Nucleus accumbens

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The nucleus accumbens (NAc or NAcc; also known as the accumbens nucleus, or formerly as the nucleus accumbens septi, Latin for 'nucleus adjacent to the septum') is a region in the basal forebrain rostral to the preoptic area of the hypothalamus.[1] The nucleus accumbens and the olfactory tubercle collectively form the ventral striatum. The ventral striatum and dorsal striatum collectively form the striatum, which is the main component of the basal ganglia.[2] The dopaminergic neurons of the mesolimbic pathway project onto the GABAergic medium spiny neurons of the nucleus accumbens and olfactory tubercle.[3][4] Each cerebral hemisphere has its own nucleus accumbens, which can be divided into two structures: the nucleus accumbens core and the nucleus accumbens shell. These substructures have different morphology and functions.

Nucleus accumbens
Approximate location of the nucleus accumbens in the brain
Nucleus accumbens of the mouse brain
Details
Part ofMesolimbic pathway
Basal ganglia (Ventral striatum)
PartsNucleus accumbens shell
Nucleus accumbens core
Identifiers
Latinnucleus accumbens septi
Acronym(s)NAc or NAcc
MeSHD009714
NeuroNames277
NeuroLex IDbirnlex_727
TA98A14.1.09.440
TA25558
FMA61889
Anatomical terms of neuroanatomy

Different NAcc subregions (core vs shell) and neuron subpopulations within each region (D1-type vs D2-type medium spiny neurons) are responsible for different cognitive functions.[5][6] As a whole, the nucleus accumbens has a significant role in the cognitive processing of motivation, aversion, reward (i.e., incentive salience, pleasure, and positive reinforcement), and reinforcement learning (e.g., Pavlovian-instrumental transfer);[4][7][8][9][10] hence, it has a significant role in addiction.[4][8] In addition, part of the nucleus accumbens core is centrally involved in the induction of slow-wave sleep.[11][12][13][14] The nucleus accumbens plays a lesser role in processing fear (a form of aversion), impulsivity, and the placebo effect.[15][16][17] It is involved in the encoding of new motor programs as well.[4]

Structure

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The nucleus accumbens is an aggregate of neurons which is described as having an outer shell and an inner core.[4]

Input

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Major glutamatergic inputs to the nucleus accumbens include the prefrontal cortex (particularly the prelimbic cortex and infralimbic cortex), basolateral amygdala, ventral hippocampus, thalamic nuclei (specifically the midline thalamic nuclei and intralaminar nuclei of the thalamus), and glutamatergic projections from the ventral tegmental area (VTA).[18] The nucleus accumbens receives dopaminergic inputs from the ventral tegmental area, which connect via the mesolimbic pathway. The nucleus accumbens is often described as one part of a cortico-basal ganglia-thalamo-cortical loop.[19]

Dopaminergic inputs from the VTA modulate the activity of GABAergic neurons within the nucleus accumbens. These neurons are activated directly or indirectly by euphoriant drugs (e.g., amphetamine, opiates, etc.) and by participating in rewarding experiences (e.g., sex, music, exercise, etc.).[20][21]

Another major source of input comes from the CA1 and ventral subiculum of the hippocampus to the dorsomedial area of the nucleus accumbens. Slight depolarizations of cells in the nucleus accumbens correlates with positivity of the neurons of the hippocampus, making them more excitable. The correlated cells of these excited states of the medium spiny neurons in the nucleus accumbens are shared equally between the subiculum and CA1. The subiculum neurons are found to hyperpolarize (increase negativity) while the CA1 neurons "ripple" (fire > 50 Hz) in order to accomplish this priming.[22]

The nucleus accumbens is one of the few regions that receives a high density of histaminergic projections from the tuberomammillary nucleus (the sole source of histamine neurons in the brain).[23]

Output

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The output neurons of the nucleus accumbens send axonal projections to the basal ganglia and the ventral analog of the globus pallidus, known as the ventral pallidum (VP). The VP, in turn, projects to the medial dorsal nucleus of the dorsal thalamus, which projects to the prefrontal cortex as well as back to the ventral and to dorsal striatum. Other efferents from the nucleus accumbens include connections with the tail of the ventral tegmental area,[24] substantia nigra, and the reticular formation of the pons.[1]

Shell

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The nucleus accumbens shell (NAcc shell) is a substructure of the nucleus accumbens. The shell and core together form the entire nucleus accumbens.

Location: The shell is the outer region of the nucleus accumbens, and – unlike the core – is considered to be part of the extended amygdala, located at its rostral pole.

Cell types: Neurons in the nucleus accumbens are mostly medium spiny neurons (MSNs) containing mainly D1-type (i.e., DRD1 and DRD5) or D2-type (i.e., DRD2, DRD3, and DRD4) dopamine receptors. A subpopulation of MSNs contain both D1-type and D2-type receptors, with approximately 40% of striatal MSNs expressing both DRD1 and DRD2 mRNA.[19][25][26] These mixed-type NAcc MSNs with both D1-type and D2-type receptors are mostly confined to the NAcc shell.[19] The neurons in the shell, as compared to the core, have a lower density of dendritic spines, less terminal segments, and less branch segments than those in the core. The shell neurons project to the subcommissural part of the ventral pallidum as well as the ventral tegmental area and to extensive areas in the hypothalamus and extended amygdala.[27][28][29]

Function: The shell of the nucleus accumbens is involved in the cognitive processing of reward, including subjective "liking" reactions to certain pleasurable stimuli, motivational salience, and positive reinforcement.[4][5][30][31] That NAcc shell has also been shown to mediate specific Pavlovian-instrumental transfer, a phenomenon in which a classically conditioned stimulus modifies operant behavior.[32][9][10] A "hedonic hotspot" or pleasure center which is responsible for the pleasurable or "liking" component of some intrinsic rewards is also located in a small compartment within the medial NAcc shell.[30][33][34] Addictive drugs have a larger effect on dopamine release in the shell than in the core.[4]

Core

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The nucleus accumbens core (NAcc core) is the inner substructure of the nucleus accumbens.

Location: The nucleus accumbens core is part of the ventral striatum, located within the basal ganglia. Cell types: The core of the NAcc is made up mainly of medium spiny neurons containing mainly D1-type or D2-type dopamine receptors. The D1-type medium spiny neurons mediate reward-related cognitive processes,[5][35][36] whereas the D2-type medium spiny neurons mediate aversion-related cognition.[6] The neurons in the core, as compared to the neurons in the shell, have an increased density of dendritic spines, branch segments, and terminal segments. From the core, the neurons project to other sub-cortical areas such as the globus pallidus and the substantia nigra. GABA is one of the main neurotransmitters in the NAcc, and GABA receptors are also abundant.[27][29]

Function: The nucleus accumbens core is involved in the cognitive processing of motor function related to reward and reinforcement and the regulation of slow-wave sleep.[4][11][12][13] Specifically, the core encodes new motor programs which facilitate the acquisition of a given reward in the future.[4] The indirect pathway (i.e., D2-type) neurons in the NAcc core which co-express adenosine A2A receptors activation-dependently promote slow-wave sleep.[11][12][13] The NAcc core has also been shown to mediate general Pavlovian-instrumental transfer, a phenomenon in which a classically conditioned stimulus modifies operant behavior.[32][9][10]

Cell types

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Approximately 95% of neurons in the NAcc are GABAergic medium spiny neurons (MSNs) which primarily express either D1-type or D2-type receptors;[20] about 1–2% of the remaining neuronal types are large aspiny cholinergic interneurons and another 1–2% are GABAergic interneurons.[20] Compared to the GABAergic MSNs in the shell, those in the core have an increased density of dendritic spines, branch segments, and terminal segments. From the core, the neurons project to other sub-cortical areas such as the globus pallidus and the substantia nigra. GABA is one of the main neurotransmitters in the NAcc, and GABA receptors are also abundant.[27][29] These neurons are also the main projection or output neurons of the nucleus accumbens.

Neurochemistry

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Some of the neurotransmitters, neuromodulators, and hormones that signal through receptors within the nucleus accumbens include:

Dopamine: Dopamine is released into the nucleus accumbens following exposure to rewarding stimuli, including recreational drugs like substituted amphetamines, cocaine, nicotine and morphine.[37][38]

Phenethylamine and tyramine: Phenethylamine and tyramine are trace amines which are synthesized in neurons that express the aromatic amino acid hydroxylase (AADC) enzyme, which includes all dopaminergic neurons.[39] Both compounds function as dopaminergic neuromodulators which regulate the reuptake and release of dopamine into the Nacc via interactions with VMAT2 and TAAR1 in the axon terminal of mesolimbic dopamine neurons.

