Dopamine

Dopamine
Identifiers
CAS number 51-61-6 Y, 62-31-7 (hydrochloride) Y
PubChem 681
ChemSpider 661 Y
UNII VTD58H1Z2X Y
DrugBank DB00988
KEGG D07870 Y
ChEBI CHEBI:18243 Y
ChEMBL CHEMBL59 Y
Jmol-3D images Image 1
Properties
Molecular formula C8H11NO2
Molar mass 153.18 g/mol
Density 1.26 g/cm3
Melting point

128 °C, 401 K, 262 °F

Boiling point

decomposes

Solubility in water 60.0 g/100 ml
Hazards
R-phrases R36/37/38
S-phrases S26 S36
 Y (verify) (what is: Y/N?)
Except where noted otherwise, data are given for materials in their standard state (at 25 °C, 100 kPa)
Infobox references

Dopamine (sometimes abbreviated DA) is a catecholamine neurotransmitter present in a wide variety of animals, including both vertebrates and invertebrates. In the brain, this substituted phenethylamine functions as a neurotransmitter, activating the five known types of dopamine receptorsD1, D2, D3, D4, and D5— as well as their variants. Dopamine is produced in several areas of the brain, including the substantia nigra and the ventral tegmental area.[1] Dopamine is also a neurohormone released by the hypothalamus. Its main function as a hormone is to inhibit the release of prolactin from the anterior lobe of the pituitary.

Dopamine is available as an intravenous medication acting on the sympathetic nervous system, producing effects such as increased heart rate and blood pressure. However, because dopamine cannot cross the blood-brain barrier, dopamine given as a drug does not directly affect the central nervous system. To increase the amount of dopamine in the brains of patients with diseases such as Parkinson's disease and dopa-responsive dystonia, L-DOPA (the precursor of dopamine) is often given because it crosses the blood-brain barrier relatively easily.

Contents

History

Dopamine was first synthesized in 1910 by George Barger and James Ewens at Wellcome Laboratories in London, England.[2] It was named dopamine because it is a monoamine whose precursor in the Barger-Ewens synthesis is 3,4-dihydroxyphenylalanine (levodopamine or L-DOPA). Dopamine's function as a neurotransmitter was first recognized in 1958 by Arvid Carlsson and Nils-Åke Hillarp at the Laboratory for Chemical Pharmacology of the National Heart Institute of Sweden.[3] Carlsson was awarded the 2000 Nobel Prize in Physiology or Medicine for showing that dopamine is not only a precursor of norepinephrine (noradrenaline) and epinephrine (adrenaline), but also a neurotransmitter.

Chemistry

Dopamine (right) has the chemical formula C6H3(OH)2-CH2-CH2-NH2. Its chemical name is "4-(2-aminoethyl)benzene-1,2-diol" and its abbreviation is "DA." As a medicinal agent, dopamine is synthesized by demethylation of 2-(3,4-dimethoxyphenyl)ethylamine (left) using hydrogen bromide.[4][5]

Biochemistry

Classification

As a member of the catecholamine family, dopamine is a precursor to norepinephrine (noradrenaline) and then epinephrine (adrenaline) in the biosynthetic pathways for these neurotransmitters.

Biosynthesis

Dopamine is biosynthesized in the body (mainly by nervous tissue and the medulla of the adrenal glands) first by the hydroxylation of the amino acid L-tyrosine to L-DOPA via the enzyme tyrosine 3-monooxygenase, also known as tyrosine hydroxylase, and then by the decarboxylation of L-DOPA by aromatic L-amino acid decarboxylase (which is often referred to as dopa decarboxylase). In some neurons, dopamine is further processed into norepinephrine by dopamine beta-hydroxylase.

In neurons, dopamine is packaged after synthesis into vesicles, which are then released into the synapse in response to a presynaptic action potential.

Inactivation and degradation

Two major degradation pathways for dopamine exist. In most areas of the brain, including the striatum and basal ganglia, dopamine is inactivated by reuptake via the dopamine transporter (DAT1), then enzymatic breakdown by monoamine oxidase (MAOA and MAOB) into 3,4-dihydroxyphenylacetic acid. In the prefrontal cortex, however, there are very few dopamine transporter proteins, and dopamine is instead inactivated by reuptake via the norepinephrine transporter (NET), presumably on neighboring norepinephrine neurons, then enzymatic breakdown by catechol-O-methyl transferase (COMT) into 3-methoxytyramine.[6] The DAT1 pathway is roughly an order of magnitude faster than the NET pathway: in mice, dopamine concentrations decay with a half-life of 200 ms in the caudate nucleus (which uses the DAT1 pathway) versus 2,000 ms in the prefrontal cortex.[7] Dopamine that is not broken down by enzymes is repackaged into vesicles for reuse by VMAT2.

Functions in the brain

Dopamine has many functions in the brain, including important roles in behavior and cognition, voluntary movement, motivation, punishment and reward, inhibition of prolactin production (involved in lactation and sexual gratification), sleep, mood, attention, working memory, and learning. Dopaminergic neurons (i.e., neurons whose primary neurotransmitter is dopamine) are present chiefly in the ventral tegmental area (VTA) of the midbrain, the substantia nigra pars compacta, and the arcuate nucleus of the hypothalamus.

