Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Neuroleptics typical

The role of fluonne in the development of CNS agents has been reviewed [14] Ruonnated phenothiazines, typified by fluphenazine (7[Pg.1121]

Typical antipsychotic drugs Neuroleptic dtugs conventional antipsychotic diugs older antipsychotic diugs ... [Pg.180]

Dailey, JW (1992) Typical and atypical neuroleptic drug effects on dopamine and other neurotransmitter functions in rodents. PhD thesis, University of London, p. 125. [Pg.160]

Figure 17.5 Possible scheme for the initiation of depolarisation block of DA neurons. In (a) the excitatory effect of glutamate released on to the DA neuron from the afferent input is counteracted by the inhibitory effect of DA, presumed to be released from dendrites, acting on D2 autoreceptors. In the absence of such inhibition due to the presence of a typical neuroleptic (b) the neuron will fire more frequently and eventually become depolarised. At5q)ical neuroleptics, like clozapine, will be less likely to produce the depolarisation of A9 neurons because they are generally weaker D2 antagonists and so will reduce the DA inhibition much less allowing it to counteract the excitatory input. Additionally some of them have antimuscarinic activity and will block the excitatory effect of ACh released from intrinsic neurons (see Fig. 17.7)... Figure 17.5 Possible scheme for the initiation of depolarisation block of DA neurons. In (a) the excitatory effect of glutamate released on to the DA neuron from the afferent input is counteracted by the inhibitory effect of DA, presumed to be released from dendrites, acting on D2 autoreceptors. In the absence of such inhibition due to the presence of a typical neuroleptic (b) the neuron will fire more frequently and eventually become depolarised. At5q)ical neuroleptics, like clozapine, will be less likely to produce the depolarisation of A9 neurons because they are generally weaker D2 antagonists and so will reduce the DA inhibition much less allowing it to counteract the excitatory input. Additionally some of them have antimuscarinic activity and will block the excitatory effect of ACh released from intrinsic neurons (see Fig. 17.7)...
Second, although typical neuroleptics produce depolarisation block of both A9 and AlO neurons, the atypical neuroleptics only induce it in AlO neurons (Chiodi and Bunney 1983). So after an atypical neuroleptic the A9 neurons of the nigrostriatal tract remain functional, which would explain why EPSs are not seen. Another difference is seen with the expression of an immediate-early gene, c-fos, and although its functional significance is not clear, typical neuroleptics induce its protein production in both the striatum and nucleus accumbens while the atypicals only achieve it in the accumbens. [Pg.362]

There is certainly evidence that whereas typical neuroleptics are equally active in mesolimbic/cortical areas as well as the striatum, the atypical drugs are much less effective in the latter. This has been shown by (1) increased DA turnover through DOPAC and HVA production in vitro, (2) augmented DA and DOPAC release by microdialysis in vivo and (3) increased c-fos- ike, expression. [Pg.364]

Its activity at Di receptors has been put forward as a possibility and although it has a relatively higher affinity for Di than Dj receptors, compared with typical neuroleptics, it is still a weak antagonist at both and in the absence of evidence for Di (or D5) receptor involvement in schizophrenia the significance of any Di antagonism is unclear. [Pg.364]

Generally most atypical neuroleptics have higher affinity for 5-HT2 than D2 receptors while typical ones retain a preference for the D2 receptor. There is, however, no infallible separation since chlorpromazine (typical neuroleptic) is more active at 5-HT2A... [Pg.365]

Figure 17.7 Possible mechanism by which atypical neuroleptics with antimuscarinic activity produce few EPSs. Normally the inhibitory effects of DA released from nigrostriatal afferents on to striatal neuron D2 receptors is believed to balance the excitatory effect of ACh from intrinsic neurons acting on muscarinic (M2) receptors (a). Typical neuroleptics block the inhibitory effect of DA which leaves unopposed the excitatory effect of ACh (b) leading to the augmented activity of the striatal neurons and EPSs (see Fig. 15.2). An atypical neuroleptic with intrinsic antimuscarinic activity reduces this possibility by counteracting the excitatory effects of released ACh as well as the inhibitory effects of DA (c). Thus the control of striatal neurons remains balanced... Figure 17.7 Possible mechanism by which atypical neuroleptics with antimuscarinic activity produce few EPSs. Normally the inhibitory effects of DA released from nigrostriatal afferents on to striatal neuron D2 receptors is believed to balance the excitatory effect of ACh from intrinsic neurons acting on muscarinic (M2) receptors (a). Typical neuroleptics block the inhibitory effect of DA which leaves unopposed the excitatory effect of ACh (b) leading to the augmented activity of the striatal neurons and EPSs (see Fig. 15.2). An atypical neuroleptic with intrinsic antimuscarinic activity reduces this possibility by counteracting the excitatory effects of released ACh as well as the inhibitory effects of DA (c). Thus the control of striatal neurons remains balanced...
What is obvious from all the experimental evidence is that it is easier to unravel the cause of the undesirable than it is to explain the desirable effects of neuroleptic drugs. EPSs occur because such drugs all have some D2 antagonist activity and so reduce DA transmission in the striatum. The degree to which they achieve this and whether they are typical or atypical depends on their affinity for D2 striatal receptors, since EPSs... [Pg.369]