Glucocorticoids and dopamine: Glucocorticoid receptors are the only corticosteroid receptors in the nucleus accumbens shell. L-DOPA, steroids, and specifically glucocorticoids are currently known to be the only known endogenous compounds that can induce psychotic problems, so understanding the hormonal control over dopaminergic projections with regard to glucocorticoid receptors could lead to new treatments for psychotic symptoms. A recent study demonstrated that suppression of the glucocorticoid receptors led to a decrease in the release of dopamine, which may lead to future research involving anti-glucocorticoid drugs to potentially relieve psychotic symptoms.[40]

GABA: A recent study on rats that used GABA agonists and antagonists indicated that GABAA receptors in the NAcc shell have inhibitory control on turning behavior influenced by dopamine, and GABAB receptors have inhibitory control over turning behavior mediated by acetylcholine.[27][41]

Glutamate: Studies have shown that local blockade of glutamatergic NMDA receptors in the NAcc core impaired spatial learning.[42] Another study demonstrated that both NMDA and AMPA (both glutamate receptors) play important roles in regulating instrumental learning.[43]

Serotonin (5-HT): Overall, 5-HT synapses are more abundant and have a greater number of synaptic contacts in the NAcc shell than in the core. They are also larger and thicker, and contain more large dense core vesicles than their counterparts in the core.

Function

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Reward and reinforcement

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The nucleus accumbens, being one part of the reward system, plays an important role in processing rewarding stimuli, reinforcing stimuli (e.g., food and water), and those which are both rewarding and reinforcing (addictive drugs, sex, and exercise).[4][44] The predominant response of neurons in the nucleus accumbens to the reward sucrose is inhibition; the opposite is true in response to the administration of aversive quinine.[45] Substantial evidence from pharmacological manipulation also suggests that reducing the excitability of neurons in the nucleus accumbens is rewarding, as, for example, would be true in the case of μ-opioid receptor stimulation.[46] The blood oxygen level dependent signal (BOLD) in the nucleus accumbens is selectively increased during the perception of pleasant, emotionally arousing pictures and during mental imagery of pleasant, emotional scenes. However, as BOLD is thought to be an indirect measure of regional net excitation to inhibition, the extent to which BOLD measures valence dependent processing is unknown.[47][48] Because of the abundance of NAcc inputs from limbic regions and strong NAcc outputs to motor regions, the nucleus accumbens has been described by Gordon Mogensen as the interface between the limbic and motor system.[49][50]

 
Tuning of appetitive and defensive reactions in the nucleus accumbens shell. (Above) AMPA blockade requires D1 function in order to produce motivated behaviors, regardless of valence, and D2 function to produce defensive behaviors. GABA agonism, on the other hand, does not require dopamine receptor function.(Below)The expansion of the anatomical regions that produce defensive behaviors under stress, and appetitive behaviors in the home environment produced by AMPA antagonism. This flexibility is less evident with GABA agonism.[51]

The nucleus accumbens is causally related to the experience of pleasure. Microinjections of μ-opioid agonists, δ-opioid agonists or κ-opioid agonists in the rostrodorsal quadrant of the medial shell enhance "liking", while more caudal injections can inhibit disgust reactions, liking reactions, or both.[30] The regions of the nucleus accumbens that can be ascribed a causal role in the production of pleasure are limited both anatomically and chemically, as besides opioid agonists only endocannabinoids can enhance liking. In the nucleus accumbens as a whole, dopamine, GABA receptor agonist or AMPA antagonists solely modify motivation, while the same is true for opioid and endocannabinoids outside of the hotspot in the medial shell. A rostro-caudal gradient exists for the enhancement of appetitive versus fearful responses, the latter of which is traditionally thought to require only D1 receptor function, and the former of which requires both D1 and D2 function. One interpretation of this finding, the disinhibition hypothesis, posits that inhibition of accumbens MSNs (which are GABAergic) disinhibits downstream structures, enabling the expression of appetitive or consummatory behaviors.[52] The motivational effects of AMPA antagonists, and to a lesser extent GABA agonists, is anatomically flexible. Stressful conditions can expand the fear inducing regions, while a familiar environment can reduce the size of the fear inducing region. Furthermore, cortical input from the orbitofrontal cortex (OFC) biases the response towards that of appetitive behavior, and infralimbic input, equivalent to the human subgenual cingulate cortex, suppresses the response regardless of valence.[30]

The nucleus accumbens is neither necessary nor sufficient for instrumental learning, although manipulations can affect performance on instrumental learning tasks. One task where the effect of NAcc lesions is evident is Pavlovian-instrumental transfer (PIT), where a cue paired with a specific or general reward can enhance instrumental responding. Lesions to the core of the NAcc impair performance after devaluation and inhibit the effect of general PIT. On the other hand, lesions to the shell only impair the effect of specific PIT. This distinction is thought to reflect consummatory and appetitive conditioned responses in the NAcc shell and the NAcc core, respectively.[53]

In the dorsal striatum, a dichotomy has been observed between D1-MSNs and D2-MSNs, with the former being reinforcing and enhancing locomotion, and the latter being aversive and reducing locomotion. Such a distinction has been traditionally assumed to apply to the nucleus accumbens as well, but evidence from pharmacological and optogenetics studies is conflicting. Furthermore, a subset of NAcc MSNs express both D1 and D2 MSNs, and pharmacological activation of D1 versus D2 receptors need not necessarily activate the neural populations exactly. While most studies show no effect of selective optogenetic stimulation of D1 or D2 MSNs on locomotor activity, one study has reported a decrease in basal locomotion with D2-MSN stimulation. While two studies have reported reduced reinforcing effects of cocaine with D2-MSN activation, one study has reported no effect. NAcc D2-MSN activation has also been reported to enhance motivation, as assessed by PIT, and D2 receptor activity is necessary for the reinforcing effects of VTA stimulation.[54] A 2018 study reported that D2 MSN activation enhanced motivation via inhibiting the ventral pallidum, thereby disinhibiting the VTA.[55]

Maternal behavior

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An fMRI study conducted in 2005 found that when mother rats were in the presence of their pups the regions of the brain involved in reinforcement, including the nucleus accumbens, were highly active.[56] Levels of dopamine increase in the nucleus accumbens during maternal behavior, while lesions in this area upset maternal behavior.[57] When women are presented pictures of unrelated infants, fMRIs show increased brain activity in the nucleus accumbens and adjacent caudate nucleus, proportionate to the degree to which the women find these infants "cute".[58]

Aversion

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Activation of D1-type MSNs in the nucleus accumbens is involved in reward, whereas the activation of D2-type MSNs in the nucleus accumbens promotes aversion.[6]

Slow-wave sleep

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In late 2017, studies on rodents which utilized optogenetic and chemogenetic methods found that the indirect pathway (i.e., D2-type) medium spiny neurons in the nucleus accumbens core which co-express adenosine A2A receptors and project to the ventral pallidum are involved in the regulation of slow-wave sleep.[11][12][13][14] In particular, optogenetic activation of these indirect pathway NAcc core neurons induces slow-wave sleep and chemogenetic activation of the same neurons increases the number and duration of slow-wave sleep episodes.[12][13][14] Chemogenetic inhibition of these NAcc core neurons suppresses sleep.[12][13] In contrast, the D2-type medium spiny neurons in the NAcc shell which express adenosine A2A receptors have no role in regulating slow-wave sleep.[12][13]

Clinical significance

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Addiction

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Current models of addiction from chronic drug use involve alterations in gene expression in the mesocorticolimbic projection.[20][59][60] The most important transcription factors that produce these alterations are ΔFosB, cyclic adenosine monophosphate (cAMP) response element binding protein (CREB), and nuclear factor kappa B (NFκB).[20] ΔFosB is the most significant gene transcription factor in addiction since its viral or genetic overexpression in the nucleus accumbens is necessary and sufficient for many of the neural adaptations and behavioral effects (e.g., expression-dependent increases in self-administration and reward sensitization) seen in drug addiction.[20][35][61] ΔFosB overexpression has been implicated in addictions to alcohol (ethanol), cannabinoids, cocaine, methylphenidate, nicotine, opioids, phencyclidine, propofol, and substituted amphetamines, among others.[20][59][61][62][63] Increases in nucleus accumbens ΔJunD expression can reduce or, with a large increase, even block most of the neural alterations seen in chronic drug abuse (i.e., the alterations mediated by ΔFosB).[20]

