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Imaging methodologies and applications for nutrition research: what can functional MRI offer?

Published online by Cambridge University Press:  24 October 2014

Susan T. Francis  and
Sally Eldeghaidy
Susan T. Francis*
Affiliation:
Sir Peter Mansfield Magnetic Resonance Centre, School of Physics and Astronomy, University of Nottingham, UK
Sally Eldeghaidy
Affiliation:
Sir Peter Mansfield Magnetic Resonance Centre, School of Physics and Astronomy, University of Nottingham, UK Department of Physics, Faculty of Science, Suez Canal University, Ismailia, Egypt
*
*Corresponding author: Dr S. Francis, email susan.francis@nottingham.ac.uk
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Abstract

Food intake is influenced by a complex regulatory system involving the integration of a wide variety of sensory inputs across multiple brain areas. Over the past decade, advances in neuroimaging using functional MRI (fMRI) have provided valuable insight into these pathways in the human brain. This review provides an outline of the methodology of fMRI, introducing the widely used blood oxygenation level-dependent contrast for fMRI and direct measures of cerebral blood flow using arterial spin labelling. A review of fMRI studies of the brain's response to taste, aroma and oral somatosensation, and how fat is sensed and mapped in the brain in relation to the pleasantness of food, and appetite control is given. The influence of phenotype on individual variability in cortical responses is addressed, and an overview of fMRI studies investigating hormonal influences (e.g. peptide YY, cholecystokinin and ghrelin) on appetite-related brain processes provided. Finally, recent developments in MR technology at ultra-high field (7 T) are introduced, highlighting the advances this can provide for fMRI studies to investigate the neural underpinnings in nutrition research. In conclusion, neuroimaging methods provide valuable insight into the mechanisms of flavour perception and appetite behaviour.

Keywords

BOLDNeuroimagingSatietyObesityRewardAppetiteFoodHypothalamusHomeostatic
Type
Conference on ‘Changing dietary behaviour: physiology through to practice’
Information
Proceedings of the Nutrition Society , Volume 74 , Issue 2 , May 2015 , pp. 89 - 98
Copyright
Copyright © The Authors 2014 

Over the past decade, advances in neuroimaging techniques, particularly functional MRI (fMRI), have provided valuable insight into central food-related pathways in the human brain. This review outlines recent advances in fMRI to understand flavour perception and human appetitive behaviour. A brief overview of the method of fMRI and the blood oxygenation level-dependent (BOLD) contrast generally used in fMRI is provided, together with how more direct measures of cerebral blood flow (CBF) can be assessed. fMRI studies of the brain's response to taste, aroma and flavour perception are outlined. The question of how fat is sensed and mapped in the brain in relation to the pleasantness of food, appetite control and hormonal influences is addressed. The role of neuroimaging studies to assess eating behaviour in obesity will be outlined. Finally, recent developments in MR technology, and the advances they can provide for future fMRI studies to investigate the neural underpinnings in nutrition research will be described.

Principles of functional MRI

fMRI has revolutionised the research of functional brain mapping and is now the most widely used method for mapping brain activity. fMRI measures brain activity indirectly through the haemodynamic changes associated with neural activation, and typically uses the BOLD contrast. BOLD contrast was introduced in the early 1990s( Reference Ogawa, Lee and Kay 1 ), and relies on the different magnetic properties of oxygenated and deoxygenated blood, which are diamagnetic and paramagnetic, respectively( Reference Okada 2 ). Paramagnetic deoxyhaemoglobin leads to a local magnetic field distortion within and around vessels, causing the protons to dephase, reducing the T 2/T 2* relaxation time and the MR signal compared with oxyhaemoglobin.

On brain activity, neural demand increases leading to an increase in glucose and oxygen consumption with an increase in both CBF and cerebral blood volume to deliver these nutrients. However, the increase in CBF, and hence the supply of oxygenated blood, increases to a level greater than that required by demand (over compensation). This leads to a local increase in blood oxygenation in active brain regions, resulting in a local increase in T 2/T 2* relaxation time and thus a small, but detectable, increase in MR image intensity termed the BOLD response( Reference Thulborn, Waterton and Matthews 3 ), Fig. 1. This effect can be observed using T 2* or T 2 weighted imaging sequences using gradient-echo or spin-echo schemes, respectively. Although gradient-echo echo planar imaging is most typically used, the change in BOLD MR signal intensity has a characteristic response, termed the haemodynamic response function, with the increase in MR signal typically delayed by 6 s following stimulus onset and having a 1–5 % signal change at a magnetic field strength of 3 T.

Fig. 1. Schematic representation of (a) the haemodynamic changes which lead to a blood oxygenation level-dependent (BOLD) signal, and (b) the BOLD haemodynamic response function.

Since BOLD-fMRI is a non-invasive technique, it can be repeatedly used. The spatial resolution is typically 3 ml isotropic, but higher spatial resolution can be achieved at increasing magnetic field strength, such as at an ultra-high field (UHF) of 7 T. The main limitation of the BOLD technique arises from the vascular origin of the signal, which inherently limits its temporal resolution and quantitation( Reference Buxton, Uludag and Dubowitz 4 , Reference Hoge, Atkinson and Gill 5 ). In addition to developing stronger magnetic fields to enhance the spatial resolution of the BOLD response and brain mapping, measuring the direct change in CBF due to neuronal activation using arterial spin labelling provides absolute quantification of the signal change and hence neuronal activity.

In arterial spin labelling, arterial blood water is magnetically labelled before it reaches the tissue of interest by applying a single radiofrequency pulse( Reference Edelman, Siewert and Darby 6 , Reference Kim 7 ) or train of pulses( Reference Wu, Fernandez-Seara and Detre 8 ). After a period of time (post-label delay), the labelled blood ‘endogenous tracer’ flows into the slice of interest, where it exchanges with tissue water. During this time, an image is taken (called the tag or label image). In this image, the blood water is in a different magnetisation state from that of the static tissue water. In addition to the label image, a control image is acquired without labelling of inflowing arterial blood. Label and control images are then subtracted to yield a perfusion weighted image that can be quantified in terms of cerebral blood flow in ml/100 g per min( Reference Buxton, Wong and Frank 9 ). Although directly measuring CBF using arterial spin labelling yields a better spatial correlation with the actual site of the active brain region than BOLD, its temporal resolution is lower than BOLD due to the time required to collect both a label and control pair. In addition, the signal-to-noise ratio and contrast-to-noise ratio are inherently lower than BOLD( Reference Silva, Lee and Yang 10 , Reference Duong, Kim and Ugurbil 11 ); however increasing the field strength increases both of these measures due to longer longitudinal relaxation time (T 1) at higher magnetic field strength.

