Fasting biases brain reward systems towards high‐calorie foods

Goldstone, Anthony P.; Prechtl, Christina Gabriele; Beaver, John D.; Muhammed, Kinan; Croese, Charlotte; Bell, Gabriel; Durighel, Giuliana; Hughes, Emer; Waldman, Adam D.; Frost, Gary; Bell, Jimmy D.

doi:10.1111/j.1460-9568.2009.06949.x

Cited by 300 publications

(273 citation statements)

References 78 publications

(98 reference statements)

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“…In addition, manipulating food motivation by varying energy content of food images is associated with f MRI activation in hypothalamus, ventral stratium, cerebellum and frontal middle gyrus to high-energy food images compared with low-energy images (66,(69)(70)(71) .…”

Section: Effect Of Hunger and Satiety On Functional Mri Responsementioning

confidence: 99%

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

Francis

Eldeghaidy

2014

Proc. Nutr. Soc.

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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 (f MRI) have provided valuable insight into these pathways in the human brain. This review provides an outline of the methodology of f MRI, introducing the widely used blood oxygenation level-dependent contrast for f MRI and direct measures of cerebral blood flow using arterial spin labelling. A review of f MRI 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 f MRI studies investigating hormonal influences (e.g. peptide YY, cholecystokinin and ghrelin) on appetiterelated brain processes provided. Finally, recent developments in MR technology at ultrahigh field (7 T) are introduced, highlighting the advances this can provide for f MRI 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. Over the past decade, advances in neuroimaging techniques, particularly functional MRI (f MRI), have provided valuable insight into central food-related pathways in the human brain. This review outlines recent advances in f MRI to understand flavour perception and human appetitive behaviour. A brief overview of the method of f MRI and the blood oxygenation level-dependent (BOLD) contrast generally used in f MRI is provided, together with how more direct measures of cerebral blood flow (CBF) can be assessed. f MRI 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 f MRI studies to investigate the neural underpinnings in nutrition research will be described. Principles of functional MRIf MRI has revolutionised the research of functional brain mapping and is now the most widely used method for mapping brain activity. f MRI measures brain activity *Corresponding author: Dr S. Francis, email susan.francis@nottingham.ac.uk ‡ 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.

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Section: Effect Of Hunger and Satiety On Functional Mri Responsementioning

confidence: 99%

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

Francis

Eldeghaidy

2014

Proc. Nutr. Soc.

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“…The sample size was only moderate, although sample sizes of 12-15 are customary in fMRI studies. Lately it has been shown to be of importance to categorize the visual food stimuli in low versus high calorie stimuli as this could influence the results especially during the fasting state [47]. Also, recently published data have implicated adiponectin in regulating food intake and energy expenditure [48,49].…”

Section: Discussionmentioning

confidence: 99%

Brain Activation by Visual Food-Related Stimuli and Correlations with Metabolic and Hormonal Parameters: A fMRI Study

Jakobsdottir¹

2012

TONEUROEJ

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Regional brain activity in 15 healthy, normal weight males during processing of visual food stimuli in a satiated and a hungry state was examined and correlated with neuroendocrine factors known to be involved in hunger and satiated states. Two functional Magnetic Resonance Imaging (fMRI) sessions were performed with a one week interval, after overnight fasting or 1 hour after a standardized meal. Blood samples and appetite assessment were obtained after each fMRI session. Main effects of processing food versus non-food stimuli were observed in the ventral visual stream, including the fusiform gyrus and hippocampal areas bilaterally, significantly more in the fasting state. Leptin concentration correlated negatively with activity in the left hippocampal area and right insula during the satiation condition. A positive correlation between ghrelin and "thought of food" hunger scores were found. The positive correlation between ghrelin and food related activation in the insula areas and the right hippocampus during fasting did not reach significance. Conclusion:The increased activation of food vs non-food pictures in the ventral visual stream reflects increased salience of food pictures when subjects are hungry. Leptin was associated with activations in areas involved in processing of new information and emotion.

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“…Acute food deprivation increases the reinforcing value of food (127,128) , the subjective appeal of high-energy density foods and the activation of brain reward systems in response to pictures of these (43) . Sustained, hypoenergetic diets generally produce increased reports of hunger (94,110,114,129,130) and changes in hunger in response to dieting can predict successful/unsuccessful weight maintenance (131) .…”

Section: Psychological Effects Of Energy Restrictionmentioning

confidence: 99%

“…Pleasant feelings, or at least satisfaction or good mood, perhaps induced by pleasant memories of the meal (see below), may follow for 1 h or more after such a meal, provided that over-satiation has been avoided. In referring to satisfaction, pleasure and enjoyment, we are acknowledging that eating food is, normally, fundamentally rewarding to the brain (43) . It is recognised that there is an ongoing debate as to whether purely hedonic sensory pleasure ('liking') can be meaningfully separated from expressions of reward-based motivation ('wanting') (44 -46) .…”

Section: Potential Benefits Of Pleasure: Liking and Rewardmentioning

confidence: 99%

Potential benefits of satiety to the consumer: scientific considerations

Hetherington

Cunningham²,

Dye

et al. 2013

Nutr. Res. Rev.

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Foods and dietary patterns that enhance satiety may provide benefit to consumers. The aim of the present review was to describe, consider and evaluate research on potential benefits of enhanced satiety. The proposal that enhanced satiety could only benefit consumers by a direct effect on food intake should be rejected. Instead, it is proposed that there is a variety of routes through which enhanced satiety could (indirectly) benefit dietary control or weight-management goals. The review highlights specific potential benefits of satiety, including: providing appetite control strategies for consumers generally and for those who are highly responsive to food cues; offering pleasure and satisfaction associated with low-energy/healthier versions of foods without feeling 'deprived'; reducing dysphoric mood associated with hunger especially during energy restriction; and improved compliance with healthy eating or weight-management efforts. There is convincing evidence of short-term satiety benefits, but only probable evidence for longer-term benefits to hunger management, possible evidence of benefits to mood and cognition, inadequate evidence that satiety enhancement can promote weight loss, and no evidence on which consumers would benefit most from satiety enhancement. The appetite-reducing effects of specific foods or diets will be much more subtle than those of pharmaceutical compounds in managing hunger; nevertheless, the experience of pharmacology in producing weight loss via effects on appetite suggests that there is potential benefit of satiety enhancement from foods incorporated into the diet to the consumer.

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Fasting biases brain reward systems towards high‐calorie foods

Cited by 300 publications

References 78 publications

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

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

Brain Activation by Visual Food-Related Stimuli and Correlations with Metabolic and Hormonal Parameters: A fMRI Study

Potential benefits of satiety to the consumer: scientific considerations

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