ΔFosB also plays an important role in regulating behavioral responses to natural rewards, such as palatable food, sex, and exercise.[20][21] Natural rewards, like drugs of abuse, induce ΔFosB in the nucleus accumbens, and chronic acquisition of these rewards can result in a similar pathological addictive state through ΔFosB overexpression.[20][21][44] Consequently, ΔFosB is the key transcription factor involved in addictions to natural rewards as well;[20][21][44] in particular, ΔFosB in the nucleus accumbens is critical for the reinforcing effects of sexual reward.[21] Research on the interaction between natural and drug rewards suggests that psychostimulants and sexual behavior act on similar biomolecular mechanisms to induce ΔFosB in the nucleus accumbens and possess cross-sensitization effects that are mediated through ΔFosB.[44][64]

Similar to drug rewards, non-drug rewards also increase the level of extracellular dopamine in the NAcc shell. Drug-induced dopamine release in the NAcc shell and NAcc core is usually not prone to habituation (i.e., the development of drug tolerance: a decrease in dopamine release from future drug exposure as a result of repeated drug exposure); on the contrary, repeated exposure to drugs that induce dopamine release in the NAcc shell and core typically results in sensitization (i.e., the amount of dopamine that is released in the NAcc from future drug exposure increases as a result of repeated drug exposure). Sensitization of dopamine release in the NAcc shell following repeated drug exposure serves to strengthen stimulus-drug associations (i.e., classical conditioning that occurs when drug use is repeatedly paired with environmental stimuli) and these associations become less prone to extinction (i.e., "unlearning" these classically conditioned associations between drug use and environmental stimuli becomes more difficult). After repeated pairing, these classically conditioned environmental stimuli (e.g., contexts and objects that are frequently paired with drug use) often become drug cues which function as secondary reinforcers of drug use (i.e., once these associations are established, exposure to a paired environmental stimulus triggers a craving or desire to use the drug which they've become associated with).[27][38]

In contrast to drugs, the release of dopamine in the NAcc shell by many types of rewarding non-drug stimuli typically undergoes habituation following repeated exposure (i.e., the amount of dopamine that is released from future exposure to a rewarding non-drug stimulus normally decreases as a result of repeated exposure to that stimulus).[27][38]

Summary of addiction-related plasticity
Form of neuroplasticity
or behavioral plasticity
Type of reinforcer Sources
Opiates Psychostimulants High fat or sugar food Sexual intercourse Physical exercise
(aerobic)
Environmental
enrichment
ΔFosB expression in
nucleus accumbens D1-type MSNsTooltip medium spiny neurons
[44]
Behavioral plasticity
Escalation of intake Yes Yes Yes [44]
Psychostimulant
cross-sensitization
Yes Not applicable Yes Yes Attenuated Attenuated [44]
Psychostimulant
self-administration
[44]
Psychostimulant
conditioned place preference
[44]
Reinstatement of drug-seeking behavior [44]
Neurochemical plasticity
CREBTooltip cAMP response element-binding protein phosphorylation
in the nucleus accumbens
[44]
Sensitized dopamine response
in the nucleus accumbens
No Yes No Yes [44]
Altered striatal dopamine signaling DRD2, ↑DRD3 DRD1, ↓DRD2, ↑DRD3 DRD1, ↓DRD2, ↑DRD3 DRD2 DRD2 [44]
Altered striatal opioid signaling No change or
μ-opioid receptors
μ-opioid receptors
κ-opioid receptors
μ-opioid receptors μ-opioid receptors No change No change [44]
Changes in striatal opioid peptides dynorphin
No change: enkephalin
dynorphin enkephalin dynorphin dynorphin [44]
Mesocorticolimbic synaptic plasticity
Number of dendrites in the nucleus accumbens [44]
Dendritic spine density in
the nucleus accumbens
[44]

Depression

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In April 2007, two research teams reported on having inserted electrodes into the nucleus accumbens in order to use deep brain stimulation to treat severe depression.[65] In 2010, experiments reported that deep brain stimulation of the nucleus accumbens was successful in decreasing depression symptoms in 50% of patients who did not respond to other treatments such as electroconvulsive therapy.[66] Nucleus accumbens has also been used as a target to treat small groups of patients with therapy-refractory obsessive-compulsive disorder.[67]

Ablation

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To treat addiction and in an attempt to treat mental illness radiofrequency ablation of the nucleus accumbens has been performed. The results are inconclusive and controversial.[68][69]

Placebo effect

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Activation of the NAcc has been shown to occur in the anticipation of effectiveness of a drug when a user is given a placebo, indicating a contributing role of the nucleus accumbens in the placebo effect.[16][70]

