Food reward

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Food intake involves both 'homeostatic feeding' (energy demands) and ‘non-homeostatic feeding’; the latter is associated with food reward, which involves both 'liking’ (pleasure/palatability) and ‘wanting’ (incentive motivation) according to the salience theory. Experiments in mice suggest that ‘liking’ involves the release of mu-opioid peptides in the nucleus accumbens, ventral pallidum, parabrachial nucleus, and nucleus of the solitary tract, while ‘wanting’ involves the neurotransmitter dopamine released in the prefrontal cortex (PFC), amygdala, hypothalamus, and projections from the ventral tegmental area (VTA) to the nucleus accumbens [1].


Food intake diagram.jpg
Key Definitions
Wanting/ Incentive salience - The motivational aspect of a stimulus that transforms the sensory information into a more desirable stimulus.
Liking - Immediate pleasure from consumption
Hedonia - The feeling of pleasure
Motivation- The direction towards a particular behaviour to achieve a goal
Reinforcement - The process by which a stimulus strengthens a behavioural response so that the probability of response is increased when the stimulus is presented again.

Motivated behaviour and food as a reinforcer

The pathways involved in motivating feeding behaviour are complex. The brain’s reward systems react to stimuli such as sight, smell and taste, and other cues that predict food. However, hunger cannot result in unconditioned goal-directed behaviour [2]. Chance encounters with various palatable foods are required before goal-directed behaviour can occur, which links the internal needs with the salience of environmental stimuli [3]

For example, an infant recognises [4] and learns to seek out sweet tastes, but the desire for a particular food is controlled by the interaction of peptide levels with the brain circuitry. Where the peptide levels are related to hunger, and the brain circuitry coding the animal’s reinforcement history for that specific food. Subsequently, the infant will indiscriminately taste both food and non-food objects, until it has received reinforcing feedback from sufficient stimuli. In addition, the monkey’s appetite for a yellow banana requires the prior learning of the relation of the sight of the yellow skin of a banana, with the sweet taste of the white banana meat plus the consequences resulting from eating the fruit. Therefore, preference for a specific food, results only when the post-ingestional consequences of that food’ reinforce’ the tendency to eat that food. For the above reasons, food is considered to be a strong reinforcer. Moreover, when the response of a behaviour stimulated by a reinforcer increases the rate of that specific behaviour; that is known as positive reinforcement or reward learning, and the positive events are called rewards [5]. The reinforcing efficacy of food reward is the ability of the reward to maintain rather than to establish behaviour; consequently the stimulus learning contributes to the response learning.

The first evidence for the involvement of dopamine in food reward came from studies in rats, where dopamine antagonists blocked the rewarding effects of brain stimulation and of psychomotor stimulants[6] [7].

Food reward pathways

Mesolimbic Dopaminergic Reward System

The role of the Mesolimbic Dopaminergic Reward System

In the ‘reward circuit’, projections from the VTA to the nucleus accumbens have received the most attention. Dopamine action in the nucleus accumbens is thought to be needed for motivation to acquire food or addictive drugs. Most reviews suggest that the projections from the VTA to the nucleus accumbens are needed for the motivation to eat but not for food consumption itself.

The Dopamine Hypothesis
Dopamine signalling from the VTA to the nucleus accumbens, hippocampus, amygdala and/or pre-frontal cortex promotes reward-related activities. Dopamine signalling in these brain regions focuses attention to salient environmental events and facilitates behaviour towards directed goals. It is thought that dopamine released from the VTA also promotes learning between food reward and the environment.

Dopamine's role in reward?
Hedonia – Dopamine in the nucleus accumbens acts as a pleasure neurotransmitter. Proposed due to drug activity. Not all rewards activate the reward system suggesting that the mesolimbic pathway is not solely hedonic.

Learning – predictions of future rewards, nucleus accumbens and VTA lesions do not affect this part but lack the motivation for the reward. •Incentive Salience – the ‘wanting’ of the reward, released when there is a stimulus worth working hard for. In absence of dopamine, the environmental stimulus goes unnoticed and the animal will eventually die from starvation and dehydration.