It has been hypothesized that dopamine transmits reward prediction error, although this has been questioned.[8] According to this hypothesis, the phasic responses of dopamine neurons are observed when an unexpected reward is presented. These responses transfer to the onset of a conditioned stimulus after repeated pairings with the reward. Further, dopamine neurons are depressed when the expected reward is omitted. Thus, dopamine neurons seem to encode the prediction error of rewarding outcomes. In nature, we learn to repeat behaviors that lead to maximizing rewards. Dopamine is therefore believed to provide a teaching signal to parts of the brain responsible for acquiring new behavior. Temporal difference learning provides a computational model describing how the prediction error of dopamine neurons is used as a teaching signal.

The reward system in insects uses octopamine, which is the presumed arthropod homolog of norepinephrine,[9] rather than dopamine. In insects, dopamine acts instead as a punishment signal and is necessary to form aversive memories.[10][11]

Anatomy

Dopaminergic neurons form a neurotransmitter system which originates in substantia nigra pars compacta, ventral tegmental area (VTA), and hypothalamus. These project axons to large areas of the brain which are typically divided into four major pathways:

This innervation explains many of the effects of activating this dopamine system. For instance, the mesolimbic pathway connects the VTA and nucleus accumbens; both are central to the brain reward system.[12]

Whilst the distinction between pathways is widely used, and is regarded as a “convenient heuristic when considering the dopamine system”, it is not absolute, and there is some overlap in the projection targets of each group of neurons.[13]

Cellular effects

Tonic and phasic activity

The level of extracellular dopamine is modulated by two mechanisms, tonic and phasic dopamine transmission. Tonic dopamine transmission occurs when small amounts of dopamine are released independently of neuronal activity, and is regulated by the activity of other neurons and neurotransmitter reuptake.[14] Phasic dopamine release results from the activity of the dopamine-containing cells themselves. This activity is characterized by irregular pacemaking activity of single spikes, and rapid bursts of typically 2-6 spikes in quick succession.[15][16] Concentrated bursts of activity result in a greater increase of extracellular dopamine levels than would be expected from the same number of spikes distributed over a longer period of time.[17]

Reuptake inhibition and synaptic release

Cocaine and amphetamines inhibit the re-uptake of dopamine; however, they influence separate mechanisms of action. Cocaine is a dopamine transporter and norepinephrine transporter blocker that competitively inhibits dopamine uptake to increase the lifetime of dopamine and augments an overabundance of dopamine (an increase of up to 150 percent) within the parameters of the dopamine neurotransmitters. Like cocaine, amphetamines increase the concentration of dopamine in the synaptic gap, but by a different mechanism. Amphetamines and methamphetamine are similar in structure to dopamine, and so can enter the terminal bouton of the presynaptic neuron via its dopamine transporters as well as by diffusing through the neural membrane directly. By entering the presynaptic neuron, amphetamines force dopamine molecules out of their storage vesicles and expel them into the synaptic gap by making the dopamine transporters work in reverse.

Motor control

Dopamine reduces the influence of the indirect pathway while increasing the actions of the direct pathway within the basal ganglia. Insufficient dopamine biosynthesis in the dopaminergic neurons can cause Parkinson's disease, a condition in which one loses the ability to execute smooth, controlled movements.

Regulating prolactin secretion

Dopamine is the primary neuroendocrine inhibitor of the secretion of prolactin from the anterior pituitary gland.[18] Dopamine produced by neurons in the arcuate nucleus of the hypothalamus is secreted into the hypothalamo-hypophysial blood vessels of the median eminence, which supply the pituitary gland. The lactotrope cells that produce prolactin, in the absence of dopamine, secrete prolactin continuously; dopamine inhibits this secretion. Thus, in the context of regulating prolactin secretion, dopamine is occasionally called prolactin-inhibiting factor (PIF), prolactin-inhibiting hormone (PIH), or prolactostatin.

Cognition and frontal cortex

In the frontal lobes, dopamine controls the flow of information from other areas of the brain. Dopamine disorders in this region of the brain can cause a decline in neurocognitive functions, especially memory, attention, and problem-solving. Reduced dopamine concentrations in the prefrontal cortex are thought to contribute to attention deficit disorder. It has been found that D1 receptors[19] as well as D4 receptors[20] are responsible for the cognitive-enhancing effects of dopamine, whereas D2 receptors are more specific for motor actions.

Chemoreceptor trigger zone

Dopamine is one of the neurotransmitters implicated in the control of nausea and vomiting via interactions in the chemoreceptor trigger zone. Metoclopramide is a D2-receptor antagonist that functions as a prokinetic/antiemetic.

Effects of drugs that reduce dopamine activity

In humans, drugs that reduce dopamine activity (neuroleptics, e.g. antipsychotics) have been shown to impair concentration, reduce motivation, cause anhedonia (inability to experience pleasure), and long-term use has been associated with tardive dyskinesia, an irreversible movement disorder.[21] Antipsychotics have significant effects on gonadal hormones including significantly lower levels of estradiol and progesterone in women whereas men display significantly lower levels of testosterone and DHEA when undergoing antipsychotic drug treatment compared to controls. Antipsychotics are known to cause hyperprolactinaemia leading to amenorrhea, cessation of normal cyclic ovarian function, loss of libido, occasional hirsutism, false positive pregnancy tests, and long-term risk of osteoporosis in women. The effects of hyperprolactinemia in men are gynaecomastia, lactation, impotence, loss of libido, and hypospermatogenesis.[22] Furthermore, antipsychotic drugs are associated with weight gain, diabetes, drooling, dysphoria (abnormal depression and discontent), fatigue, sexual dysfunction, heart rhythm problems, stroke and heart attack. Selective D2/D3 agonists pramipexole and ropinirole, used to treat restless legs syndrome (RLS), have limited anti-anhedonic properties as measured by the Snaith-Hamilton Pleasure Scale (SHAPS).[23]

Opioid and cannabinoid transmission

Opioid and cannabinoid transmission instead of dopamine may modulate consummatory pleasure and food palatability (liking).[24] This could explain why animals' "liking" of food is independent of brain dopamine concentration. Other consummatory pleasures, however, may be more associated with dopamine. One study found that both anticipatory and consummatory measures of sexual behavior (male rats) were disrupted by DA receptor antagonists.[25] Libido can be increased by drugs that affect dopamine, but not by drugs that affect opioid peptides or other neurotransmitters.