Additional images

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See also

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References

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  1. ^ a b Carlson NR (2013). Physiology of Behavior (11th ed.). Boston: Pearson. [page needed]
  2. ^ Nucleus Accumbens
  3. ^ Ikemoto S (November 2010). "Brain reward circuitry beyond the mesolimbic dopamine system: a neurobiological theory". Neuroscience and Biobehavioral Reviews. 35 (2): 129–50. doi:10.1016/j.neubiorev.2010.02.001. PMC 2894302. PMID 20149820. Recent studies on intracranial self-administration of neurochemicals (drugs) found that rats learn to self-administer various drugs into the mesolimbic dopamine structures–the posterior ventral tegmental area, medial shell nucleus accumbens and medial olfactory tubercle. ... In the 1970s it was recognized that the olfactory tubercle contains a striatal component, which is filled with GABAergic medium spiny neurons receiving glutamatergic inputs form cortical regions and dopaminergic inputs from the VTA and projecting to the ventral pallidum just like the nucleus accumbens
    Figure 3: The ventral striatum and self-administration of amphetamine
  4. ^ a b c d e f g h i j Malenka RC, Nestler EJ, Hyman SE (2009). Sydor A, Brown RY (eds.). Molecular Neuropharmacology: A Foundation for Clinical Neuroscience (2nd ed.). New York: McGraw-Hill Medical. pp. 147–148, 367, 376. ISBN 978-0-07-148127-4. VTA DA neurons play a critical role in motivation, reward-related behavior (Chapter 15), attention, and multiple forms of memory. This organization of the DA system, wide projection from a limited number of cell bodies, permits coordinated responses to potent new rewards. Thus, acting in diverse terminal fields, dopamine confers motivational salience ("wanting") on the reward itself or associated cues (nucleus accumbens shell region), updates the value placed on different goals in light of this new experience (orbital prefrontal cortex), helps consolidate multiple forms of memory (amygdala and hippocampus), and encodes new motor programs that will facilitate obtaining this reward in the future (nucleus accumbens core region and dorsal striatum). In this example, dopamine modulates the processing of sensorimotor information in diverse neural circuits to maximize the ability of the organism to obtain future rewards. ...
    The brain reward circuitry that is targeted by addictive drugs normally mediates the pleasure and strengthening of behaviors associated with natural reinforcers, such as food, water, and sexual contact. Dopamine neurons in the VTA are activated by food and water, and dopamine release in the NAc is stimulated by the presence of natural reinforcers, such as food, water, or a sexual partner. ...
    The NAc and VTA are central components of the circuitry underlying reward and memory of reward. As previously mentioned, the activity of dopaminergic neurons in the VTA appears to be linked to reward prediction. The NAc is involved in learning associated with reinforcement and the modulation of motoric responses to stimuli that satisfy internal homeostatic needs. The shell of the NAc appears to be particularly important to initial drug actions within reward circuitry; addictive drugs appear to have a greater effect on dopamine release in the shell than in the core of the NAc.
  5. ^ a b c Saddoris MP, Cacciapaglia F, Wightman RM, Carelli RM (August 2015). "Differential Dopamine Release Dynamics in the Nucleus Accumbens Core and Shell Reveal Complementary Signals for Error Prediction and Incentive Motivation". The Journal of Neuroscience. 35 (33): 11572–82. doi:10.1523/JNEUROSCI.2344-15.2015. PMC 4540796. PMID 26290234. Here, we have found that real-time dopamine release within the nucleus accumbens (a primary target of midbrain dopamine neurons) strikingly varies between core and shell subregions. In the core, dopamine dynamics are consistent with learning-based theories (such as reward prediction error) whereas in the shell, dopamine is consistent with motivation-based theories (e.g., incentive salience).
  6. ^ a b c Calipari ES, Bagot RC, Purushothaman I, Davidson TJ, Yorgason JT, Peña CJ, Walker DM, Pirpinias ST, Guise KG, Ramakrishnan C, Deisseroth K, Nestler EJ (March 2016). "In vivo imaging identifies temporal signature of D1 and D2 medium spiny neurons in cocaine reward". Proceedings of the National Academy of Sciences of the United States of America. 113 (10): 2726–31. Bibcode:2016PNAS..113.2726C. doi:10.1073/pnas.1521238113. PMC 4791010. PMID 26831103. Increased activity of the mesolimbic dopamine system is a central mechanism underlying the reinforcing and rewarding actions of drugs of abuse, including cocaine, as well as the compulsive drug seeking that develops over time and characterizes an addicted state (10–12). Dopamine action in NAc is mediated predominantly via activation of D1 or D2 dopamine receptors that are expressed by largely nonoverlapping populations of medium spiny neurons (MSNs) (13). These two subtypes of MSNs exert opposite effects on behavior, with optogenetic activation of D1-type neurons promoting positive reinforcement and increasing the formation of cocaine reward–context associations and activation of D2-type neurons being aversive and decreasing cocaine reward (14, 15); related differences in behavioral responses are seen in response to D1 vs. D2 receptor agonists or antagonists (16). ... Previous work has demonstrated that optogenetically stimulating D1 MSNs promotes reward, whereas stimulating D2 MSNs produces aversion.
  7. ^ Wenzel JM, Rauscher NA, Cheer JF, Oleson EB (January 2015). "A role for phasic dopamine release within the nucleus accumbens in encoding aversion: a review of the neurochemical literature". ACS Chemical Neuroscience. 6 (1): 16–26. doi:10.1021/cn500255p. PMC 5820768. PMID 25491156. Thus, fear-evoking stimuli are capable of differentially altering phasic dopamine transmission across NAcc subregions. The authors propose that the observed enhancement in NAcc shell dopamine likely reflects general motivational salience, perhaps due to relief from a CS-induced fear state when the US (foot shock) is not delivered. This reasoning is supported by a report from Budygin and colleagues112 showing that, in anesthetized rats, the termination of tail pinch results in augmented dopamine release in the shell.
  8. ^ a b Malenka RC, Nestler EJ, Hyman SE (2009). "Chapter 10: Neural and Neuroendocrine Control of the Internal Milieu". In Sydor A, Brown RY (eds.). Molecular Neuropharmacology: A Foundation for Clinical Neuroscience (2nd ed.). New York: McGraw-Hill Medical. p. 266. ISBN 978-0-07-148127-4. Dopamine acts in the nucleus accumbens to attach motivational significance to stimuli associated with reward.
  9. ^ a b c Salamone JD, Pardo M, Yohn SE, López-Cruz L, SanMiguel N, Correa M (2016). "Mesolimbic Dopamine and the Regulation of Motivated Behavior". Current Topics in Behavioral Neurosciences. 27: 231–57. doi:10.1007/7854_2015_383. ISBN 978-3-319-26933-7. PMID 26323245. Considerable evidence indicates that accumbens DA is important for Pavlovian approach and Pavlovian-to-instrumental transfer [(PIT)] ... PIT is a behavioral process that reflects the impact of Pavlovian-conditioned stimuli (CS) on instrumental responding. For example, presentation of a Pavlovian CS paired with food can increase output of food-reinforced instrumental behaviors, such as lever pressing. Outcome-specific PIT occurs when the Pavlovian unconditioned stimulus (US) and the instrumental reinforcer are the same stimulus, whereas general PIT is said to occur when the Pavlovian US and the reinforcer are different. ... More recent evidence indicates that accumbens core and shell appear to mediate different aspects of PIT; shell lesions and inactivation reduced outcome-specific PIT, while core lesions and inactivation suppressed general PIT (Corbit and Balleine 2011). These core versus shell differences are likely due to the different anatomical inputs and pallidal outputs associated with these accumbens subregions (Root et al. 2015). These results led Corbit and Balleine (2011) to suggest that accumbens core mediates the general excitatory effects of reward-related cues. PIT provides a fundamental behavioral process by which conditioned stimuli can exert activating effects upon instrumental responding