Functional MRI paradigm designs to study nutrition

In fMRI, various designs and approaches are used for studying the mechanism underlying food intake and appetite. One of the most direct methods is the presentation of taste, aroma or flavour stimuli or food images in a block design, where stimuli are presented for a period of time followed by a rest period. In an fMRI study, a set of BOLD images covering the whole brain (a brain volume) is typically collected each 2–3 s during the presentation of stimuli, and to increase the sensitivity to detect active brain areas, hundreds of brain volumes are acquired during many repeats of a stimulus. This leads to an fMRI paradigm typically taking 10–20 min. Signal averaging and statistical processing are required due to the difficulty in detecting the low BOLD signal changes against background physiological noise signal fluctuations( Reference Purdon and Weisskoff 12 ). However, BOLD sensitivity increases supra-linearly with magnetic strength, one reason for the current demand for UHF MR scanners.

Alternatively, the brains’ response to food or food cues can be measured under different physiological conditions, such as the fasted state v. fed state, or the presence of exogenously administered or endogenously produced gut hormones. Another approach is to study the resting state signal fluctuations in the brain, where individuals do not perform any tasks during scanning (this is termed resting state fMRI). Subjects are scanned under different physiological conditions and the connectivity between different brain regions is studied. CBF-fMRI studies provide an alternative assessment of the effect of physiological state by measuring the absolute cerebral blood flow at different time points, which can then be compared with a baseline measure of CBF.

Functional MRI responses to taste, aroma and oral somatosensation

The sensory properties of food and their hedonic effects are important drivers of food intake. The use of fMRI in recent years has improved the understanding of the cortical representation of sensory properties of food in human subjects. Although taste stimulation has consistently activated the same brain regions across multiple fMRI studies, including insula and overlaying operculum, the transduction mechanisms remain incompletely characterised. Previous studies reported the primary taste cortex is located within the anterior insula/frontal operculum( Reference Small, Zald and Jones-Gotman 13 Reference Veldhuizen, Albrecht and Zelano 15 ) with secondary projections to the orbitofrontal cortex (OFC)( Reference Francis, Rolls and Bowtell 16 ), amygdala( Reference O'Doherty, Rolls and Francis 17 ), anterior cingulate cortex (ACC)( Reference Small, Gregory and Mak 18 ), ventral striatum( Reference O'Doherty, Dayan and Friston 19 ) and dorsolateral prefrontal cortex( Reference Kringelbach, de Araujo and Rolls 20 ). O'Doherty et al. were the first to investigate the cortical response to pleasant (glucose) and aversive (salt) taste stimuli by assessing stimuli against a tasteless control stimulus( Reference O'Doherty, Rolls and Francis 21 ). In individual subject analysis, the OFC showed separate areas to be activated in response to these two tastes. Small et al. also highlighted activations in the OFC to sweet and aversive taste, and investigated the neural response to taste intensity when valence was held constant, showing activation of the amygdala and mid-insula( Reference Small, Gregory and Mak 18 ). Furthermore, the amygdala responded to both sweet and aversive taste (when intensity was held constant), with preferential activation to sweet taste, providing evidence that the amygdala is not solely involved in processing aversive taste. Other activations including ACC have been reported in many fMRI studies( Reference Francis, Rolls and Bowtell 16 , Reference Small, Gregory and Mak 18 , Reference O'Doherty, Rolls and Francis 21 , Reference de Araujo, Kringelbach and Rolls 22 ), while the rolandic operculum of the parietal cortex has been identified as a part of the primary gustatory cortex( Reference Ogawa, Wakita and Hasegawa 23 , Reference Faurion, Cerf and Van De Moortele 24 ). A recent meta-analysis confirmed widespread activation of the insula and operculum in response to taste stimuli, diverging from posterior to the most anterior junction of insula and operculum, in addition to activation in medial OFC, pregenual ACC and mediodorsal thalamus( Reference Veldhuizen, Albrecht and Zelano 15 ).

In response to aroma stimuli, fMRI studies report robust activation in higher-order olfactory areas, including the OFC, insula and ACC( Reference Francis, Rolls and Bowtell 16 , Reference O'Doherty, Rolls and Francis 25 , Reference Savic, Gulyas and Larsson 26 ). In contrast, the primary olfactory cortex has shown no( Reference Yousem, Williams and Howard 27 , Reference Fulbright, Skudlarski and Lacadie 28 ) or inconsistent activations in some studies( Reference O'Doherty, Rolls and Francis 25 , Reference Weismann, Yousry and Heuberger 29 ). This may be due to its small structure, susceptibility artefacts in this region or habituation effects( Reference Poellinger, Thomas and Lio 30 ).

Oral somatosensation plays a crucial role in many aspects of flavour perception. fMRI studies have revealed brain regions involved in tactile components such as astringency( Reference Cerf-Ducastel, Van de Moortele and MacLeod 31 ), burn( Reference Rudenga, Green and Nachtigal 32 ) and temperature( Reference Guest, Grabenhorst and Essick 33 ). Textural properties of food are known to correlate with fat content, and fat may also act as a chemical stimulus, with NEFA stimulating taste receptor cells for the detection of fat( Reference Gilbertson 34 , Reference Mattes 35 ). Very few studies have investigated the cortical representation to oral viscosity and oral fat in the mouth. de Araujo and Rolls( Reference de Araujo and Rolls 36 ) and De Celis Alonso et al. ( Reference De Celis Alonso, Marciani and Head 37 ) investigated the representation of oral viscosity (carboxymethyl cellulose) and manugel alginate gel, respectively. Both studies showed activation in the mid- and anterior insula, with the mid-insula representing the somatosensory properties of the oral activity (texture), other areas, including post-central gyrus and rolandic/parietal operculum were also reported( Reference De Celis Alonso, Marciani and Head 37 ). In addition, the sensory and hedonic aspects of oral fat have been investigated in a number of studies using BOLD and CBF measures. Human responses to oral fat have been found to activate taste, texture and reward areas( Reference de Araujo and Rolls 36 , Reference Eldeghaidy, Marciani and McGlone 38 Reference Frank, Linder and Kullmann 40 ). Responses to oral fat in the form of pure fat have been found in the ACC extending to the OFC and hypothalamus, with the rostral ACC and medial OFC being activated independent of viscosity, leading to the suggestion that it is these areas that process the hedonic properties of fat( Reference de Araujo and Rolls 36 ). Moreover, the subjective rating of texture and flavour pleasantness of oral fat was found to correlate with activity in the mid-OFC and ACC, areas thought to represent flavour pleasantness( Reference Grabenhorst, Rolls and Parris 39 ). This study also suggested that the pregenual cingulate cortex is activated by converging flavour and fat signals, hence representing overall pleasantness. Further investigations on the effect of fat content on the cortical response show a positive correlation with increasing fat level/concentration in taste, texture and reward areas( Reference Eldeghaidy, Marciani and McGlone 38 Reference Frank, Linder and Kullmann 40 ). Most recently, the somatosensory cortex has been shown to be involved in the processing of oral flavoured fat through functional coupling with the OFC, for a high-fat pleasant sample compared with a low-fat food with the same flavour. It has been suggested that this may reflect the role of somatosensory cortex in the processing of pleasant-flavoured oral fat( Reference Grabenhorst and Rolls 41 ). Understanding the cortical encoding of the perceived response to fat is important in relation to the pleasantness of food and appetite control, and it provides additional and valuable information to the food industry in order to improve the design of products that are lower in fat but still rewarding to eat, and hence decrease the risk of obesity and associated complications.