Learning, reinforcement, and reward-seeking behavior

Dopamine is commonly associated with the reward system of the brain, providing feelings of enjoyment and reinforcement to motivate a person to perform certain activities. Dopamine is released (particularly in areas such as the nucleus accumbens and prefrontal cortex) by rewarding experiences such as food, sex, drugs, and neutral stimuli that become associated with them.[26] Recent studies indicate that aggression may also stimulate the release of dopamine in this way.[27]

This theory can be discussed in terms of drugs such as cocaine, nicotine, and amphetamines, which directly or indirectly lead to an increase of dopamine in the mesolimbic reward pathway of the brain, and in relation to neurobiological theories of chemical addiction (not to be confused with psychological dependence), arguing that this dopamine pathway is pathologically altered in addicted persons.[28]

Dopaminergic neurons of the midbrain are the main source of dopamine in the brain.[26] Dopamine has been shown to be involved in the control of movements, the signaling of error in prediction of reward, motivation, and cognition. Cerebral dopamine depletion is the hallmark of Parkinson's disease.[26] Other pathological states have also been associated with dopamine dysfunction, such as schizophrenia, autism, and attention deficit hyperactivity disorder, as well as drug abuse.

Dopamine is closely associated with reward-seeking behaviors, such as approach, consumption, and addiction.[26] Recent researches suggest that the firing of dopaminergic neurons is a motivational substance as a consequence of reward-anticipation. This hypothesis is based on the evidence that, when a reward is greater than expected, the firing of certain dopaminergic neurons increases, which consequently increases desire or motivation towards the reward.[26] However, recent research finds that while some dopaminergic neurons react in the way expected of reward neurons, others do not and seem to respond in regard to unpredictability.[29] This research finds the reward neurons predominate in the ventromedial region in the substantia nigra pars compacta as well as the ventral tegmental area. Neurons in these areas project mainly to the ventral striatum and thus might transmit value-related information in regard to reward values.[29] The nonreward neurons are predominate in the dorsolateral area of the substantia nigra pars compacta which projects to the dorsal striatum and may relate to orienting behaviour.[29] It has been suggested that the difference between these two types of dopaminergic neurons arises from their input: reward-linked ones have input from the basal forebrain while the nonreward-related ones from the lateral habenula.[29]

Animal studies

Clues to dopamine's role in motivation, desire, and pleasure have come from studies performed on animals. In one such study, rats were depleted of dopamine by up to 99 percent in the nucleus accumbens and neostriatum using 6-hydroxydopamine.[26] With this large reduction in dopamine, the rats would no longer eat by their own volition. The researchers then force-fed the rats food and noted whether they had the proper facial expressions indicating whether they liked or disliked it. The researchers of this study concluded that the reduction in dopamine did not reduce the rat's consummatory pleasure, only the desire to actually eat. In another study, mutant hyperdopaminergic (increased dopamine) mice show higher "wanting" but not "liking" of sweet rewards.[30]

Salience

Dopamine may also have a role in the salience of potentially important stimuli, such as sources of reward or of danger.[31] This hypothesis argues that dopamine assists decision-making by influencing the priority, or level of desire, of such stimuli to the person concerned.

Dopamine's role in experiencing pleasure has been questioned by several researchers. It has been argued that dopamine is more associated with anticipatory desire and motivation (commonly referred to as "wanting") as opposed to actual consummatory pleasure (commonly referred to as "liking").

Latent inhibition and creative drive

Dopamine in the mesolimbic pathway increases general arousal and goal directed behaviors and decreases latent inhibition; all three effects increase the creative drive of idea generation. This has led to a three-factor model of creativity involving the frontal lobes, the temporal lobes, and mesolimbic dopamine.[32]

Sociability

Sociability is also closely tied to dopamine neurotransmission. Low D2 receptor-binding is found in people with social anxiety. Traits common to negative schizophrenia (social withdrawal, apathy, anhedonia) are thought to be related to a hypodopaminergic state in certain areas of the brain. In instances of bipolar disorder, manic subjects can become hypersocial, as well as hypersexual. This is credited to an increase in dopamine, because mania can be reduced by dopamine-blocking antipsychotics.[33]

Processing of pain

Dopamine has been demonstrated to play a role in pain processing in multiple levels of the central nervous system including the spinal cord,[34] periaqueductal gray (PAG),[35] thalamus,[36] basal ganglia,[37][38] insular cortex,[39][40] and cingulate cortex.[41] Accordingly, decreased levels of dopamine have been associated with painful symptoms that frequently occur in Parkinson's disease.[42] Abnormalities in dopaminergic neurotransmission have also been demonstrated in painful clinical conditions, including burning mouth syndrome,[43] fibromyalgia,[44][45] and restless legs syndrome.[46] In general, the analgesic capacity of dopamine occurs as a result of dopamine D2 receptor activation; however, exceptions to this exist in the PAG, in which dopamine D1 receptor activation attenuates pain presumably via activation of neurons involved in descending inhibition.[47] In addition, D1 receptor activation in the insular cortex appears to attenuate subsequent pain-related behavior.