  10. ^ a b c Corbit LH, Balleine BW (2016). "Learning and Motivational Processes Contributing to Pavlovian-Instrumental Transfer and Their Neural Bases: Dopamine and Beyond". Current Topics in Behavioral Neurosciences. 27: 259–89. doi:10.1007/7854_2015_388. ISBN 978-3-319-26933-7. PMID 26695169. Such effects suggest that specific motivational states gate the arousing effects of Pavlovian incentives processes on instrumental performance ... Behavioral findings are supported by evidence that distinct neural circuits centered on the NAc core and shell mediate the general and specific forms of transfer, respectively, and ongoing work is beginning to explain how Pavlovian and instrumental learning processes that occur independently and at separate times are integrated within neural circuits that govern behavioral control.
  11. ^ a b c d Cherasse Y, Urade Y (November 2017). "Dietary Zinc Acts as a Sleep Modulator". International Journal of Molecular Sciences. 18 (11): 2334. doi:10.3390/ijms18112334. PMC 5713303. PMID 29113075. More recently, Fuller's laboratory also discovered that sleep can be promoted by the activation of a gamma-aminobutyric acid-ergic (GABAergic) population of neurons located in the parafacial zone [11,12], while the role of the GABAergic A2AR-expressing neurons of the nucleus accumbens [13] and the striatum has just been revealed [14,15].
  12. ^ a b c d e f g Valencia Garcia S, Fort P (February 2018). "Nucleus Accumbens, a new sleep-regulating area through the integration of motivational stimuli". Acta Pharmacologica Sinica. 39 (2): 165–166. doi:10.1038/aps.2017.168. PMC 5800466. PMID 29283174. The nucleus accumbens comprises a contingent of neurons specifically expressing the post-synaptic A2A-receptor (A2AR) subtype making them excitable by adenosine, its natural agonist endowed with powerful sleep-promoting properties[4]. ... In both cases, large activation of A2AR-expressing neurons in NAc promotes slow wave sleep (SWS) by increasing the number and duration of episodes. ... After optogenetic activation of the core, a similar promotion of SWS was observed, whereas no significant effects were induced when activating A2AR-expressing neurons within the shell.
  13. ^ a b c d e f g Oishi Y, Xu Q, Wang L, Zhang BJ, Takahashi K, Takata Y, Luo YJ, Cherasse Y, Schiffmann SN, de Kerchove d'Exaerde A, Urade Y, Qu WM, Huang ZL, Lazarus M (September 2017). "Slow-wave sleep is controlled by a subset of nucleus accumbens core neurons in mice". Nature Communications. 8 (1): 734. Bibcode:2017NatCo...8..734O. doi:10.1038/s41467-017-00781-4. PMC 5622037. PMID 28963505. Here, we show that chemogenetic or optogenetic activation of excitatory adenosine A2A receptor-expressing indirect pathway neurons in the core region of the NAc strongly induces slow-wave sleep. Chemogenetic inhibition of the NAc indirect pathway neurons prevents the sleep induction, but does not affect the homoeostatic sleep rebound.
  14. ^ a b c Yuan XS, Wang L, Dong H, Qu WM, Yang SR, Cherasse Y, Lazarus M, Schiffmann SN, d'Exaerde AK, Li RX, Huang ZL (October 2017). "2A receptor neurons control active-period sleep via parvalbumin neurons in external globus pallidus". eLife. 6: e29055. doi:10.7554/eLife.29055. PMC 5655138. PMID 29022877.
  15. ^ Schwienbacher I, Fendt M, Richardson R, Schnitzler HU (November 2004). "Temporary inactivation of the nucleus accumbens disrupts acquisition and expression of fear-potentiated startle in rats". Brain Research. 1027 (1–2): 87–93. doi:10.1016/j.brainres.2004.08.037. PMID 15494160. S2CID 18338111.
  16. ^ a b Zubieta JK, Stohler CS (March 2009). "Neurobiological mechanisms of placebo responses". Annals of the New York Academy of Sciences. 1156 (1): 198–210. Bibcode:2009NYASA1156..198Z. doi:10.1111/j.1749-6632.2009.04424.x. PMC 3073412. PMID 19338509.
  17. ^ Basar K, Sesia T, Groenewegen H, Steinbusch HW, Visser-Vandewalle V, Temel Y (December 2010). "Nucleus accumbens and impulsivity". Progress in Neurobiology. 92 (4): 533–57. doi:10.1016/j.pneurobio.2010.08.007. PMID 20831892. S2CID 16964212.
  18. ^ Gipson CD, Kupchik YM, Kalivas PW (January 2014). "Rapid, transient synaptic plasticity in addiction". Neuropharmacology. 76 Pt B: 276–86. doi:10.1016/j.neuropharm.2013.04.032. PMC 3762905. PMID 23639436. Within a simplified PFC-NAc-VTA circuit, the NAc serves as a "gateway" through which information regarding the direction of behavioral output is processed from limbic cortex to motor subcircuits. It is thought that the transition to compulsive drug seeking arises from an impaired ability of this subcircuit to effectively process information about negative environmental contingencies, leading to an inability to inhibit prepotent drug-associated responses; thereby the addict is rendered prone to relapse.
    Figure 1: Glutamatergic afferents to the nucleus accumbens involved in addictive behavior
  19. ^ a b c Yager LM, Garcia AF, Wunsch AM, Ferguson SM (August 2015). "The ins and outs of the striatum: Role in drug addiction". Neuroscience. 301: 529–541. doi:10.1016/j.neuroscience.2015.06.033. PMC 4523218. PMID 26116518. [The striatum] receives dopaminergic inputs from the ventral tegmental area (VTA) and the substantia nigra (SNr) and glutamatergic inputs from several areas, including the cortex, hippocampus, amygdala, and thalamus (Swanson, 1982; Phillipson and Griffiths, 1985; Finch, 1996; Groenewegen et al., 1999; Britt et al., 2012). These glutamatergic inputs make contact on the heads of dendritic spines of the striatal GABAergic medium spiny projection neurons (MSNs) whereas dopaminergic inputs synapse onto the spine neck, allowing for an important and complex interaction between these two inputs in modulation of MSN activity ... It should also be noted that there is a small population of neurons in the NAc that coexpress both D1 and D2 receptors, though this is largely restricted to the NAc shell (Bertran- Gonzalez et al., 2008). ... Neurons in the NAc core and NAc shell subdivisions also differ functionally. The NAc core is involved in the processing of conditioned stimuli whereas the NAc shell is more important in the processing of unconditioned stimuli; Classically, these two striatal MSN populations are thought to have opposing effects on basal ganglia output. Activation of the dMSNs causes a net excitation of the thalamus resulting in a positive cortical feedback loop; thereby acting as a 'go' signal to initiate behavior. Activation of the iMSNs, however, causes a net inhibition of thalamic activity resulting in a negative cortical feedback loop and therefore serves as a 'brake' to inhibit behavior ... there is also mounting evidence that iMSNs play a role in motivation and addiction (Lobo and Nestler, 2011; Grueter et al., 2013). ... Together these data suggest that iMSNs normally act to restrain drug-taking behavior and recruitment of these neurons may in fact be protective against the development of compulsive drug use.
  20. ^ a b c d e f g h i j k Robison AJ, Nestler EJ (October 2011). "Transcriptional and epigenetic mechanisms of addiction". Nature Reviews. Neuroscience. 12 (11): 623–37. doi:10.1038/nrn3111. PMC 3272277. PMID 21989194. ΔFosB has been linked directly to several addiction-related behaviors ... Importantly, genetic or viral overexpression of ΔJunD, a dominant negative mutant of JunD which antagonizes ΔFosB- and other AP-1-mediated transcriptional activity, in the NAc or OFC blocks these key effects of drug exposure14,22–24. This indicates that ΔFosB is both necessary and sufficient for many of the changes wrought in the brain by chronic drug exposure. ΔFosB is also induced in D1-type NAc MSNs by chronic consumption of several natural rewards, including sucrose, high fat food, sex, wheel running, where it promotes that consumption14,26–30. This implicates ΔFosB in the regulation of natural rewards under normal conditions and perhaps during pathological addictive-like states. ... 95% of NAc neurons are GABAergic MSNs (medium spiny neurons), which can be further differentiated into those MSNs that express the D1 dopamine receptor (D1-type MSNs) and express dynorphin and substance P and those that express the D2 dopamine receptor (D2-type MSNs) and express enkephalin132. Drug induction of ΔFosB133,134, and the effects of ΔFosB and G9a on cell morphology and behavior, differ between D1-type and D2-type MSNs135, and neuronal activity of these two cell types causes opposing effects on the rewarding properties of cocaine131. ... About 1–2% of NAc neurons are aspiny large cholinergic interneurons, which have been shown to play an important role in cocaine reward130, and a similar number are GABAergic interneurons, the function of which are less well understood.
