Dopaminergic neurotransmission

Unlike aniracetam, pramiracetam does not appear to interact with dopaminergic, serotonergic, or adrenergic neurotransmission (72). The agent inhibits prolylendopeptidase in certain brain areas, but its inhibition constant, iC, is only 11 ]lM (69). The absence or weak activity of this compound with various neuronal systems appears to make it less likely to be of significant therapeutic value than other members of this class of agents. 

At low doses, both psychostimulants could theoretically stimulate tonic, extracellular levels of monoamines, and the small increase in steady state levels would produce feedback inhibition of further release by stimulating presynaptic autoreceptors. While this mechanism is clearly an important one for the normal regulation of monoamine neurotransmission, there is no direct evidence to support the notion that the doses used clinically to treat ADHD are low enough to have primarily presynaptic effects. However, alterations in phasic dopamine release could produce net reductions in dopamine release under putatively altered tonic dopaminergic conditions that might occur in ADHD and that might explain the beneficial effects of methylphenidate in ADHD. 

Because chronic cocaine use appears to reduce the efficiency of central dopamine neurotransmission, a number of dopaminergic compounds, including amantadine, bromocriptine, mazindol, and methylphenidate, have been examined as treatments for cocaine abuse. It is thought that these relatively slow-onset dopaminergic agents, with low or relatively low abuse potential, would correct the dopamine dysregulation and alleviate withdrawal symptoms following chronic stimulant use. 

There are few reports on the effects of nitrous oxide on dopaminergic neurotransmission. A study in mice showed that nitrous oxide inhalation produced a significant increase in locomotor activity that was antagonized in a dose-dependent fashion by the dopamine synthesis inhibitor a-methyl-/)-tyrosine (Hynes and Berkowitz 1983). Moreover, administration of the D2 antagonist haloperidol also reduced the locomotor activity induced by nitrous oxide (Hynes and Berkowitz 1983). These results suggest that excitatory effects induced by nitrous oxide may be also mediated by dopaminergic neurotransmission. However, other studies have reported that exposure to nitrous oxide resulted in decreased dopamine release by neurons in the striatum (Balon et al. 2002 Turle et al. 1998). 

A number of azetidine-based compounds have been disclosed in patent applications from Aventis Pharma for CBi-modulated treatment of diseases such as obesity, Parkinson s disease, schizophrenia, respiratory and neurological diseases [330-334]. Compound (556) was specifically claimed for use in two formulation patent applications [330, 331] for a stable semi-solid composition and oral emulsion composition, respectively. The optional coadministration of an agent that activates norepinephrinergic and se-rotoninergic neurotransmission (for example, sibutramine) or dopaminergic neurotransmission was also claimed for the treatment of obesity. The optional use of a dopamine agonist (for example, levodopa) was claimed... 

This laboratory, as well as others, has shown unequivocally that PCP affects a variety of parameters related to neurotransmission in several neuronal systems. This paper has focused on evidence for the involvement of dopaminergic, cholinergic, and glutama-tergic pathways, and evidence of their interactions in the rat striatum. However, the effects of PCP undoubtedly involve other neuronal systems in other brain areas. Thus, it must be borne in mind that the data discussed in this paper cannot possibly account for the more complex behavioral effects of PCP. 

The administration of low doses of PCP to rodents induces hyperactivity and stereotypy (Chen et al. 1959 ). The observation that neuroleptics such as chlorpromazine, haloperidol, and pimozide, and adrenolytics such as alpha-methyl paratyrosine antagonize these behavioral effects of PCP suggests that they are mediated by facilitation of central dopaminergic neurotransmission (Murray and Horita 1979). The actions of PCP on central dopaminergic neurotransmission may be similar to amphetamine. A dose of PCP (2.5 mg/kg) in rats, which has no effects when given alone, enhances the behavioral effects of 1 and 3 mg/kg of d-amphetamine (Balster and Chait 1978). PCP, like dopamine, has also been shown to suppress plasma prolactin (Bayorh et al. 1983). However, the firm establishment of an excl usive relationship between dopamine neuro-transmission and PCP effects is difficult because of the prominent interactions of this drug with other neurotransmitter systems. 

Figure 1.1 The dopamine transporter terminates the action of released dopamine by transport back into the presynaptic neuron. Dopamine transport occurs with the binding of one molecule of dopamine, one chloride ion, and two sodium ions to the transporter the transporter then translocates from the outside of the neuronal membrane into the inside of the neuron.22 Cocaine appears to bind to the sodium ion binding site. This changes the conformation of the chloride ion binding site thus dopamine transport does not occur. This blockade of dopamine transport potentiates dopaminergic neurotransmission and may be the basis for the rewarding effects of cocaine.

Strombom, U.H. and Liedman, B., Role of dopaminergic neurotransmission in locomotor stimulation by dexamphetamine and ethanol, Psychopharmacology, 78, 271, 1982. 

Since cocaine potentiates dopaminergic neurotransmission by binding to DA transporter and blocking reuptake, persisting increases in DA transporter function after cocaine levels have fallen... 

The D2 antagonist activity of current antipsychotics led to the "dopamine hypothesis," which states that the pathophysiology of schizophrenia is due to excessive dopaminergic neurotransmission and dysfunctional D2 signaling [6]. This hypothesis has prevailed for nearly 60 years however, it falls short as a complete explanation due to the deficiencies current antipsychotics exhibit against negative and cognitive symptoms. 

Li+, at therapeutically relevant concentrations, is a potent inhibitor of norepinephrine-stimulated adenylate cyclase activity ex vivo in both rat [133] and human brain [134], and it inhibits norepinephrine-stimulated cAMP accumulation in Li+-treated patients. Li+ also inhibits dopamine-stimulated cAMP accumulation in rat brain [135]. These inhibitory effects of Li+ have been shown to be region specific within rat brain, a fact that has obvious significance for a therapeutic mechanism of action. It is interesting that other antimanic drugs may also have dampening effects on dopaminergic neurotransmission. 

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