crucial cognitive ability for maintaining overall wellbeing (74,75). ...

Decreased Exercise-Induced Changes in Prefrontal Cortex Hemodynamics Are Associated With Depressive Symptoms

Frontiers in Neuroergonomics

... Although we expected explain-to-others and explain-to-oneself to cause more brain activity reflective of cognitive processing than the control group, we were particularly interested in the degree to which explain-toothers caused additional brain activity reflecting additional social processing. For example, Schilbach et al. (2013) and Cañigueral et al. (2021) propose that social processing is embodied in brain networks, such that mutual engagement may stimulate additional brain dynamics compared to completing a task alone. Many studies have emphasized that human interaction with others is a major factor in how we learn (Marchiori & Warglien, 2008;Pan et al., 2018Pan et al., , 2020Pan et al., , 2023. ...

Facial and neural mechanisms during interactive disclosure of biographical information

NeuroImage

... Alternative approaches, then, may allow for more stringent interpretations of data, exploring the dependencies within different data streams. In the cross-brain GLM (xGLM; Hamilton, 2021) approach, as an example, a general linear model incorporating behavioral data and cross-brain data is used to model individual's brain activity in relation to both their own behavior and interagents' behavior and brain activity (see Kingsbury et al., 2019;Pinti et al., 2021). ...

The role of anterior prefrontal cortex (area 10) in face-to-face deception measured with fNIRS

Social Cognitive and Affective Neuroscience