Flavour perception of foods or beverages is a complex multimodal process, engaging taste, olfaction and texture modalities, and does not result from the simple addition of these stimuli( Reference Small, Jones-Gotman and Zatorre 14 ). Despite taste, aroma and oral somatosenation systems being anatomically dissociated at the peripheral level, they are highly integrated at the cortical level, and the exact mechanisms that lead to flavour perception are still not well understood. Small( Reference Small 42 ) has suggested a model for flavour perception, which postulates that the oral somatomotor areas play the principal role in binding the taste, olfactory and associated tactile sensations into the unitary flavour percept. fMRI provides a great tool to understand the cortical association and integration between the different modalities. Evidence from recent fMRI studies show overlapping brain responses to taste and aroma in areas including anterior insula, ACC, OFC and amygdala( Reference Small, Voss and Mak 43 Reference McCabe and Rolls 47 ). Verhagen and Engelen performed a meta-analysis, which suggested the anterior insula to be a multi-modal area activated by both taste and aroma stimuli( Reference Verhagen and Engelen 48 ). However, the mechanism of interaction is poorly understood. In addition, the cortical representation to oral somatosensation and taste was shown to overlap in the insula and operculum( Reference Cerf-Ducastel, Van de Moortele and MacLeod 31 Reference Guest, Grabenhorst and Essick 33 ). Although fMRI provides a powerful method in revealing the cortical response to flavour perception, much is still to be discovered in flavour perception.

Phenotype and its modulation of functional MRI responses

The perception of taste is known to vary widely across individuals. There are many factors that contribute to an individual's taste perception and subsequent food preferences and energy intake, including the density of taste papillae on the tongue and genetic differences in taste receptors( Reference Bartoshuk, Duffy and Miller 49 ). The most well-researched taste phenotyping is the perception of the bitterness taste. In behavioural studies, this can be assessed by measuring a subjects’ sensitivity to a bitter chemical called 6-n-propylthiouracil (PROP). Subjects are asked to taste a filter paper soaked in super saturated PROP solution and rate for bitterness intensity on a Generalised Labelled Magnitude Scale( Reference Bartoshuk, Duffy and Fast 50 ). Non-tasters cannot taste the bitterness of PROP (about 25 % of the population), medium tasters (about 50 %) sense the bitterness while accepting it and super-tasters (about 25 %) find the taste of PROP unacceptable. Tasters (medium- and super-tasters) are more sensitive than non-tasters to the bitterness of caffeine, and to the sweetness of sucrose( Reference Chang, Chung and Kim 51 ), some artificial sweeteners( Reference Bartoshuk, Duffy and Miller 49 ) and salt taste( Reference Miller and Reedy 52 ). Moreover, some studies have also shown that PROP tasters are also more sensitive to fat( Reference Duffy, Bartoshuk and Lucchina 53 ), oral irritation( Reference Duffy, Peterson and Bartoshuk 54 ) and oral temperature( Reference Manrique and Zald 55 ). Variability in PROP taster status is, in part, explained by the TAS2R receptor gene family( Reference Duffy, Davidson and Kidd 56 ). Previous research showed that the density of fungiform papillae is significantly higher in PROP super-tasters( Reference Duffy, Davidson and Kidd 56 , Reference Duffy and Bartoshuk 57 ) suggesting that this could be the source of increased sensitivity to taste stimuli and oral sensitivity. Essick et al. showed a strong correlation between PROP tasters and oral somatosensation( Reference Essick, Chopra and Guest 58 ), with supertasters having improved lingual tactile spatial acuity (to embossed letters) compared with medium tasters or non-tasters.

Recently, a new taste phenotype known as thermal taster status has been described( Reference Cruz and Green 59 ). Thermal stimulation of small areas of the tongue was found to elicit a ‘phantom’ taste in some individuals. Thermal sourness and/or saltiness can be perceived by cooling the tongue, whereas re-warming the tongue from an initial cooling period can evoke a sweetness taste. In addition, thermal tasters were found to be more sensitive than thermal non-tasters to taste and olfactory stimuli( Reference Green and George 60 ), and oral stimulation including temperature( Reference Bajec and Pickering 61 ). The mechanism underlying this is still under investigation, and appears to not be associated with fungiform papillae density, as no correlation has been found previously. Fungiform papillae are surrounded and sometimes innervated by the trigeminal nerve, which carries information from the tongue related to chemical and physical properties of foods, and this may lead to a correlation between PROP tasters and thermal tasters. Recent studies also show there is a relationship between the trigeminal system and PROP taster status( Reference Bajec and Pickering 61 ).

