Dopamine adverse effects

Disulfiram produces a variety of adverse effects, which commonly include drowsiness, lethargy, and fatigue (Chick 1999). Other more serious adverse effects, such as optic neuritis, peripheral neuropathy, and hepatotoxicity, are rare. Psychiatric effects of disulfiram are also uncommon. They probably occur only at higher dosages of the drug and may result from the inhibition by disulfiram of a variety of enzymes in addition to ALDH. Included among the enzymes inhibited by disulfiram is dopamine P-hydroxylase, inhibition of which increases dopamine levels, which in turn can exacerbate psychotic symptoms in patients with schizophrenia and occasionally may result in psychotic or depressive symptoms in patients without schizophrenia. 

A recent meta-analysis was performed on all published human trials that used low-dose dopamine in the prevention or treatment of ARE20 A total of 61 studies were identified that randomized more than 3300 patients to low-dose dopamine or placebo. Results reveal no significant difference between the treatment and control groups for mortality, requirement for RRT, or adverse effects. 

Low-dose dopamine is not without adverse reactions and most studies have failed to evaluate its potential toxicities. Adverse reactions that may be associated with low-dose dopamine include tachycardia, arrhythmias, myocardial ischemia, depressed respiratory drive, and gut ischemia. Low-dose dopamine has also been postulated to impair resistance to infection through a reduction in prolactin concentrations.21 Furthermore, significant overlap in receptor activation occurs. Therefore, doses considered to activate only dopamine receptors may increase cardiac output and blood pressure through dopamine s effect on 3- or a-adrenergic receptors. 

Develop a formal plan to assess response and adverse effects of dopamine agonists. When appropriate, be sure to make dose adjustments. 

The answer is d. (Katz ng, pp 464-4670 Adding carbidopa decreases the amount of dopamine that is formed peripherally from dopa by dopa decarboxylase Depression, psychosis, and other psychiatric adverse effects of L-dopa are mediated by CN5 dopamine, so adding carbidopa does not make them less likely The combination of L-dopa and carbidopa reduces the extracerebral metabolism of L-dopa, resulting in decreased peripheral adverse effects. 

D5 has slightly different properties than D4, and it does not have any estrogenic activity [289]. It does, however, also have adverse effects on the reproductive system, much like D4, but also on the adipose tissue, bile production, and even immune system due to D5 s effect of reducing the prolactin levels [291]. In addition, it was determined that D5 causes a significant increase in uterine tumors in rats after a 160 ppm exposure. However, it is proposed that the tumors occur in rats through a mechanism that would not affect humans [291]. D5 also acts as a dopamine agonist and it can cause adverse effects on the nervous system in humans [291]. For exposures to D6 in rats, an increase in liver and thyroid mass and reproductive effects were observed [292]. 

Dopamine antagonist activity is the hallmark of classical neuroleptics. The antihypertensive agents, reserpine (obsolete) and a-methyldopa, deplete neuronal stores of the amine. A common adverse effect of dopamine antagonists or depletors is parkinsonism. 

Dopamine receptor agonists. Deficient dopaminergic transmission in the striatum can be compensated by ergot derivatives (bromocriptine p. 114], lisu-ride, cabergoline, and pergolide) and nonergot compounds (ropinirole, prami-pexole). These agonists stimulate dopamine receptors (D2, D3, and D sub-types), have lower clinical efficacy than levodopa, and share its main adverse effects. 

Adverse Effects. Clinically most important and therapy-limiting are ex-trapyramidal disturbances these result from dopamine receptor blockade. 

Neuroleptic activity profiles. The marked differences in action spectra of the phenothiazines, their derivatives and analogues, which may partially resemble those of butyrophenones, are important in determining therapeutic uses of neuroleptics. Relevant parameters include antipsychotic efficacy (symbolized by the arrow) the extent of sedation and the ability to induce ex-trapyramidal adverse effects. The latter depends on relative differences in antagonism towards dopamine and acetylcholine, respectively (p. 188). Thus, the butyrophenones carry an increased risk of adverse motor reactions because Lullmann, Color Atlas of Pharmacology 2000 Thieme All rights reserved. Usage subject to terms and oonditlons of lloense. 

Levodopa, the metabolic precursor of dopamine, is the most effective agent in the treatment of Parkinson s disease but not for drug-induced Parkinsonism. Oral levodopa is absorbed by an active transport system for aromatic amino acids. Levodopa has a short elimination half-life of 1-3 hours. Transport over the blood-brain barrier is also mediated by an active process. In the brain levodopa is converted to dopamine by decarboxylation and both its therapeutic and adverse effects are mediated by dopamine. Either re-uptake of dopamine takes place or it is metabolized, mainly by monoamine oxidases. The isoenzyme monoamine oxidase B (MAO-B) is responsible for the majority of oxidative metabolism of dopamine in the striatum. As considerable peripheral conversion of levodopa to dopamine takes place large doses of the drug are needed if given alone. Such doses are associated with a high rate of side effects, especially nausea and vomiting but also cardiovascular adverse reactions. Peripheral dopa decarboxylase inhibitors like carbidopa or benserazide do not cross the blood-brain barrier and therefore only interfere with levodopa decarboxylation in the periphery. The combined treatment with levodopa with a peripheral decarboxylase inhibitor considerably decreases oral levodopa doses. However it should be realized that neuropsychiatric complications are not prevented by decarboxylase inhibitors as even with lower doses relatively more levodopa becomes available in the brain. 

Amantadine was originally introduced as an antiviral compound (see Chapter 50), but it is modestly effective in treating symptoms of parkinsonism. It is useful in the early stages of parkinsonism or as an adjunct to levodopa therapy. Its mechanism of action in parkinsonism is not clear, but amantadine may affect dopamine release and reuptake. Additional sites of action may include antagonism at muscarinic and A-methyl-D-aspartate (NMDA) receptors. Adverse effects include nausea, dizziness, insomnia, confusion, hallucinations, ankle edema, and livedo reticularis. Amantadine and the anticholinergics may exert additive effects on mental functioning. 

Di Rocco A, Brannan T, Prikhojan A, et al Sertraline induced parkinsonism a case report and an in-vivo study of the effect of sertraline on dopamine metabolism. J Neural Transm 105 247—251, 1998 Doughty Ml, Lyle WM Medications used to prevent migraine headaches and their potential ocular adverse effects. Optom Vis Sci 72 879-891, 1995... 

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