  21. ^ a b c d e Blum K, Werner T, Carnes S, Carnes P, Bowirrat A, Giordano J, Oscar-Berman M, Gold M (2012). "Sex, drugs, and rock 'n' roll: hypothesizing common mesolimbic activation as a function of reward gene polymorphisms". Journal of Psychoactive Drugs. 44 (1): 38–55. doi:10.1080/02791072.2012.662112. PMC 4040958. PMID 22641964. It has been found that deltaFosB gene in the NAc is critical for reinforcing effects of sexual reward. Pitchers and colleagues (2010) reported that sexual experience was shown to cause DeltaFosB accumulation in several limbic brain regions including the NAc, medial pre-frontal cortex, VTA, caudate, and putamen, but not the medial preoptic nucleus. Next, the induction of c-Fos, a downstream (repressed) target of DeltaFosB, was measured in sexually experienced and naive animals. The number of mating-induced c-Fos-IR cells was significantly decreased in sexually experienced animals compared to sexually naive controls. Finally, DeltaFosB levels and its activity in the NAc were manipulated using viral-mediated gene transfer to study its potential role in mediating sexual experience and experience-induced facilitation of sexual performance. Animals with DeltaFosB overexpression displayed enhanced facilitation of sexual performance with sexual experience relative to controls. In contrast, the expression of DeltaJunD, a dominant-negative binding partner of DeltaFosB, attenuated sexual experience-induced facilitation of sexual performance, and stunted long-term maintenance of facilitation compared to DeltaFosB overexpressing group. Together, these findings support a critical role for DeltaFosB expression in the NAc in the reinforcing effects of sexual behavior and sexual experience-induced facilitation of sexual performance. ... both drug addiction and sexual addiction represent pathological forms of neuroplasticity along with the emergence of aberrant behaviors involving a cascade of neurochemical changes mainly in the brain's rewarding circuitry.
  22. ^ Goto Y, O'Donnell P (February 2001). "Synchronous activity in the hippocampus and nucleus accumbens in vivo". The Journal of Neuroscience. 21 (4): RC131. doi:10.1523/jneurosci.21-04-j0003.2001. PMC 6762233. PMID 11160416.
  23. ^ Malenka RC, Nestler EJ, Hyman SE (2009). "Chapter 6: Widely Projecting Systems: Monoamines, Acetylcholine, and Orexin". In Sydor A, Brown RY (eds.). Molecular Neuropharmacology: A Foundation for Clinical Neuroscience (2nd ed.). New York: McGraw-Hill Medical. pp. 175–176. ISBN 978-0-07-148127-4. Within the brain, histamine is synthesized exclusively by neurons with their cell bodies in the tuberomammillary nucleus (TMN) that lies within the posterior hypothalamus. There are approximately 64000 histaminergic neurons per side in humans. These cells project throughout the brain and spinal cord. Areas that receive especially dense projections include the cerebral cortex, hippocampus, neostriatum, nucleus accumbens, amygdala, and hypothalamus.  ... While the best characterized function of the histamine system in the brain is regulation of sleep and arousal, histamine is also involved in learning and memory ... It also appears that histamine is involved in the regulation of feeding and energy balance.
  24. ^ Barrot M, Sesack SR, Georges F, Pistis M, Hong S, Jhou TC (October 2012). "Braking dopamine systems: a new GABA master structure for mesolimbic and nigrostriatal functions". The Journal of Neuroscience. 32 (41): 14094–101. doi:10.1523/JNEUROSCI.3370-12.2012. PMC 3513755. PMID 23055478.
  25. ^ Ferré S, Lluís C, Justinova Z, Quiroz C, Orru M, Navarro G, Canela EI, Franco R, Goldberg SR (June 2010). "Adenosine-cannabinoid receptor interactions. Implications for striatal function". Br. J. Pharmacol. 160 (3): 443–453. doi:10.1111/j.1476-5381.2010.00723.x. PMC 2931547. PMID 20590556. Two classes of MSNs, which are homogeneously distributed in the striatum, can be differentiated by their output connectivity and their expression of dopamine and adenosine receptors and neuropeptides. In the dorsal striatum (mostly represented by the nucleus caudate-putamen), enkephalinergic MSNs connect the striatum with the globus pallidus (lateral globus pallidus) and express the peptide enkephalin and a high density of dopamine D2 and adenosine A2A receptors (they also express adenosine A1 receptors), while dynorphinergic MSNs connect the striatum with the substantia nigra (pars compacta and reticulata) and the entopeduncular nucleus (medial globus pallidus) and express the peptides dynorphin and substance P and dopamine D1 and adenosine A1 but not A2A receptors ... These two different phenotypes of MSN are also present in the ventral striatum (mostly represented by the nucleus accumbens and the olfactory tubercle). However, although they are phenotypically equal to their dorsal counterparts, they have some differences in terms of connectivity. First, not only enkephalinergic but also dynorphinergic MSNs project to the ventral counterpart of the lateral globus pallidus, the ventral pallidum, which, in fact, has characteristics of both the lateral and medial globus pallidus in its afferent and efferent connectivity. In addition to the ventral pallidum, the medial globus pallidus and the substantia nigra-VTA, the ventral striatum sends projections to the extended amygdala, the lateral hypothalamus and the pedunculopontine tegmental nucleus. ... It is also important to mention that a small percentage of MSNs have a mixed phenotype and express both D1 and D2 receptors (Surmeier et al., 1996).
  26. ^ Nishi A, Kuroiwa M, Shuto T (July 2011). "Mechanisms for the modulation of dopamine d(1) receptor signaling in striatal neurons". Front Neuroanat. 5: 43. doi:10.3389/fnana.2011.00043. PMC 3140648. PMID 21811441. Dopamine plays critical roles in the regulation of psychomotor functions in the brain (Bromberg-Martin et al., 2010; Cools, 2011; Gerfen and Surmeier, 2011). The dopamine receptors are a superfamily of heptahelical G protein-coupled receptors, and are grouped into two categories, D1-like (D1, D5) and D2-like (D2, D3, D4) receptors, based on functional properties to stimulate adenylyl cyclase (AC) via Gs/olf and to inhibit AC via Gi/o, respectively ... It has been demonstrated that D1 receptors form the hetero-oligomer with D2 receptors, and that the D1–D2 receptor hetero-oligomer preferentially couples to Gq/PLC signaling (Rashid et al., 2007a,b). The expression of dopamine D1 and D2 receptors are largely segregated in direct and indirect pathway neurons in the dorsal striatum, respectively (Gerfen et al., 1990; Hersch et al., 1995; Heiman et al., 2008). However, some proportion of medium spiny neurons are known to expresses both D1 and D2 receptors (Hersch et al., 1995). Gene expression analysis using single cell RT-PCR technique estimated that 40% of medium spiny neurons express both D1 and D2 receptor mRNA (Surmeier et al., 1996).
  27. ^ a b c d e f Shirayama Y, Chaki S (October 2006). "Neurochemistry of the nucleus accumbens and its relevance to depression and antidepressant action in rodents". Current Neuropharmacology. 4 (4): 277–91. doi:10.2174/157015906778520773. PMC 2475798. PMID 18654637.
  28. ^ Meredith GE, Agolia R, Arts MP, Groenewegen HJ, Zahm DS (September 1992). "Morphological differences between projection neurons of the core and shell in the nucleus accumbens of the rat". Neuroscience. 50 (1): 149–62. doi:10.1016/0306-4522(92)90389-j. PMID 1383869. S2CID 11278705.
  29. ^ a b c Meredith GE, Pennartz CM, Groenewegen HJ (1993). "The cellular framework for chemical signalling in the nucleus accumbens". Chemical Signalling in the Basal Ganglia. Progress in Brain Research. Vol. 99. pp. 3–24. doi:10.1016/s0079-6123(08)61335-7. ISBN 978-0-444-81562-0. PMID 7906426.
  30. ^ a b c d Berridge KC, Kringelbach ML (May 2015). "Pleasure systems in the brain". Neuron. 86 (3): 646–64. doi:10.1016/j.neuron.2015.02.018. PMC 4425246. PMID 25950633.
  31. ^ Baliki MN, Mansour A, Baria AT, Huang L, Berger SE, Fields HL, Apkarian AV (October 2013). "Parceling human accumbens into putative core and shell dissociates encoding of values for reward and pain". The Journal of Neuroscience. 33 (41): 16383–93. doi:10.1523/JNEUROSCI.1731-13.2013. PMC 3792469. PMID 24107968. Recent evidence indicates that inactivation of D2 receptors, in the indirect striatopallidal pathway in rodents, is necessary for both acquisition and expression of aversive behavior, and direct pathway D1 receptor activation controls reward-based learning (Hikida et al., 2010; Hikida et al., 2013). It seems we can conclude that direct and indirect pathways of the NAc, via D1 and D2 receptors, subserve distinct anticipation and valuation roles in the shell and core of NAc, which is consistent with observations regarding spatial segregation and diversity of responses of midbrain dopaminergic neurons for rewarding and aversive conditions, some encoding motivational value, others motivational salience, each connected with distinct brain networks and having distinct roles in motivational control (Bromberg-Martin et al., 2010; Cohen et al., 2012; Lammel et al., 2013). ... Thus, the previous results, coupled with the current observations, imply that the NAc pshell response reflects a prediction/anticipation or salience signal, and the NAc pcore response is a valuation response (reward predictive signal) that signals the negative reinforcement value of cessation of pain (i.e., anticipated analgesia).