Very few studies have investigated the impact of taste phenotype on the primary gustatory cortex and oral somatosensory areas. Eldeghaidy et al. showed that the cortical response to oral fat in PROP tasters was highly correlated in key taste, texture, and reward processing areas, with a significant increase in BOLD response with PROP taster status (super-taster>taster>non-taster)( Reference Eldeghaidy, Marciani and McGlone 38 ), Fig. 2. More recently, Clark et al., showed that the cortical response to taste and carbonation in thermal tasters was significantly higher in several cortical areas involved in flavour processing compared with thermal non-tasters( Reference Clark, Francis and Bealin-Kelly 62 ). Furthermore, the variation in genotype, such as the α-synuclein gene and TaqIA A1, has also been shown to be associated with the BOLD response to taste stimuli in the OFC and striatum( Reference Stice, Spoor and Bohon 63 , Reference Felsted, Ren and Chouinard-Decorte 64 ) and regions known to be rich in dopaminergic axon terminals, including ACC, amygdala, thalamus and putamen( Reference Wilcox, Claus and Blaine 65 ). These results highlight new information about the cortical features of different phenotypes, and emphasise the importance of phenotyping participants for fMRI taste studies to increase the statistical power of group analysis.

Fig. 2. (colour online) Cortical response to oral fat. (a) Blood oxygenation level-dependent response to oral fat delivery, shown with false discovery rate (FDR) corrected at P < 0·05, overlaid on a T 1-weighted image. (b) Region of interest analysis of the T-scores showing a significant increase in the oral somatosensory (SI, SII and mid-insula) and reward area (amygdala) in 6-n-propylthiouracil supertasters( Reference Eldeghaidy, Marciani and McGlone 38 ). ACC, anterior cingulate cortex.

Effect of hunger and satiety on functional MRI response

A number of fMRI studies have investigated the cortical modulation to satiation. Most studies show increased activation in insula, amygdala, OFC parahippocampal cortex, thalamus, hypothalamus, ACC and caudate in a hunger/fasting state, compared with increased activation in prefrontal cortex and inferior parietal lobe in a satiated/fed state (areas that show decreased activation in fasting/hunger areas). Viewing food images when hungry modulates the response in appetite-related brain regions, including the amygdala, parahippocampal gyrus and lateral OFC, compared with the fed state( Reference Fuhrer, Zysset and Stumvoll 66 Reference van der Laan, de Ridder and Viergever 69 ). In addition, manipulating food motivation by varying energy content of food images is associated with fMRI activation in hypothalamus, ventral stratium, cerebellum and frontal middle gyrus to high-energy food images compared with low-energy images( Reference Fuhrer, Zysset and Stumvoll 66 , Reference van der Laan, de Ridder and Viergever 69 Reference Goldstone, de Hernandez and Beaver 71 ).

In addition to visual stimulation with food images, studies using oral food cues have also shown modulation of brain responses by satiation. Key brain areas attenuated due to satiation include the insula, amygdala, striatum and OFC. Suppression in OFC, amygdala, ventral striatum is reported in many studies and may reflect the decrease in pleasantness and desire to eat( Reference O'Doherty, Rolls and Francis 25 , Reference Smeets, Graaf and Stafleu 72 , Reference Smeets, Weijzen and de Graaf 73 ). Suppression in the anterior insula activity on satiation suggests its role in feeding behaviour in addition to its taste sensory processing( Reference de Araujo, Kringelbach and Rolls 22 , Reference O'Doherty, Rolls and Francis 25 , Reference Small, Zatorre and Dagher 74 Reference Gautier, Del Parigi and Chen 76 ). The hypothalamus is widely recognised as the gatekeeper to control food intake, highly influenced by nutrients, with evidence that hypothalamic dysfunction may lead to obesity( Reference Thaler and Schwartz 77 ). Prior studies have shown the hypothalamus is modulated by satiety( Reference Gautier, Del Parigi and Chen 76 , Reference Smeets, de Graaf and Stafleu 78 ); however this modulation is inconsistent across BOLD studies, and may be due to its small structure, variability in position and close proximity to the sinus cavity. Recent CBF studies show a decrease in activation of the hypothalamus after the consumption of glucose( Reference Page, Chan and Arora 79 ) and a high-fat meal( Reference Frank, Linder and Kullmann 40 ) compared with baseline. In addition, the decrease in hypothalamus CBF correlated positively with the insula gustatory brain region( Reference Frank, Linder and Kullmann 40 ), indicating the interaction between homeostatic and taste areas in response to a high-fat meal.

How do hormonal responses influence the cortex?

Food intake and its termination are affected by internal and external factors. The homeostatic system controls appetite and food intake via anorectic and appetitive hormones connecting to the neural circuitry, and converging through the hypothalamus to stimulate or inhibit food intake( Reference von Ruesten, Steffen and Floegel 80 ). The non-homeostatic mechanisms including food palatability (through sight, smell and taste sensory), habitual, sociocultural, emotional and economic influences also drive food intake and appetite. It is now widely accepted that, there is extensive cross-modulation between homeostatic and non-homeostatic systems, with regard to appetite control. Fig. 3 shows a simplified schematic of the gut–brain axis and the appetite and homeostatic brain areas modulated by food intake.

Fig. 3. (colour online) A simplified illustration of the gut–brain axis and appetite and homeostatic brain areas modulated by food intake. OFC, the orbitofrontal cortex; ACC, anterior cingulate cortex; PYY, peptide YY, GLP-1, glucagon-like peptide 1; CCK, chole cystokinin.

Peptide YY (PYY), glucagon-like peptide 1 and cholecystokinin (CCK) are anorectic hormones secreted by the gut and intestine following a meal ingestion, leading to inhibition of food intake. Prior BOLD-fMRI studies have assessed the brain response to an intravenous infusion of PYY, and showed a modulation in OFC, posterior insula, ACC, striatum and homeostatic regions of the brainstem and hypothalamus( Reference Batterham, Ffytche and Rosenthal 81 ). The subjects’ energy intake correlated negatively with OFC signal change after the PYY infusion and positively with hypothalamus activity after saline infusion. These authors postulated the presence of PYY switched the regulation of food intake from a homeostatic brain region (hypothalamus) to a hedonic region (OFC). In a more recent study, the combined administration of PYY and glucagon-like peptide 1 to fasted human subjects attenuated brain areas that control appetitive behaviour, including amygdala, caudate, insula, nucleus accumbens, OFC and putamen( Reference De Silva, Salem and Long 82 ).