Behavior disorders

Deficient dopamine neurotransmission is implicated in attention-deficit hyperactivity disorder, and stimulant medications used to successfully treat the disorder increase dopamine neurotransmission, leading to decreased symptoms.[48] Consistent with this hypothesis, dopaminergic pathways have a role in inhibitory action control and the inhibition of the tendency to make unwanted actions.[49]

The long term use of levodopa in Parkinson's disease has been linked to dopamine dysregulation syndrome.[50]

Dopaminergic mind hypothesis

The dopaminergic mind hypothesis seeks to explain the differences between modern humans and their hominid relatives by focusing on changes in dopamine.[51] It theorizes that increased levels of dopamine were part of a general physiological adaptation due to an increased consumption of meat around two million years ago in Homo habilis, and later enhanced by changes in diet and other environmental and social factors beginning approximately 80,000 years ago. Under this theory, the "high-dopamine" personality is characterized by high intelligence, a sense of personal destiny, a religious/cosmic preoccupation, an obsession with achieving goals and conquests, an emotional detachment that in many cases leads to ruthlessness, and a risk-taking mentality. High levels of dopamine are proposed to underlie increased psychological disorders in industrialized societies. According to this hypothesis, a "dopaminergic society" is an extremely goal-oriented, fast-paced, and even manic society, "given that dopamine is known to increase activity levels, speed up our internal clocks and create a preference for novel over unchanging environments."[51] In the same way that high-dopamine individuals lack empathy and exhibit a more masculine behavioral style, dopaminergic societies are "typified by more conquest, competition, and aggression than nurturance and communality."[51] Although behavioral evidence and some indirect anatomical evidence (e.g., enlargement of the dopamine-rich striatum in humans)[52] support a dopaminergic expansion in humans, there is still no direct evidence that dopamine levels are markedly higher in humans relative to other apes.[53] However, recent discoveries about the sea-side settlements of early man may provide evidence of dietary changes consistent with this hypothesis.[54]

Links to psychosis

Abnormally high dopaminergic transmission has been linked to psychosis and schizophrenia.[55] Increased dopaminergic functional activity, specifically in the mesolimbic pathway, is found in schizophrenic individuals. However, decreased activity in another dopaminergic pathway, the mesocortical pathway, may also be involved. The two pathways are thought to be responsible for differing sets of symptoms seen in schizophrenia. Antipsychotic medications act largely as dopamine antagonists, inhibiting dopamine at the receptor level, and thereby blocking the effects of the neurochemical in a dose-dependant manner. The older, so-called typical antipsychotics most commonly act on D2 receptors,[56] while the atypical drugs also act on D1, D3 and D4 receptors.[57][58] The finding that drugs such as amphetamines, methamphetamine and cocaine, which can increase dopamine levels by more than tenfold,[59] can temporarily cause psychosis, provides further evidence for this link.[60]

Therapeutic use

Levodopa is a dopamine precursor used in various forms to treat Parkinson's disease and dopa-responsive dystonia. It is typically co-administered with an inhibitor of peripheral decarboxylation (DDC, dopa decarboxylase), such as carbidopa or benserazide. Inhibitors of alternative metabolic route for dopamine by catechol-O-methyl transferase are also used. These include entacapone and tolcapone.

Nonneural functions

Renal and cardiovascular

Dopamine (brand name Intropin) also has effects when administered through an IV line outside the central nervous system. The effects in this form are dose dependent.

Immunoregulatory

Dopamine acts upon receptors present on immune cells, with all subtypes of dopamine receptors found on leukocytes. There is low expression of receptors on T lymphocytes and monocytes, moderate expression on neutrophils and eosinophils, and high expression on B cells and natural killer cells.[67] The sympathetic innervation of lymphoid tissues is dopaminergic, and increases during stress.[68] Dopamine can also affect immune cells in the spleen, bone marrow, and blood circulation.[69] In addition, dopamine can be synthesized and released by the immune cells themselves.[70][71]

The effects of dopamine on immune cells depend upon their physiological state. While dopamine activates resting T cells, it inhibits them when they are activated. Disorders such as schizophrenia and Parkinson's disease, in which there are changes in brain dopamine receptors and dopamine signaling pathways, are also associated with altered immune functioning.[72]

In plants

Fruit browning

Polyphenol oxidases (PPOs) are a family of enzymes responsible for the browning of fresh fruits and vegetables when they are cut or bruised. These enzymes use molecular oxygen (O2) to oxidise various 1,2-diphenols to their corresponding quinones. The natural substrate for PPOs in bananas is dopamine. The product of their oxidation, dopamine quinone, spontaneously oxidises to other quinones. The quinones then polymerise and condense with amino acids and proteins to form brown pigments known as melanins. The quinones and melanins derived from dopamine may help protect damaged fruit and vegetables against growth of bacteria and fungi.[73]

Anti-herbivore

Dopamine is released by the marine alga Ulvaria obscura as an anti-herbivore defense mechanism.[74]