  32. ^ a b Cartoni E, Puglisi-Allegra S, Baldassarre G (November 2013). "The three principles of action: a Pavlovian-instrumental transfer hypothesis". Frontiers in Behavioral Neuroscience. 7: 153. doi:10.3389/fnbeh.2013.00153. PMC 3832805. PMID 24312025.
  33. ^ Richard JM, Castro DC, Difeliceantonio AG, Robinson MJ, Berridge KC (November 2013). "Mapping brain circuits of reward and motivation: in the footsteps of Ann Kelley". Neuroscience and Biobehavioral Reviews. 37 (9 Pt A): 1919–31. doi:10.1016/j.neubiorev.2012.12.008. PMC 3706488. PMID 23261404.
  34. ^ Berridge KC, Robinson TE, Aldridge JW (February 2009). "Dissecting components of reward: 'liking', 'wanting', and learning". Current Opinion in Pharmacology. 9 (1): 65–73. doi:10.1016/j.coph.2008.12.014. PMC 2756052. PMID 19162544.
  35. ^ a b Nestler EJ (December 2013). "Cellular basis of memory for addiction". Dialogues in Clinical Neuroscience. 15 (4): 431–43. doi:10.31887/DCNS.2013.15.4/enestler. PMC 3898681. PMID 24459410. DESPITE THE IMPORTANCE OF NUMEROUS PSYCHOSOCIAL FACTORS, AT ITS CORE, DRUG ADDICTION INVOLVES A BIOLOGICAL PROCESS: the ability of repeated exposure to a drug of abuse to induce changes in a vulnerable brain that drive the compulsive seeking and taking of drugs, and loss of control over drug use, that define a state of addiction. ... A large body of literature has demonstrated that such ΔFosB induction in D1-type NAc neurons increases an animal's sensitivity to drug as well as natural rewards and promotes drug self-administration, presumably through a process of positive reinforcement ... For example, the shell and core subregions of NAc display differences in drug-induced synaptic plasticity, as do D1- versus D2-type medium spiny neurons within each subregion.60,63,64,67
  36. ^ Dumitriu D, Laplant Q, Grossman YS, Dias C, Janssen WG, Russo SJ, Morrison JH, Nestler EJ (May 2012). "Subregional, dendritic compartment, and spine subtype specificity in cocaine regulation of dendritic spines in the nucleus accumbens". The Journal of Neuroscience. 32 (20): 6957–66. doi:10.1523/JNEUROSCI.5718-11.2012. PMC 3360066. PMID 22593064. The enduring spine density change in core but not shell fits well with the established idea that the shell is preferentially involved in the development of addiction, while the core mediates the long-term execution of learned addiction-related behaviors (Ito et al., 2004; Di Chiara, 2002; Meredith et al., 2008). Consistent with the idea of NAc core being the locus of long-lasting drug-induced neuroplasticity, several studies have shown that electrophysiological changes in core persist longer than their shell counterparts. ... Furthermore, data presented here support the idea that NAc shell is preferentially involved in immediate drug reward, while the core might play a more explicit role in longer-term aspects of addiction.
  37. ^ Pontieri FE, Tanda G, Di Chiara G (December 1995). "Intravenous cocaine, morphine, and amphetamine preferentially increase extracellular dopamine in the "shell" as compared with the "core" of the rat nucleus accumbens". Proceedings of the National Academy of Sciences of the United States of America. 92 (26): 12304–8. Bibcode:1995PNAS...9212304P. doi:10.1073/pnas.92.26.12304. JSTOR 2369093. PMC 40345. PMID 8618890.
  38. ^ a b c Di Chiara G (December 2002). "Nucleus accumbens shell and core dopamine: differential role in behavior and addiction". Behavioural Brain Research. 137 (1–2): 75–114. doi:10.1016/s0166-4328(02)00286-3. PMID 12445717. S2CID 54410118.
  39. ^ Eiden LE, Weihe E (January 2011). "VMAT2: a dynamic regulator of brain monoaminergic neuronal function interacting with drugs of abuse". Annals of the New York Academy of Sciences. 1216 (1): 86–98. Bibcode:2011NYASA1216...86E. doi:10.1111/j.1749-6632.2010.05906.x. PMC 4183197. PMID 21272013. VMAT2 is the CNS vesicular transporter for not only the biogenic amines DA, NE, EPI, 5-HT, and HIS, but likely also for the trace amines TYR, PEA, and thyronamine (THYR) ... [Trace aminergic] neurons in mammalian CNS would be identifiable as neurons expressing VMAT2 for storage, and the biosynthetic enzyme aromatic amino acid decarboxylase (AADC).
  40. ^ Barrot M, Marinelli M, Abrous DN, Rougé-Pont F, Le Moal M, Piazza PV (March 2000). "The dopaminergic hyper-responsiveness of the shell of the nucleus accumbens is hormone-dependent". The European Journal of Neuroscience. 12 (3): 973–9. doi:10.1046/j.1460-9568.2000.00996.x. PMID 10762327. S2CID 6111417.
  41. ^ Akiyama G, Ikeda H, Matsuzaki S, Sato M, Moribe S, Koshikawa N, Cools AR (June 2004). "GABAA and GABAB receptors in the nucleus accumbens shell differentially modulate dopamine and acetylcholine receptor-mediated turning behaviour". Neuropharmacology. 46 (8): 1082–8. doi:10.1016/j.neuropharm.2004.02.007. PMID 15111014. S2CID 25631633.
  42. ^ Smith-Roe SL, Sadeghian K, Kelley AE (August 1999). "Spatial learning and performance in the radial arm maze is impaired after N-methyl-D-aspartate (NMDA) receptor blockade in striatal subregions". Behavioral Neuroscience. 113 (4): 703–17. doi:10.1037/0735-7044.113.4.703. PMID 10495079.
  43. ^ Giertler C, Bohn I, Hauber W (March 2005). "Involvement of NMDA and AMPA/KA receptors in the nucleus accumbens core in instrumental learning guided by reward-predictive cues". The European Journal of Neuroscience. 21 (6): 1689–702. doi:10.1111/j.1460-9568.2005.03983.x. PMID 15845096. S2CID 14206373.
  44. ^ a b c d e f g h i j k l m n o p q Olsen CM (December 2011). "Natural rewards, neuroplasticity, and non-drug addictions". Neuropharmacology. 61 (7): 1109–22. doi:10.1016/j.neuropharm.2011.03.010. PMC 3139704. PMID 21459101. Cross-sensitization is also bidirectional, as a history of amphetamine administration facilitates sexual behavior and enhances the associated increase in NAc DA ... As described for food reward, sexual experience can also lead to activation of plasticity-related signaling cascades. The transcription factor delta FosB is increased in the NAc, PFC, dorsal striatum, and VTA following repeated sexual behavior (Wallace et al., 2008; Pitchers et al., 2010b). This natural increase in delta FosB or viral overexpression of delta FosB within the NAc modulates sexual performance, and NAc blockade of delta FosB attenuates this behavior (Hedges et al., 2009; Pitchers et al., 2010b). Further, viral overexpression of delta FosB enhances the conditioned place preference for an environment paired with sexual experience (Hedges et al., 2009). ...
    Table 1
  45. ^ Day JJ, Carelli RM (April 2007). "The nucleus accumbens and Pavlovian reward learning". The Neuroscientist. 13 (2): 148–59. doi:10.1177/1073858406295854. PMC 3130622. PMID 17404375. Consistent with other reports (Nicola and others 2004; Taha and Fields 2006), the predominant response of NAc neurons to sucrose infusions was a decrease in activity (Fig. 2). As is evident in Figure 2, the same neurons exhibited opposite responses when an aversive quinine solution was delivered intra-orally. One hypothesis suggests that inhibitions observed during reward delivery occur among GABA-containing NAc neurons that project to important motor areas such as the ventral pallidum (VP).
  46. ^ Carlezon WA, Thomas MJ (2009). "Biological substrates of reward and aversion: a nucleus accumbens activity hypothesis". Neuropharmacology. 56 (Suppl 1): 122–32. doi:10.1016/j.neuropharm.2008.06.075. PMC 2635333. PMID 18675281. When considered together, these studies provided two critical pieces of evidence that have played a prominent role in the formulation of our current working hypothesis: first, that dopamine-dependent reward is attenuated by blockade of D2-like receptors, which are inhibitory receptors expressed predominately in the NAc on the MSNs of the indirect pathway; and second, that events that would be expected to reduce the overall excitability of the NAc (e.g., stimulation of Gi-coupled opioid receptors, reduced stimulation of excitatory NMDA receptors, reduced excitatory input) are sufficient for reward. This interpretation led to the development of a model of reward in which the critical event is reduced activation of MSNs in the NAc
  47. ^ Costa VD, Lang PJ, Sabatinelli D, Versace F, Bradley MM (September 2010). "Emotional imagery: assessing pleasure and arousal in the brain's reward circuitry". Human Brain Mapping. 31 (9): 1446–57. doi:10.1002/hbm.20948. PMC 3620013. PMID 20127869.