CCK is released within minutes of eating, as a function of the presence of fat (long-chain NEFA) or protein, and thought to play a role in meal termination( Reference Moran and Kinzig 83 , Reference Liddle, Goldfine and Rosen 84 ). The satiety effects of CCK are mediated in part by the vagal nerve( Reference Batterham, Cowley and Small 85 , Reference Degen, Matzinger and Drewe 86 ), to activate the brainstem nucleus tractus solitarius which projects to brain regions controlling food intake (e.g. hypothalamus and amygdala)( Reference Petrovich, Setlow and Holland 87 ). Very few studies have assessed the brains’ response to nutrients and the role of CCK in mediating such a response. The intra-gastric infusion of lipids has been shown to lead to a CCK-dependent increase in BOLD signal in the brainstem, pons, hypothalamus, cerebellum and motor cortical areas( Reference Lassman, Mckie and Gregory 88 ). Li et al. investigated the brain response to different macronutrients (fat, glucose and protein) and measured the associated gut hormone concentrations, including ghrelin (appetitive hormone), CCK, and glucagon-like peptide 1, in both fed and fasted states( Reference Li, An and Zhang 89 ). The BOLD response reduced when fed in the middle insula, thalamus, parahippocampal cortex, caudate, and lateral OFC, compared with the hunger state( Reference Li, An and Zhang 89 ). However, amygdala activation was modulated following protein ingestion but not after fat or glucose, suggesting it may play a more important role than other regions in mediating dietary protein-induced satiety. BOLD signal changes were positively correlated with circulating ghrelin concentrations and were negatively correlated with circulating insulin, CCK and glucagon-like peptide 1 concentrations. More recently, the CCK plasma values have been showed to correlate negativity with BOLD response in reward (amygdala) and taste (insula) regions in response to ingestion of a high-fat meal( Reference Eldeghaidy, Marciani and Hort 90 ). A number of studies have also investigated the cortical response to ghrelin( Reference Sun, Veldhuizenb and Wray 91 Reference Malik, McGlone and Bedrossian 93 ).

Effect of obesity on the cortical response

There is now extensive literature on using fMRI to examine how obesity influences the cortical response to food. Recent fMRI studies showed that brain activity of obese people is significantly different from that of normal-weight control subjects in several brain regions implicated in food reward, emotion/memory and sensory/motor processing, with greater activation in the obese group paired with hypo-activity in areas associated with homeostatic satiety and cognitive control/attention. Szalay et al. showed that obese subjects had high levels of activation in taste and reward areas (amygdala, nucleus accumbens for sweet, fatty or quinone samples, whereas control healthy subjects varied their response depending on the taste of the sample( Reference Szalay, Aradi and Schwarcz 94 ). The authors postulated that the dysfunction in reward circuitry in obese subjects may have a distinguished role in overeating due to their altered responsiveness to tastes. Other studies( Reference Rothemund, Preuschhof and Bohner 95 , Reference Stoeckel, Weller and Cook 96 ) demonstrated that food motivation associated with viewing high- and low-energy food images in obese women is different from healthy weighted subjects, with an enhanced activation to high-energy food images in dorsal striatal regions (reward areas). Moreover, increasing body BMI positively correlated with BOLD signal for the high-energy condition in anterior insula (taste region), OFC (reward and secondary taste area), posterior cingulate, dorsal striatum and post-central gyrus. A more recent functional connectivity analysis study showed a relative deficiency in the reward network in obese women, with a deficit in amygdala modulated activation of both OFC and nucleus accumbens, but a tendency towards excessive modulation of the nucleus accumbens by the OFC( Reference Stoeckel, Kim and Weller 97 ). These results show it may not only be the hyper-activation of the reward system in obese individuals that increases the motivational values of food, but also differences in the interaction of regions within the reward network. Together these studies demonstrate unique patterns of brain activation in obese compared to healthy control individuals when food motivation is manipulated by varying food content.

What can ultra-high field offer to functional MRI studies of nutrition?

The studies described in this review demonstrate the application of fMRI to reveal brain regions involved in food perception, and provide a powerful method to study the interactions between homeostatic and hedonic signals controlling eating mechanism. In addition, these studies suggest that the neural circuitry involved in the control of food intake is not limited to the hypothalamus and brainstem, but involves hedonic brain regions. However, there is still much research needed to understand the neural underpinnings in nutrition research in the human brain. One of the major gains of UHF (7 T) MR is the increased BOLD contrast-to-noise ratio. The use of such UHF scanners will improve the spatial mapping, and allow better differentiation of cortical areas involved in uni-modal and multi-modal processing, for example in the primary gustatory cortex. Furthermore, the increased BOLD contrast-to-noise ratio can be applied to study single trial BOLD responses and habituation, thus allowing the delivery of more natural stimuli and reduced adaptation effects.

Conclusion

In conclusion, neuroimaging methods have been shown to provide valuable insight into improving the understanding of flavour processing and the dependence of phenotype of the cortical response. fMRI studies have begun to demonstrate how the homeostatic system controls appetite and food, and allow the study of the effect of obesity at the cortical level.

Financial Support

None.

Conflicts of Interest

None.

Authorship

S. T. F and S. E. wrote the paper. Both authors have read and approved the final manuscript.

Footnotes

The original version of this article was published with incorrect conference details. A notice detailing this has been published and the error rectified in the online and print PDF and HTML copies.