See also

References

  1. ^ http://www.encyclopedia.com/doc/1O87-ventraltegmentalarea.html Reference for VTA.
  2. ^ Fahn, Stanley, "The History of Levodopa as it Pertains to Parkinson's disease," Movement Disorder Society’s 10th International Congress of Parkinson's Disease and Movement Disorders on November 1, 2006, in Kyoto, Japan.
  3. ^ Benes, F.M. (2001). "Carlsson and the discovery of dopamine". Trends in Pharmacological Sciences 22 (1): 46–47. doi:10.1016/S0165-6147(00)01607-2. PMID 11165672. 
  4. ^ J. S. Bayeler, Ann. Chem., 513, 196 (1934).
  5. ^ G. Hahn, K. Stiehl, Chem. Ber., 69, 2640 (1936).
  6. ^ Morón, JA; Brockington, A; Wise, RA; Rocha, BA; Hope, BT (2002). "Dopamine uptake through the norepinephrine transporter in brain regions with low levels of the dopamine transporter: evidence from knock-out mouse lines.". Journal of Neuroscience 22 (2): 389–95. PMID 11784783. http://www.jneurosci.org/cgi/content/abstract/22/2/389. 
  7. ^ Yavich, L; Forsberg, MM; Karayiorgou, M; Gogos, JA; Männistö, PT (2007). "Site-specific role of catechol-O-methyltransferase in dopamine overflow within prefrontal cortex and dorsal striatum.". Journal of Neuroscience 27 (38): 10196–209. doi:10.1523/JNEUROSCI.0665-07.2007. PMID 17881525. http://www.jneurosci.org/cgi/content/abstract/27/38/10196. 
  8. ^ Peter Redgrave, Kevin Gurney (2006). "The short-latency dopamine signal: a role in discovering novel actions?". Nature Reviews Neuroscience 7 (12): 967–975. doi:10.1038/nrn2022. PMID 17115078. 
  9. ^ Barron AB, Maleszka R, Vander Meer RK, Robinson GE (2007). "Octopamine modulates honey bee dance behavior". Proc. Natl. Acad. Sci. U.S.A. 104 (5): 1703–7. doi:10.1073/pnas.0610506104. PMC 1779631. PMID 17237217. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=1779631. 
  10. ^ Schwaerzel M, Monastirioti M, Scholz H, Friggi-Grelin F, Birman S, Heisenberg M (November 2003). "Dopamine and octopamine differentiate between aversive and appetitive olfactory memories in Drosophila". J. Neurosci. 23 (33): 10495–502. PMID 14627633. http://www.jneurosci.org/cgi/pmidlookup?view=long&pmid=14627633. 
  11. ^ Selcho M, Pauls D, Han KA, Stocker RF, Thum AS (2009). Giurfa, Martin. ed. "The role of dopamine in Drosophila larval classical olfactory conditioning". PLoS ONE 4 (6): e5897. doi:10.1371/journal.pone.0005897. PMC 2690826. PMID 19521527. http://dx.plos.org/10.1371/journal.pone.0005897. 
  12. ^ Schultz, Cambridge university, UK
  13. ^ Bjorklund A, Dunnett SB (2007). "Dopamine neuron systems in the brain: an update". Trends in Neurosciences 20 (5): 194–202. doi:10.1016/j.tins.2007.03.006. PMID 17408759. 
  14. ^ Grace AA, (1991). "Phasic versus tonic dopamine release and the modulation of dopamine system responsivity: A hypothesis for the eitiology of schizophrenia" (pdf). Neuroscience 41 (1): 1–24. doi:10.1016/0306-4522(91)90196-U. PMID 1676137. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6T0F-485YGDY-4&_user=128590&_coverDate=12%2F31%2F1991&_rdoc=1&_fmt=high&_orig=search&_sort=d&_docanchor=&view=c&_searchStrId=1403836309&_rerunOrigin=scholar.google&_acct=C000010619&_version=1&_urlVersion=0&_userid=128590&md5=1c4978d564d1aaa5afc501a3454d469c. 
  15. ^ Grace AA, Bunney BS (1984). "The control of firing pattern in nigral dopamine neurons: single spike firing" (pdf). Journal of Neuroscience 4 (11): 2866–2876. PMID 6150070. http://www.jneurosci.org/cgi/reprint/4/11/2866. 
  16. ^ Grace AA, Bunney BS (1984). "The control of firing pattern in nigral dopamine neurons: burst firing" (pdf). Journal of Neuroscience 4 (11): 28677–2890. PMID 6150071. http://www.jneurosci.org/cgi/reprint/4/11/2877. 
  17. ^ Gonon FG (1988). "Nonlinear relationship between impulse flow and dopamine released by rat midbrain dopaminergic neurons as studied by in vivo electrochemistry" (pdf). Neuroscience 24 (1): 19–28. doi:10.1016/0306-4522(88)90307-7. PMID 3368048. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6T0F-485P3C0-5Y&_user=128590&_coverDate=01%2F31%2F1988&_rdoc=1&_fmt=high&_orig=search&_sort=d&_docanchor=&view=c&_searchStrId=1403496208&_rerunOrigin=scholar.google&_acct=C000010619&_version=1&_urlVersion=0&_userid=128590&md5=366f22be3c8d212a7bf26bf7630eeb93. 
  18. ^ Ben-Jonathan N, Hnasko R (2001). "Dopamine as a Prolactin (PRL) Inhibitor" (PDF). Endocrine Reviews 22 (6): 724–763. doi:10.1210/er.22.6.724. PMID 11739329. http://edrv.endojournals.org/cgi/reprint/22/6/724.pdf. 