  48. ^ Sabatinelli D, Bradley MM, Lang PJ, Costa VD, Versace F (September 2007). "Pleasure rather than salience activates human nucleus accumbens and medial prefrontal cortex". Journal of Neurophysiology. 98 (3): 1374–9. doi:10.1152/jn.00230.2007. PMID 17596422. S2CID 14938485.
  49. ^ Mogenson GJ, Jones DL, Yim CY (1980). "From motivation to action: functional interface between the limbic system and the motor system". Progress in Neurobiology. 14 (2–3): 69–97. doi:10.1016/0301-0082(80)90018-0. PMID 6999537. S2CID 14029796.
  50. ^ Hart G, Leung BK, Balleine BW (February 2014). "Dorsal and ventral streams: the distinct role of striatal subregions in the acquisition and performance of goal-directed actions". Neurobiology of Learning and Memory. 108: 104–18. doi:10.1016/j.nlm.2013.11.003. PMC 4661143. PMID 24231424.
  51. ^ Castro DC, Cole SL, Berridge KC (2015). "Lateral hypothalamus, nucleus accumbens, and ventral pallidum roles in eating and hunger: interactions between homeostatic and reward circuitry". Frontiers in Systems Neuroscience. 9: 90. doi:10.3389/fnsys.2015.00090. PMC 4466441. PMID 26124708.
  52. ^ Berridge KC, Kringelbach ML (June 2013). "Neuroscience of affect: brain mechanisms of pleasure and displeasure". Current Opinion in Neurobiology. 23 (3): 294–303. doi:10.1016/j.conb.2013.01.017. PMC 3644539. PMID 23375169.
  53. ^ Yin HH, Ostlund SB, Balleine BW (October 2008). "Reward-guided learning beyond dopamine in the nucleus accumbens: the integrative functions of cortico-basal ganglia networks". The European Journal of Neuroscience. 28 (8): 1437–48. doi:10.1111/j.1460-9568.2008.06422.x. PMC 2756656. PMID 18793321.
  54. ^ Soares-Cunha C, Coimbra B, Sousa N, Rodrigues AJ (September 2016). "Reappraising striatal D1- and D2-neurons in reward and aversion" (PDF). Neuroscience and Biobehavioral Reviews. 68: 370–386. doi:10.1016/j.neubiorev.2016.05.021. hdl:1822/47044. PMID 27235078. S2CID 207092810.
  55. ^ Soares-Cunha C, Coimbra B, Domingues AV, Vasconcelos N, Sousa N, Rodrigues AJ (19 April 2018). "Nucleus Accumbens Microcircuit Underlying D2-MSN-Driven Increase in Motivation". eNeuro. 5 (2): ENEURO.0386–18.2018. doi:10.1523/ENEURO.0386-18.2018. PMC 5957524. PMID 29780881. D2-MSN optogenetic activation decreased ventral pallidum (VP) activity, reducing the inhibitory tone to VTA, leading to increased dopaminergic activity. Importantly, optogenetic activation of D2-MSN terminals in the VP was sufficient to recapitulate the motivation enhancement
  56. ^ Ferris CF, Kulkarni P, Sullivan JM, Harder JA, Messenger TL, Febo M (January 2005). "Pup suckling is more rewarding than cocaine: evidence from functional magnetic resonance imaging and three-dimensional computational analysis". The Journal of Neuroscience. 25 (1): 149–56. arXiv:1510.02343. doi:10.1523/jneurosci.3156-04.2005. PMC 6725197. PMID 15634776.
  57. ^ Numan M (January 2007). "Motivational systems and the neural circuitry of maternal behavior in the rat". Developmental Psychobiology. 49 (1): 12–21. doi:10.1002/dev.20198. PMID 17186513.
  58. ^ Glocker ML, Langleben DD, Ruparel K, Loughead JW, Valdez JN, Griffin MD, Sachser N, Gur RC (June 2009). "Baby schema modulates the brain reward system in nulliparous women". Proceedings of the National Academy of Sciences of the United States of America. 106 (22): 9115–9. Bibcode:2009PNAS..106.9115G. doi:10.1073/pnas.0811620106. JSTOR 40482823. PMC 2690007. PMID 19451625.
  59. ^ a b Hyman SE, Malenka RC, Nestler EJ (2006). "Neural mechanisms of addiction: the role of reward-related learning and memory". Annual Review of Neuroscience. 29: 565–98. doi:10.1146/annurev.neuro.29.051605.113009. PMID 16776597.
  60. ^ Steiner H, Van Waes V (January 2013). "Addiction-related gene regulation: risks of exposure to cognitive enhancers vs. other psychostimulants". Progress in Neurobiology. 100: 60–80. doi:10.1016/j.pneurobio.2012.10.001. PMC 3525776. PMID 23085425.
  61. ^ a b Ruffle JK (November 2014). "Molecular neurobiology of addiction: what's all the (Δ)FosB about?". The American Journal of Drug and Alcohol Abuse. 40 (6): 428–37. doi:10.3109/00952990.2014.933840. PMID 25083822. S2CID 19157711. ΔFosB is an essential transcription factor implicated in the molecular and behavioral pathways of addiction following repeated drug exposure. The formation of ΔFosB in multiple brain regions, and the molecular pathway leading to the formation of AP-1 complexes is well understood. The establishment of a functional purpose for ΔFosB has allowed further determination as to some of the key aspects of its molecular cascades, involving effectors such as GluR2 (87,88), Cdk5 (93) and NFkB (100). Moreover, many of these molecular changes identified are now directly linked to the structural, physiological and behavioral changes observed following chronic drug exposure (60,95,97,102). New frontiers of research investigating the molecular roles of ΔFosB have been opened by epigenetic studies, and recent advances have illustrated the role of ΔFosB acting on DNA and histones, truly as a molecular switch (34).
  62. ^ Kanehisa Laboratories (29 October 2014). "Alcoholism – Homo sapiens (human)". KEGG Pathway. Retrieved 31 October 2014.
  63. ^ Kim Y, Teylan MA, Baron M, Sands A, Nairn AC, Greengard P (February 2009). "Methylphenidate-induced dendritic spine formation and DeltaFosB expression in nucleus accumbens". Proceedings of the National Academy of Sciences of the United States of America. 106 (8): 2915–20. Bibcode:2009PNAS..106.2915K. doi:10.1073/pnas.0813179106. PMC 2650365. PMID 19202072.
  64. ^ Pitchers KK, Vialou V, Nestler EJ, Laviolette SR, Lehman MN, Coolen LM (February 2013). "Natural and drug rewards act on common neural plasticity mechanisms with ΔFosB as a key mediator". The Journal of Neuroscience. 33 (8): 3434–42. doi:10.1523/JNEUROSCI.4881-12.2013. PMC 3865508. PMID 23426671. Drugs of abuse induce neuroplasticity in the natural reward pathway, specifically the nucleus accumbens (NAc), thereby causing development and expression of addictive behavior. ... Together, these findings demonstrate that drugs of abuse and natural reward behaviors act on common molecular and cellular mechanisms of plasticity that control vulnerability to drug addiction, and that this increased vulnerability is mediated by ΔFosB and its downstream transcriptional targets. ... Sexual behavior is highly rewarding (Tenk et al., 2009), and sexual experience causes sensitized drug-related behaviors, including cross-sensitization to amphetamine (Amph)-induced locomotor activity (Bradley and Meisel, 2001; Pitchers et al., 2010a) and enhanced Amph reward (Pitchers et al., 2010a). Moreover, sexual experience induces neural plasticity in the NAc similar to that induced by psychostimulant exposure, including increased dendritic spine density (Meisel and Mullins, 2006; Pitchers et al., 2010a), altered glutamate receptor trafficking, and decreased synaptic strength in prefrontal cortex-responding NAc shell neurons (Pitchers et al., 2012). Finally, periods of abstinence from sexual experience were found to be critical for enhanced Amph reward, NAc spinogenesis (Pitchers et al., 2010a), and glutamate receptor trafficking (Pitchers et al., 2012). These findings suggest that natural and drug reward experiences share common mechanisms of neural plasticity
  65. ^ Brain Electrodes Help Treat Depression Archived 16 March 2012 at the Wayback Machine, Technology Review, 26 April 2007
  66. ^ Bewernick BH, Hurlemann R, Matusch A, Kayser S, Grubert C, Hadrysiewicz B, Axmacher N, Lemke M, Cooper-Mahkorn D, Cohen MX, Brockmann H, Lenartz D, Sturm V, Schlaepfer TE (January 2010). "Nucleus accumbens deep brain stimulation decreases ratings of depression and anxiety in treatment-resistant depression". Biological Psychiatry. 67 (2): 110–6. doi:10.1016/j.biopsych.2009.09.013. PMID 19914605. S2CID 26242126.
  67. ^ Ooms P, Mantione M, Figee M, Schuurman PR, van den Munckhof P, Denys D (February 2014). "Deep brain stimulation for obsessive-compulsive disorders: long-term analysis of quality of life". Journal of Neurology, Neurosurgery, and Psychiatry. 85 (2): 153–8. doi:10.1136/jnnp-2012-302550. PMID 23715912. S2CID 54572260.
  68. ^ "Controversial Surgery for Addiction Burns Away Brain's Pleasure Center" Author Maia Szalavitz. Dec. 13, 2012
  69. ^ "China Bans Irreversible Brain Procedure" Author Zamiska Nicholas. April 28, 2008. The Wall Street Journal
  70. ^ Scott DJ, Stohler CS, Egnatuk CM, Wang H, Koeppe RA, Zubieta JK (July 2007). "Individual differences in reward responding explain placebo-induced expectations and effects". Neuron. 55 (2): 325–36. doi:10.1016/j.neuron.2007.06.028. PMID 17640532.
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