References

1. Ogawa, S, Lee, TM, Kay, AR et al. (1990) Brain magnetic resonance imaging with contrast dependent on blood oxygenation. Proc Natl Acad Sci USA 87, 98689872.Google Scholar
2. Okada, YC (1983) Inferences concerning anatomy and physiology of the human brain based on its magnetic field. Il Nuovo Cimento D 2, 379409.Google Scholar
3. Thulborn, KR, Waterton, JC, Matthews, PM et al. (1982) Oxygenation dependence of the transverse relaxation time of water protons in whole blood at high field. Biochim Biophys Acta 714, 265270.CrossRefGoogle ScholarPubMed
4. Buxton, RB, Uludag, K, Dubowitz, DJ et al. (2004) Modeling the hemodynamic response to brain activation. Neuroimage 23, S220S233.Google Scholar
5. Hoge, RD, Atkinson, J, Gill, B et al. (1999) Investigation of BOLD signal dependence on cerebral blood flow and oxygen consumption: the deoxyhemoglobin dilution model. Magn Reson Med 42, 849863.Google Scholar
6. Edelman, RR, Siewert, B, Darby, DG et al. (1994) Qualitative mapping of cerebral blood flow and functional localization with echo-planar MR imaging and signal targeting with alternating radio frequency. Radiology 192, 513520.Google Scholar
7. Kim, SG (1995) Quantification of relative cerebral blood flow change by flow-sensitive alternating inversion recovery (FAIR) technique: application to functional mapping. Magn Reson Med 34, 293301.Google Scholar
8. Wu, W-C, Fernandez-Seara, M, Detre, JA et al. (2007) A theoretical and experimental investigation of the tagging efficiency of pseudocontinuous arterial spin labeling. Magn Reson Med 58, 10201027.CrossRefGoogle ScholarPubMed
9. Buxton, RB, Wong, EC & Frank, LR (1998) Dynamics of blood flow and oxygenation changes during brain activation: the balloon model. Magn Reson Med 39, 855864.Google Scholar
10. Silva, AC, Lee, SP, Yang, G et al. (1999) Simultaneous blood oxygenation leveldependent and cerebral blood flow functional magnetic resonance imaging during forepaw stimulation in the rat. J Cerebr Blood F Met 19, 871879.Google Scholar
11. Duong, TQ, Kim, DS, Ugurbil, K et al. (2000) Spatiotemporal dynamics of the BOLD fMRI signals: toward mapping submillimeter cortical columns using the early negative response. Magn Reson Med 44, 231242.Google Scholar
12. Purdon, PL & Weisskoff, RM (1998) Effect of temporal autocorrelation due to physiological noise and stimulus paradigm on voxel-level false-positive rates in fMRI. Hum Brain Mapp 6, 239249.Google Scholar
13. Small, DM, Zald, DH, Jones-Gotman, M et al. (1999) Human cortical gustatory areas: a review of functional neuroimaging data. Neuroreport 10, 713.Google Scholar
14. Small, DM, Jones-Gotman, M, Zatorre, RJ et al. (1997) Flavor processing: more than the sum of its parts. Neuroreport 8, 39133917.Google Scholar
15. Veldhuizen, MG, Albrecht, J, Zelano, C et al. (2011) Identification of human gustatory cortex by activation likelihood estimation. Hum Brain Mapp 32, 22562266.Google Scholar
16. Francis, S, Rolls, ET, Bowtell, R et al. (1999) The representation of pleasant touch in the brain and its relationship with taste and olfactory areas. Neuroreport 10, 453459.Google Scholar
17. O'Doherty, J, Rolls, ET, Francis, S et al. (2001) Representation of pleasant and aversive taste in the human brain. J Neurophysiol 85, 13151321.Google Scholar
18. Small, DM, Gregory, MD, Mak, YE et al. (2003) Dissociation of neural representation of intensity and affective valuation in human gustation. Neuron 39, 701711.Google Scholar
19. O'Doherty, JP, Dayan, P, Friston, K et al. (2003) Temporal difference models and reward-related learning in the human brain. Neuron 38, 329337.Google Scholar
20. Kringelbach, ML, de Araujo, IET & Rolls, ET (2004) Taste-related activity in the human dorsolateral prefrontal cortex. Neuroimage 21, 781788.CrossRefGoogle ScholarPubMed
21. O'Doherty, J, Rolls, E, Francis, S et al. (2001) Representation of pleasant and aversive taste in the human brain. J Neurophysiol 85, 13151321.Google Scholar
22. de Araujo, IE, Kringelbach, M, Rolls, E et al. (2003) Human cortical responses to water in the mouth, and the effects of thirst. J Neurophysiol 90, 18651876.Google Scholar
23. Ogawa, H, Wakita, M, Hasegawa, K et al. (2005) Functional MRI detection of activation in the primary gustatory cortices in humans. Chem Senses 30, 583592.Google Scholar
24. Faurion, A, Cerf, B, Van De Moortele, PF et al. (1999) Human taste cortical areas studied with functional magnetic resonance imaging: evidence of functional lateralization related to handedness. Neurosci Lett 277, 189192.Google Scholar
25. O'Doherty, J, Rolls, ET, Francis, S et al. (2000) Sensory-specific satiety-related olfactory activation of the human orbitofrontal cortex. Neuroreport 11, 893897.Google Scholar
26. Savic, I, Gulyas, B, Larsson, M et al. (2000) Olfactory functions are mediated by parallel and hierarchical processing. Neuron 26, 735745.Google Scholar
27. Yousem, DM, Williams, SCR, Howard, RO et al. (1997) Functional MR imaging during odor stimulation: preliminary data. Radiology 204, 833838.Google Scholar
28. Fulbright, RK, Skudlarski, P, Lacadie, CM et al. (1998) Functional MR imaging of regional brain responses to pleasant and unpleasant odors. AJNR Am J Neuroradiol 19, 17211726.Google Scholar
29. Weismann, M, Yousry, I, Heuberger, E et al. (2001) Functional magnetic resonance imaging of human olfaction. Neuroimaging Clin N Am 11, 237250.Google Scholar
30. Poellinger, A, Thomas, R, Lio, P et al. (2001) Activation and habituation in olfaction—an fMRI study. NeuroImage 13.Google Scholar
31. Cerf-Ducastel, B, Van de Moortele, PF, MacLeod, P et al. (2001) Interaction of gustatory and lingual somatosensory perceptions at the cortical level in the human: a functional magnetic resonance imaging study. Chem Senses 26, 371383.Google Scholar
32. Rudenga, K, Green, BG, Nachtigal, D et al. (2010) Evidence for an intgrated oral sensory module in the human ventral insula. . Chem Senses 35, 693703.Google Scholar
33. Guest, S, Grabenhorst, F, Essick, G et al. (2007) Human cortical representation of oral temperature. Physiol Behav 92, 975984.Google Scholar