  19. ^ Heijtz RD, Kolb B, Forssberg H (2007). "Motor inhibitory role of dopamine D1 receptors: implications for ADHD" (PDF). Physiol Behav 92 (1-2): 155–160. doi:10.1016/j.physbeh.2007.05.024. PMID 17585966. http://www.sciencedirect.com/science?_ob=MImg&_imagekey=B6T0P-4NTB97R-Y-1&_cdi=4868&_user=308069&_orig=search&_coverDate=09%2F30%2F2007&_sk=999079998&view=c&wchp=dGLbVzz-zSkzV&md5=c49d721e7e713190c2ac6fab7a491093&ie=/sdarticle.pdf. 
  20. ^ Browman, KE; Curzon, P; Pan, JB; Molesky, AL; Komater, VA; Decker, MW; Brioni, JD; Moreland, RB et al. (2005). "A-412997, a selective dopamine D4 agonist, improves cognitive performance in rats.". Pharmacology, biochemistry, and behavior 82 (1): 148–55. doi:10.1016/j.pbb.2005.08.002. PMID 16154186. 
  21. ^ Lambert M, Schimmelmann B, Karow A, Naber D (2003). "Subjective well-being and initial dysphoric reaction under antipsychotic drugs - concepts, measurement and clinical relevance". Pharmacopsychiatry 36 (Suppl 3): S181–90. doi:10.1055/s-2003-45128. PMID 14677077. 
  22. ^ Raji Y, Ifabunmi SO, Akinsomisoye OS, Morakinyo AO, Oloyo AK (2005). "Gonadal Responses to Antipsychotic Drugs: Chlorpromazine and Thioridazine Reversibly Suppress Testicular Functions in Albino Rats". International Journal of Pharmacology 1 (3): 287–92. doi:10.3923/ijp.2005.287.292. 
  23. ^ Lemke M, Brecht H, Koester J, Kraus P, Reichmann H (2005). "Anhedonia, depression, and motor functioning in Parkinson's disease during treatment with pramipexole". J Neuropsychiatry Clin Neurosci 17 (2): 214–20. doi:10.1176/appi.neuropsych.17.2.214. PMID 15939976. http://neuro.psychiatryonline.org/cgi/content/full/17/2/214. 
  24. ^ Peciña S, Berridge K (2005). "Hedonic hot spot in nucleus accumbens shell: where do mu-opioids cause increased hedonic impact of sweetness?". J Neurosci 25 (50): 11777–86. doi:10.1523/JNEUROSCI.2329-05.2005. PMID 16354936. http://www.jneurosci.org/cgi/content/full/jneuro;25/50/11777. 
  25. ^ Pfaus J, Phillips A (1991). "Role of dopamine in anticipatory and consummatory aspects of sexual behavior in the male rat". Behav Neurosci 105 (5): 727–43. doi:10.1037/0735-7044.105.5.727. PMID 1840012. 
  26. ^ a b c d e f Arias-Carrión O, Pöppel E (2007). "Dopamine, learning and reward-seeking behavior". Act Neurobiol Exp 67 (4): 481–488. http://www.ane.pl/pdfdownload.php?art=6738. 
  27. ^ Dopamine Involved In Aggression - Medical News Today
  28. ^ Eric J. Nestler, Department of Psychiatry and Center for Basic Neuroscience, The University of Texas Southwestern Medical Center (2005). "Is There A Common Molecular Pathway For Addiction?". Nature Neuroscience 8 (11): 1445–1449. doi:10.1038/nn1578. http://dept.wofford.edu/neuroscience/NeuroSeminar/pdfSpring2006/a7.pdf. 
  29. ^ a b c d Matsumoto M, Hikosaka O. (2009). "Two types of dopamine neuron distinctly convey positive and negative motivational signals.". Nature 459 (7248): 837–41. doi:10.1038/nature08028. PMC 2739096. PMID 19448610. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2739096. 
  30. ^ Peciña S, Cagniard B, Berridge K, Aldridge J, Zhuang X (2003). "Hyperdopaminergic mutant mice have higher "wanting" but not "liking" for sweet rewards". J Neurosci 23 (28): 9395–402. PMID 14561867. 
  31. ^ Schultz W (2002). "Getting formal with dopamine and reward". Neuron 36 (2): 241–263. doi:10.1016/S0896-6273(02)00967-4. PMID 12383780. 
  32. ^ Flaherty, A.W, (2005). "Frontotemporal and dopaminergic control of idea generation and creative drive". Journal of Comparative Neurology 493 (1): 147–153. doi:10.1002/cne.20768. PMC 2571074. PMID 16254989. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2571074. 
  33. ^ http://bipolar.about.com/cs/menu_treat/a/0312_treatmania_3.htm
  34. ^ Jensen, TS; Yaksh, TL. (1984). "Effects of an intrathecal dopamine agonist, apomorphine, on thermal and chemical evoked noxious responses in rats". Brain Res. 296 (2): 285–93. doi:10.1016/0006-8993(84)90064-7. PMID 6322926. 
  35. ^ Flores, JA; El Banoua, F; Galán-Rodríguez, B; Fernandez-Espejo, E. (2004). "Opiate anti-nociception is attenuated following lesion of large dopamine neurons of the periaqueductal grey: critical role for D1 (not D2) dopamine receptors". Pain 110 (1-2): 205–14. doi:10.1016/j.pain.2004.03.036. PMID 15275769. 
  36. ^ Shyu, BC; Kiritsy-Roy, JA; Morrow, TJ; Casey, KL. (1992). "Neurophysiological, pharmacological and behavioral evidence for medial thalamic mediation of cocaine-induced dopaminergic analgesia". Brain Res 572 (1-2): 216–23. doi:10.1016/0006-8993(92)90472-L. PMID 1611515. 