The incentive salience theory seems to best fit the data in this field. Therefore dopamine causes the wanting of the reward after the appropriate stimuli have been processed in the reward system. Dopamine transmission is needed to form these associations. An increase in extracellular dopamine is seen in regard to natural rewards, food, water and sex, during acute administration. However novelty is an important factor in the increased release from the nucleus accumbens.

It has been suggested that the role of dopamine in motivation is shared between the nucleus accumbens and CPu pathways(see diagram). The SNpc-CPu pathway is essential for motivation with dopamine signalling from the VTA to the nucleus accumbens needed in regard to modulating the actions of the other dopamine pathway.

The substantia nigra pars compacta to the caudate putamen: A critical dopamine pathway

Dopamine-deficient mice starve, apparently because they are not motivated to respond to hunger signals. Thus, its been proposed that dopamine is crucial for mice to engage in the majority of goal-directed or motivated behaviours. However it is not clear which dopamine pathway is involved; a universal finding is the involvement of the striatum, the input structure of the basal ganglia in a circuit responsible for mediating goal-directed behaviour, with the striatum’s central role being the processing of reward like stimuli. The two proposed pathways are from the VTA to nucleus accumbens (ventral striatum); or the substantia nigra pars compacta to the caudate putamen (dorsal striatum). The striatum includes not only the dorsal region, which encompasses the caudate nucleus and putamen, but also the ventral region that includes the core and shell of the nucleus accumbens (Figure 2) [8]

Our understanding of how reward information is processed comes mailly from studies in animal models. One study, using nonhuman primates, found that striatal neurons responded to the anticipation and delivery of reward [9] Another found a reward-related dopamine response specifically in the mouse dorsal striatum, correlated with the delivery of food reward [10] The importance of dopamine in the dorsal striatum was demonstrated using dopamine-deficient mice whose dopamine signalling is restored by viral rescue. These mice learned to lever press for food rewards as quickly as control mice, and their motivation to work for food was restored. Importantly, in these dopamine-deficient mice, feeding was never restored after viral transduction in the nucleus accumbens.[11][12]

Recently, advances in neuroimaging techniques has allowed researchers to extend such investigations to the human brain. Dopamine release increases in dorsal striatum of hungry participants when stimulated with food items, demonstrating its involvement in reward processing. During the delivery of rewards, fMRI signals were higher in the dorsal striatum, particularly the head of the caudate putamen(Delgado MR (2007)). These findings strongly suggest the human dorsal striatums involvement in reward processing; with the caudate putamen being an integral structure of a circuit involved in learning and updating current rewards with the aim of maximizing reward consumption. It has been proposed that dopamine signaling in the caudate putamen is essential for motivation, while dopamine signaling in the nucleus accumbens modulates this motivation and evaluation of reward-like stimuli (Figure 2).

The effect of hormones on the dopaminergic reward system

Plasma concentrations of ghrelin, leptin and insulin reflect the size of energy stores, such as adipose tissue, and act at the mediobasal hypothalamus to influence feeding behaviours and energy expenditure. Recent evidence also implicates a role for these hormones in dopamine reward pathways Palmiter R.D (2007), [13] Receptors for these hormones are located on dopamine neurones in the VTA, and ligand binding results in activation e.g. by ghrelin [14] or inhibition e.g. by insulin or leptin of dopamine signalling to the nucleus accumbens [15]. These alterations in dopamine signalling pathways have complex effects on eating behaviours. Many studies suggest that insulin and leptin attenuate food reward, reducing the incentive to eat. For example, administering insulin or leptin to rats affected conditional place preference (CPP), which assesses the ability to relate a particular food reward to a particular environment (Figlewicz DP, 2003). Rats were fed a high fat diet and underwent a ‘training period’ prior to the test involving intracerebroventricular administration of insulin or leptin. CPP was only abolished in those rats that received insulin or leptin treatment before or during the test as well as in training, whilst those who only received it in training maintained a normal CPP. This suggests that insulin and leptin influence the retrieval of food reward associations rather than the initial formation of these associations; presumably as a consequence of inhibition of dopamine reward pathways. These results have been reinforced by studies which have shown decreased sucrose self-administration in response to insulin or leptin administration and decreased sucrose licking following insulin treatment.[16] The high levels of insulin and leptin associated with obesity impair dopamine food reward pathways resulting in abnormal eating behaviours.