34. Gilbertson, TA (1998) Gustatory mechanisms for the detection of fat. Curr Opin Neurobiol 8, 447452.Google Scholar
35. Mattes, RD (2005) Fat taste and lipid metabolism in humans. Physiol Behav 86, 691697.Google Scholar
36. de Araujo, IE & Rolls, ET (2004) Representation in the human brain of food texture and oral fat. J Neurosci 24, 30863093.Google Scholar
37. De Celis Alonso, B, Marciani, L, Head, K et al. (2007) Functional Magnetic Resonance imaging assessment of the cortical representation of oral viscosity. J Texture Stud 38, 725737.Google Scholar
38. Eldeghaidy, S, Marciani, L, McGlone, F et al. (2011) The cortical response to the oral perception of fat emulsions and the effect of taster status. J Neurophysiol 105, 25722581.Google Scholar
39. Grabenhorst, F, Rolls, ET, Parris, BA et al. (2010) How the brain represents the reward value of fat in the mouth. Cereb Cortex 20, 10821091.Google Scholar
40. Frank, S, Linder, K, Kullmann, S et al. (2012) Fat intake modulates cerebral blood flow in homeostatic and gustatory brain areas in humans. Am J Clin Nutr 95, 13421349.CrossRefGoogle ScholarPubMed
41. Grabenhorst, F & Rolls, ET (2014) The representation of oral fat texture in the human somatosensory cortex. Hum Brain Mapp 35, 25212530.Google Scholar
42. Small, DM (2008) Flavor and the formation of category-specific processing in olfaction. Chem Percept 1, 136146.Google Scholar
43. Small, DM, Voss, J, Mak, YE et al. (2004) Experience-dependent neural integration of taste and smell in the human brain. J Neurophysiol 92, 18921903.Google Scholar
44. De Araujo, IET, Rolls, ET, Kringelbach, ML et al. (2003) Taste-olfactory convergence, and the representation of the pleasantness of flavour, in the human brain. Eur J Neurosci 18, 20592068.Google Scholar
45. Eldeghaidy, S, Marciani, L, Pfeiffer, J et al. (2011) Use of an immediate swallow protocol to assess taste and aroma integration in fMRI studies. Chemosens Percept 4, 163174.Google Scholar
46. Small, DM & Prescott, J (2005) Odor/taste integration and the perception of flavor. Exp Brain Res 166, 345357.Google Scholar
47. McCabe, C & Rolls, ET (2007) Umami: a delicious flavor formed by convergence of taste and olfactory pathways in the human brain. Eur J Neurosci 25, 18551864.Google Scholar
48. Verhagen, JV & Engelen, L (2006) The neurocognitive bases of human multimodal food perception: sensory integration. Neurosci Biobehav Rev 30, 613665.Google Scholar
49. Bartoshuk, LM, Duffy, VB & Miller, IJ (1994) PTC/PROP tasting: anatomy, psychophysics, and sex effects. Physiol Behav 56, 11651171.Google Scholar
50. Bartoshuk, LM, Duffy, VB, Fast, K et al. (2003) Labeled scales (eg, category, Likert, VAS) and invalid across-group comparisons: what we have learned from genetic variation in taste. Food Qual Prefer 14, 125138.Google Scholar
51. Chang, WI, Chung, JW, Kim, YK et al. (2006) The relationship between phenylthiocarbamide (PTC) and 6-n-propylthiouracil (PROP) taster status and taste thresholds for sucrose and quinine. Arch Oral Biol 51, 427432.Google Scholar
52. Miller, IJ & Reedy, FE (1990) Variations in human taste bud density and taste Intensity perception. Physiol Behav 47, 12131219.CrossRefGoogle ScholarPubMed
53. Duffy, VB, Bartoshuk, LM, Lucchina, LA et al. (1996) Supertasters of PROP (6-npropylthiouracil) rate the highest creaminess to high-fat milk products. Chem Senses 21, 598.Google Scholar
54. Duffy, VB, Peterson, J & Bartoshuk, L (2004) Associations between taste genetics, oral sensation and alcohol intake. Physiol Behav 82, 435445.Google Scholar
55. Manrique, S & Zald, DH (2006) Individual differences in oral thermosensation. Physiol Behav 88, 417424.Google Scholar
56. Duffy, VB, Davidson, AC, Kidd, JR et al. (2004) Bitter receptor gene (TAS2R38), 6-n-propylthlouracll (PROP) bitterness and alcohol intake. Alcohol Clin Exp Res 28, 16291637.Google Scholar
57. Duffy, BV & Bartoshuk, LM (2000) Food acceptance and genetic variation in taste. J Am Diet Assoc 100, 647655.Google Scholar
58. Essick, GK, Chopra, A, Guest, S et al. (2003) Lingual tactile acuity, taste perception, and the density and diameter of fungiform papillae in female subjects. Physiol Behav 80, 289302.Google Scholar
59. Cruz, A & Green, BG (2000) Thermal stimulation of taste. Nature 403, 889892.Google Scholar
60. Green, BG & George, P (2004) Thermal taste’ predicts higher responsiveness to chemical taste and flavor. Chem Senses 29, 617628.Google Scholar
61. Bajec, MR & Pickering, G (2008) Thermal taste, PROP responsiveness, and perception of oral sensations. Physiol Behav 95, 581590.CrossRefGoogle ScholarPubMed
62. Clark, R, Francis, S, Bealin-Kelly, F et al. (2011) The cortical response to carbonation and its interaction with taste perception. In 9th Pangborn Sensory Science Symp.Google Scholar
63. Stice, E, Spoor, S, Bohon, C et al. (2008) Relation of reward from food intake and anticipated food intake to obesity: a functional magnetic resonance imaging study. J Abnorm Psychol 117, 924935.CrossRefGoogle ScholarPubMed
64. Felsted, JA, Ren, X, Chouinard-Decorte, F et al. (2010) Genetically determined differences in brain response to a primary food reward. J Neurosci 30, 24282432.Google Scholar
65. Wilcox, CE, Claus, ED, Blaine, SK et al. (2013) Genetic variation in the alpha synuclein gene (SNCA) is associated with BOLD response to alcohol cues. J Stud Alcohol Drugs 74, 233244.Google Scholar
66. Fuhrer, D, Zysset, S & Stumvoll, M (2008) Brain activity in hunger and satiety: an exploratory visually stimulated FMRI study. Obesity (Silver Spring) 16, 945950.Google Scholar
67. LaBar, KS, Gitelman, DR, Parrish, TB et al. (2001) Hunger selectively modulates corticolimbic activation to food stimuli in humans. Behav Neurosci 115, 493500.Google Scholar
68. Mohanty, A, Gitelman, DR, Small, DM et al. (2008) The spatial attention network interacts with limbic and monoaminergic systems to modulate motivation- induced attention shifts. Cereb Cortex 18, 26042613.Google Scholar