  37. ^ Chudler, EH; Dong, WK. (1995). "The role of the basal ganglia in nociception and pain". Pain 60 (1): 3–38. doi:10.1016/0304-3959(94)00172-B. PMID 7715939. 
  38. ^ Altier, N; Stewart, J. (1999). "The role of dopamine in the nucleus accumbens in analgesia". Life Sci. 65 (22): 2269–87. doi:10.1016/S0024-3205(99)00298-2. PMID 10597883. 
  39. ^ Burkey, AR; Carstens, E; Jasmin, L. (1999). "Dopamine reuptake inhibition in the rostral agranular insular cortex produces antinociception". J Neurosci 19 (10): 4169–79. PMID 10234044. 
  40. ^ Coffeen, U; López-Avila, A; Ortega-Legaspi, JM; Angel, R; López-Muñoz, FJ; Pellicer, F. (2008). "Dopamine receptors in the anterior insular cortex modulate long-term nociception in the rat". Eur J Pain. 12 (5): 535–43. doi:10.1016/j.ejpain.2007.08.008. PMID 17936656. 
  41. ^ López-Avila, A; Coffeen, U; Ortega-Legaspi, JM; Angel, R; Pellicer, F. (2004). "Dopamine and NMDA systems modulate long-term nociception in the rat anterior cingulate cortex". Pain 111 (1-2): 136–43. doi:10.1016/j.pain.2004.06.010. PMID 15327817. 
  42. ^ Brefel-Courbon, C; Payoux, P; Thalamas, C; Ory, F; Quelven, I; Chollet, F; Montastruc, JL; Rascol, O. (2005). "Effect of levodopa on pain threshold in Parkinson's disease: a clinical and positron emission tomography study". Mov Disord 20 (12): 1557–63. doi:10.1002/mds.20629. PMID 16078219. 
  43. ^ Jääskeläinen, SK; Rinne, JO; Forssell, H; Tenovuo, O; Kaasinen, V; Sonninen, P; Bergman, J. (2001). "Role of the dopaminergic system in chronic pain -- a fluorodopa-PET study". Pain 90 (3): 257–60. doi:10.1016/S0304-3959(00)00409-7. PMID 11207397. 
  44. ^ Wood, PB; Patterson Jc, 2nd; Sunderland, JJ; Tainter, KH; Glabus, MF; Lilien, DL (2007). "Reduced presynaptic dopamine activity in fibromyalgia syndrome demonstrated with positron emission tomography: a pilot study". J Pain 8 (1): 51–8. doi:10.1016/j.jpain.2006.05.014. PMID 17023218. 
  45. ^ Wood, PB; Schweinhardt, P; Jaeger, E; Dagher, A; Hakyemez, H; Rabiner, EA; Bushnell, MC; Chizh, BA. (2007). "Fibromyalgia patients show an abnormal dopamine response to pain". Eur J Neurosci 25 (12): 3576–82. doi:10.1111/j.1460-9568.2007.05623.x. PMID 17610577. 
  46. ^ Cervenka, S; Pålhagen, SE; Comley, RA; Panagiotidis, G; Cselényi, Z; Matthews, JC; Lai, RY; Halldin, C et al. (2006). "Support for dopaminergic hypoactivity in restless legs syndrome: a PET study on D2-receptor binding". Brain 129 (Pt 8): 2017–28. doi:10.1093/brain/awl163. PMID 16816393. 
  47. ^ Wood, PB. (2008). "Role of central dopamine in pain and analgesia". Expert Rev Neurother 8 (5): 781–97. doi:10.1586/14737175.8.5.781. PMID 18457535. 
  48. ^ "A dynamic developmental theory of attention-deficit/hyperactivity disorder (ADHD) predominantly hyperactive/impulsive and combined subtypes". Cambridge Journals. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=332927. Retrieved 2009-04-20. 
  49. ^ Colzato, LS; Van Den Wildenberg, WP; Van Wouwe, NC; Pannebakker, MM; Hommel, B (2009). "Dopamine and inhibitory action control: evidence from spontaneous eye blink rates.". Experimental brain research. Experimentelle Hirnforschung. Experimentation cerebrale 196 (3): 467–74. doi:10.1007/s00221-009-1862-x. PMC 2700244. PMID 19484465. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2700244. 
  50. ^ Merims D, Giladi N (2008). "Dopamine dysregulation syndrome, addiction and behavioral changes in Parkinson's disease". Parkinsonism Relat. Disord. 14 (4): 273–80. doi:10.1016/j.parkreldis.2007.09.007. PMID 17988927. 
  51. ^ a b c Previc F (2009). The Dopaminergic Mind in Human Evolution and History Cambridge University Press. ISBN 978-0-521-51699-0.
  52. ^ Rapoport, S. I. (1990). "Integrated phylogeny of the primate brain, with special reference to humans and their diseases". Brain Research Reviews 15 (3): 267–294. doi:10.1016/0165-0173(90)90004-8. PMID 2289087. 
  53. ^ Raghanti, M. A.; Stimpson, C. D.; Marcinkiewicz, J. L.; Erwin, J. M.; Hof, P. R.; Sherwood, C. C. (2008a). "Cortical dopaminergic innervation among humans, chimpanzees, and macaque monkeys: A comparative study". Neuroscience 155 (1): 203–20. doi:10.1016/j.neuroscience.2008.05.008. PMID 18562124. 
  54. ^ http://www.scientificamerican.com/article.cfm?id=interactive-seas-saved-humanity
  55. ^ "Disruption of gene interaction linked to schizophrenia". St. Jude Children's Research Hospital. http://www.innovations-report.com/html/reports/life_sciences/report-52499.html. Retrieved 2006-07-06. 