Table 1: Summary of effects of centrally administered insulin and leptin on reward behaviours

Behaviour Effect of insulin Effect of leptin
Brain self-stimulation Decrease Decrease
Relapse to heroin suckling Not tested Decrease
Acute sucrose suckling Decrease Not tested
Food-condtioned place preference Decrease Decrease
Sucrose self-administration Decrease Decrease
Acute chow intake Decrease Decrease
Opioid-stimulated sucrose Decrease Decrease

Ghrelin can increase dopamine signalling via ghrelin receptors on VTA neurones, via direct activation and also indirect manipulation of inputs onto the VTA to those of an excitatory nature. However, it is unclear whether this is a significant part the mechanism by which ghrelin stimulates feeding.[17]

A major difficulty in elucidating the roles of these hormones in reward systems is that, due to the involvement of multiple hormones, manipulation of one results in activation of compensatory mechanisms. Furthermore, by manipulating levels of these hormones to abnormal levels, we can suggest potential functions for them, but this may not be relevant when they are found at physiological concentrations. It should also be noted that the VTA possesses other neurons such as GABA-projection neurons, which also express receptors for the discussed hormones. Therefore, we can not assume that these hormones affect feeding behaviours solely by their action on dopamine reward pathways. It is also unclear whether these hormones act directly on dopamine reward pathways; insulin and leptin may influence dopamine reward systems by altering the activity of secondary peptide effector pathways, such as orexin A and melanocortins.

Opioid and cannabinoid systems

Other reward systems, including the endogenous opioid and endocannabinoid systems, also play a role in reward behaviours and interact with dopamine reward pathways. Opioid peptides act in the nucleus accumbens to increase ‘wanting’ and ‘liking’ of food rewards. [18] Opioids also influence mesolimibic dopamine pathways by inhibiting GABAergic input onto the dopamine neurones of the VTA, resulting in increased dopamine release [19]. The endocannabinoid system has also been implicated in reward behaviours, and cannabinoid receptors are expressed in several brain areas implicated in reward, including in the mesolimibic system. Endocannabinoids modulate neurotransmission, and, for example, cannabinoid receptor agonists stimulate dopamine release, increasing the reward experienced in response to food and drug abuse. Conversly, antagonising these receptors inhibits activation of dopamine release by such rewards. The normal physiological effect of endocannabinoids on reward systems remains unclear, but they been hypothesised to be involved in the ‘fine-tuning’ of dopamine release. [20]

Food reward and Obesity

Obesity and the dopamine system

There is a difference in dopamine activity between obese women and lean women/men in response to food and satiety. The obese have a higher metabolic activity in the parietal somatosensory area of the cortex which is linked to the sensory mouth, lips and tongue. An increased amount of sensory processing in this brain region could increase the reinforcing properties of food.

Deficiencies of the D2 receptor may increase the likelihood of being obese. [21] Obese people have fewer D2 receptors in the striatum and with both the D1 and D2 receptors acting synergistically to decrease feeding, this altered expression causes increased eating. The DRD2 gene is responsible for the reinforcing properties of food/addictive behaviour. [22] Those who have the allelic variant A1 in this gene have fewer D2 receptors and therefore less dopamine signalling within the brain. This ishigher in obese individuals, making the dopamine reward circuits less sensitive. This mayexplain why obese people overeat to compensate for their lack of reward.

References

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