69. van der Laan, LN, de Ridder, DTD, Viergever, MA et al. (2011) The first taste is always with the eyes: a meta-analysis on the neural correlates of processing visual food cues. NeuroImage 55, 296303.Google Scholar
70. Killgore, WD, Young, AD, Femia, LA et al. (2003) Cortical and limbic activation during viewing of high- versus low-calorie food. Neuroimage 19, 13811394.Google Scholar
71. Goldstone, AP, de Hernandez, CG, Beaver, JD et al. (2009) Fasting biases brain reward systems towards high-calorie foods. Eur J Neurosci 30, 16251635.Google Scholar
72. Smeets, P, Graaf, C, Stafleu, A et al. (2006) Effect of satiety on brain activation during chocolate tasting in men and women. Am J Clin Nutr 83, 12971305.Google Scholar
73. Smeets, PAM, Weijzen, P, de Graaf, C et al. (2011) Consumption of caloric and non-caloric versions of a soft drink differentially affects brain activation during tasting. Neuroimage 54, 13671367.Google Scholar
74. Small, D, Zatorre, R, Dagher, A et al. (2001) Changes in brain activity related to eating chocolate From pleasure to aversion. Brain 124, 17201733.Google Scholar
75. Tataranni, P & DelParigi, A (2003) Functional neuroimaging: a new generation of human brain studies in obesity research. Obes Rev 4, 229238.Google Scholar
76. Gautier, J, Del Parigi, A, Chen, K et al. (2001) Effect of satiation on brain activity in obese and lean women. Obes Res 9, 676684.Google Scholar
77. Thaler, JP & Schwartz, MW (2010) Minireview: inflammation and obesity pathogenesis: the hypothalamus heats up. Endocrinology 151, 41094115.Google Scholar
78. Smeets, P, de Graaf, C, Stafleu, A et al. (2005) Functional MRI of human hypothalamic responses following glucose ingestion. Neuroimage 24, 363368.Google Scholar
79. Page, KA, Chan, O, Arora, J et al. (2013) Effects of fructose vs glucose on regional cerebral blood flow in brain regions involved with appetite and reward pathways. J Am Med Assoc 309, 6370.Google Scholar
80. von Ruesten, A, Steffen, A, Floegel, A et al. (2011) Trend in obesity prevalence in European adult cohort populations during follow-up since 1996 and their predictions to 2015. PLoS ONE 11, e27455.Google Scholar
81. Batterham, R, Ffytche, D, Rosenthal, J et al. (2007) PYY modulation of cortical and hypothalamic brain areas predicts feeding behaviour in humans. Nature 450, 106109.Google Scholar
82. De Silva, A, Salem, V, Long, CJ et al. (2011) The gut hormones PYY 3–36 and GLP-1 7–36 amide reduce food intake and modulate brain activity in appetite centers in humans. Cell Metab 14, 700706.Google Scholar
83. Moran, TH & Kinzig, KP (2004) Gastrointestinal satiety signals II. Cholecystokinin. Am J Physiol Gastrointest Liver Physiol 286, G183G188.Google Scholar
84. Liddle, RA, Goldfine, ID, Rosen, MS et al. (1985) Cholecystokinin bioactivity in human plasma. Molecular forms, responses to feeding, and relationship to gallbladder contraction. J Clin Invest 75, 11441152.Google Scholar
85. Batterham, R, Cowley, M, Small, C et al. (2002) Gut hormone PYY3–36 physiologically inhibits food intake. Nature 418, 650654.Google Scholar
86. Degen, L, Matzinger, D, Drewe, J et al. (2001) The effect of cholecystokinin in controlling appetite and food intake in humans. Peptides 22, 12651269.Google Scholar
87. Petrovich, G, Setlow, B, Holland, P et al. (2002) Amygdalo-hypothalamic circuit allows learned cues to override satiety and promote eating. J Neurosci 22, 87488753.Google Scholar
88. Lassman, D, Mckie, S, Gregory, L et al. (2010) Defining the role of cholecystokinin in the lipid-induced human brain activation matrix. Gastroenterology 138, 15141524.Google Scholar
89. Li, J, An, R, Zhang, Y et al. (2012) Correlations of macronutrient-induced functional magnetic resonance imaging signal changes in human brain and gut hormone responses. Am J Clin Nutr 96, 275282.Google Scholar
90. Eldeghaidy, S, Marciani, L, Hort, J et al. (2014) Prior feeding of fat modulates the cortical response to fat in the mouth in humans. In Joint Annual Metting ISMRM-ESMRMB.Google Scholar
91. Sun, X, Veldhuizenb, MG, Wray, AE et al. (2014) The neural signature of satiation is associated with ghrelin response and triglyceride metabolism. Physiol Behav.Google Scholar
92. Goldstone, AP, Prechtl, CG, Scholtz, S et al. (2014) Ghrelin mimics fasting to enhance human hedonic, orbitofrontal cortex, and hippocampal responses to food. Am J Clin Nutr 99, 13191330.Google Scholar
93. Malik, S, McGlone, F, Bedrossian, D et al. (2008) Ghrelin modulates brain activity in areas that control appetitive behavior. Cell Metab 7, 400409.Google Scholar
94. Szalay, C, Aradi, M, Schwarcz, A et al. (2012) Gustatory perception alterations in obesity: an fMRI study. Brain Res 1473, 131140.Google Scholar
95. Rothemund, Y, Preuschhof, C, Bohner, G et al. (2007) Differential activation of the dorsal striatum by high-calorie visual food stimuli in obese individuals. Neuroimage 37, 410421.Google Scholar
96. Stoeckel, LE, Weller, RE, Cook, EW et al. (2008) Widespread reward-system activation in obese women in response to pictures of high-calorie foods. Neuroimage 41, 636647.Google Scholar
97. Stoeckel, LE, Kim, J, Weller, RE et al. (2009) Effective connectivity of a reward network in obese women. Brain Res Bull 79, 388395.Google Scholar
Figure 0

Fig. 1. Schematic representation of (a) the haemodynamic changes which lead to a blood oxygenation level-dependent (BOLD) signal, and (b) the BOLD haemodynamic response function.

Figure 1

Fig. 2. (colour online) Cortical response to oral fat. (a) Blood oxygenation level-dependent response to oral fat delivery, shown with false discovery rate (FDR) corrected at P < 0·05, overlaid on a T1-weighted image. (b) Region of interest analysis of the T-scores showing a significant increase in the oral somatosensory (SI, SII and mid-insula) and reward area (amygdala) in 6-n-propylthiouracil supertasters(38). ACC, anterior cingulate cortex.

Figure 2

Fig. 3. (colour online) A simplified illustration of the gut–brain axis and appetite and homeostatic brain areas modulated by food intake. OFC, the orbitofrontal cortex; ACC, anterior cingulate cortex; PYY, peptide YY, GLP-1, glucagon-like peptide 1; CCK, chole cystokinin.