  56. ^ http://www.williams.edu/imput/synapse/pages/IIIB5.htm
  57. ^ http://bjp.rcpsych.org/cgi/content/full/181/4/271
  58. ^ Durcan, M; Rigdon, GC; Norman, MH; Morgan, PF (1995). "Is clozapine selective for the dopamine D4 receptor?". Life Sciences 57 (18): PL275. doi:10.1016/0024-3205(95)02151-8. PMID 7475902. 
  59. ^ Methamphetamine 101
  60. ^ Lieberman, J.A.; JM Kane, J. Alvir (1997). "Provocative tests with psychostimulant drugs in schizophrenia". Psychopharmacology (Berl). 91 (4): 415–433. doi:10.1007/BF00216006. PMID 2884687. 
  61. ^ Gildea, John J (2009). "Dopamine and angiotensin as renal counterregulatory systems controlling sodium balance". Current Opinion in Nephrology and Hypertension 18 (1): 28. doi:10.1097/MNH.0b013e32831a9e0b. PMC 2847451. PMID 19077686. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2847451. 
  62. ^ Cinelli, A. R.; Efendiev, R.; Pedemonte, C. H. (2008). "Trafficking of Na-K-ATPase and dopamine receptor molecules induced by changes in intracellular sodium concentration of renal epithelial cells". AJP: Renal Physiology 295 (4): F1117. doi:10.1152/ajprenal.90317.2008. PMC 2576148. PMID 18701625. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2576148. 
  63. ^ "Renal Vasodilatory Action of Dopamine in Patients With Heart Failure: Magnitude of Effect and Site of Action". Circulation. 2008;117:200-205. http://www.circ.ahajournals.org/cgi/content/full/117/2/200. Retrieved 2009-04-20. 
  64. ^ a b c Shen, Howard (2008). Illustrated Pharmacology Memory Cards: PharMnemonics. Minireview. pp. 8. ISBN 1-59541-101-1. 
  65. ^ "Dopamine and Dextrose". Drugs.com. http://www.drugs.com/pro/dopamine-and-dextrose.html. Retrieved 2009-04-20. 
  66. ^ a b Bronwen Jean Bryant; Kathleen Mary Knights (15 November 2009). Pharmacology for Health Professionals (2nd ed.). Elsevier Australia. p. 192. ISBN 9780729539296. http://books.google.com/books?id=TQV6sLzYsOYC&pg=PA119. Retrieved 9 June 2011. 
  67. ^ McKenna, F; McLaughlin, PJ; Lewis, BJ; Sibbring, GC; Cummerson, JA; Bowen-Jones, D; Moots, RJ. (2002). "Dopamine receptor expression on human T- and B-lymphocytes, monocytes, neutrophils, eosinophils and NK cells: a flow cytometric study". J Neuroimmunol 132 (1-2): 34–40. doi:10.1016/S0165-5728(02)00280-1. PMID 12417431. 
  68. ^ Mignini, F; Streccioni, V; Amenta, F (2003). "Autonomic innervation of immune organs and neuroimmune modulation.". Autonomic & autacoid pharmacology 23 (1): 1–25. doi:10.1046/j.1474-8673.2003.00280.x. PMID 14565534. 
  69. ^ Basu, S; Dasgupta, PS. (2000). "Dopamine, a neurotransmitter, influences the immune system". J Neuroimmunol 102 (2): 113–24. doi:10.1016/S0165-5728(99)00176-9. PMID 10636479. 
  70. ^ Bergquist, J; Tarkowski, A; Ekman, R; Ewing, A. (1994). "Discovery of endogenous catecholamines in lymphocytes and evidence for catecholamine regulation of lymphocyte function via an autocrine loop". Proc Natl Acad Sci U S A 91 (26): 12912–6. doi:10.1073/pnas.91.26.12912. PMC 45550. PMID 7809145. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=45550. 
  71. ^ Cosentino, M; Fietta, AM; Ferrari, M; Rasini, E; Bombelli, R; Carcano, E; Saporiti, F; Meloni, F et al. (2007). "Human CD4+CD25+ regulatory T cells selectively express tyrosine hydroxylase and contain endogenous catecholamines subserving an autocrine/paracrine inhibitory functional loop.". Blood 109 (2): 632–42. doi:10.1182/blood-2006-01-028423. PMID 16985181. http://bloodjournal.hematologylibrary.org/cgi/reprint/109/2/632. 
  72. ^ Sarkar, C; Basu, B; Chakroborty, D; Dasgupta, PS; Basu, S (2010). "The immunoregulatory role of dopamine: an update.". Brain, behavior, and immunity 24 (4): 525–8. doi:10.1016/j.bbi.2009.10.015. PMC 2856781. PMID 19896530. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2856781. 
  73. ^ Mayer, AM (2006). "Polyphenol oxidases in plants and fungi: Going places? A review". Phytochemistry 67 (21): 2318–2331. doi:10.1016/j.phytochem.2006.08.006. PMID 16973188. 
  74. ^ Van Alstyne, Kathryn L.; Nelson, Amorah V.; Vyvyan, James R.; Cancilla, Devon A. (2006). "Dopamine functions as an antiherbivore defense in the temperate green alga Ulvaria obscura". Oecologia 148 (2): 304–311. doi:10.1007/s00442-006-0378-3. http://www.springerlink.com/content/g012ht767x47223q/. Retrieved December 29, 2011. 

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