Figure 17.9 Schematic representation of the proposed activity profile of an ideal neuroleptic. The figure shows DA pathways to the prefrontal cortex, mesolimbic nucleus accumbens and striatum the effects required for an ideal drug on the DA influence and symptoms there and to what extent they are met by most typical and atypical neuroleptics and by clozapine. Note that while all atypical neuroleptics induce few extrapyramidal w side-effects (EPSs) few of them, apart from clozapine, have much beneficial effect in overcoming negative symptoms of schizophrenia ... Figure 17.9 Schematic representation of the proposed activity profile of an ideal neuroleptic. The figure shows DA pathways to the prefrontal cortex, mesolimbic nucleus accumbens and striatum the effects required for an ideal drug on the DA influence and symptoms there and to what extent they are met by most typical and atypical neuroleptics and by clozapine. Note that while all atypical neuroleptics induce few extrapyramidal w side-effects (EPSs) few of them, apart from clozapine, have much beneficial effect in overcoming negative symptoms of schizophrenia ...
Chiodi, LA and Bunney, BS (1983) Typical and at q)ical neuroleptics differential effects of chronic administration on the activity of A9 and AlO midbrain dopamine neurones. J. Neurosci. 3 1607-1619. [Pg.372]

Malhotra etal. (1996a) HTR2A (T102C/H452T) Clozapine, typical neuroleptics No association. Schizophrenia or schizoaffective disorder Caucasian... [Pg.74]

Chlorpromazine is technically described as a phenothiazine, as are thioridazine and fluphenazine. Together with their structural analogues the thioxanthenes (e.g., clopenthixol) and the butyrophenones (e.g., haloperidol), the phenothiazines comprise the three major families of typical neuroleptics. They were developed in the late 1950s and early 1960s (Table 11.3). All these drugs block dopamine receptors, principally the D2 subtypes, with an affinity that correlates highly (r = +0.90) with their clinical... [Pg.165]

List the principal side effects or adverse drug reactions of a typical neuroleptic. [Pg.170]

Butyrophenones A family of typical antipsychotic drugs (neuroleptics), the most commonly used being haloperidol. [Pg.239]

Thioridazine A typical neuroleptic but with fewer side effects. [Pg.249]

Thioxanthenes A family of typical neuroleptics including clopenthixol. [Pg.249]

Non-motor signs of the disorder are also treatable with symptomatic medications. The frequent mood disorder can be treated with standard antidepressants, including tricyclics (such as amitryptiline) or serotonin reuptake inhibitors (SSRIs, such as fluoxetine or sertraline). This treatment is not without risks in these patients, as it may trigger manic episodes or may even precipitate suicide. Anxiety responds to benzodiazepines, as well as to effective treatment of depression. Long-acting benzodiazepines are favored over short-acting ones because of the lesser abuse potential. Some of the behavioral abnormalities may respond to treatment with the neuroleptics as well. The use of atypical neuroleptics, such as clozapine is preferred over the typical neuroleptics as they may help to control dyskinesias with relatively few extrapyramidal side-effects (Ch. 54). [Pg.773]

Many antipsychotics show great interindividual variation in plasma levels and so analysis of therapeutic levels can be important clinically as well as in the research laboratory. In addition, nonresponse to the drugs may actually be due to excessive levels of neuroleptics, a paradoxical situation that requires analysis to identify (Rockland, 1986). Several methods using FID were cited in the previous edition of the Handbook of Neurochemistry but ECD and NPD have both shown utility for the typically low therapeutic levels (Cooper, 1988). GC-FID has been used to analyze levels of clozapine in blood, gastric, and urine samples in fatal cases of overdose with this drug (Ferslew et al., 1998), and olanzapine has been measured in blood and urine samples by GC-NPD in overdoses (Stephens et al., 1998). 4-(4-Chlorophenyl)-4-hydroxypiperidine, a metabolite of haloperidol, was analyzed in urine, plasma, brain, and liver from haloperidol-treated rats by GC-ECD, after derivatization with PFBC under aqueous conditions (Fang et al., 1996). [Pg.11]

A more detailed discussion of the pharmacological properties of typical and atypical neuroleptics is given in Chapter 11. [Pg.147]

In CONCLUSION, lithium is universally accepted as a mood-stabilizing drug and an effective antimanic agent whose value is limited by its poor therapeutic index (i.e. its therapeutic to toxicity ratio). Neuroleptics are effective in attenuating the symptoms of acute mania but they too have serious adverse side effects. High potency typical neuroleptics appear to increase the likelihood of tardive dyskinesia. Of the less well-established treatments, carbamazepine would appear to have a role, particularly in the more advanced stages of the illness when lithium is less effective. [Pg.210]

Wahlbeck K, Cheine M, Essali MA. Clozapine versus typical neuroleptic medication for schizophrenia. Cochrane Database Syst Rev 1999. Issue 4. [Pg.684]

See other pages where Neuroleptics typical is mentioned: [Pg.98]    [Pg.14]    [Pg.98]    [Pg.14]    [Pg.183]    [Pg.183]    [Pg.834]    [Pg.1253]    [Pg.1504]    [Pg.193]    [Pg.359]    [Pg.363]    [Pg.365]    [Pg.367]    [Pg.93]    [Pg.165]    [Pg.166]    [Pg.167]    [Pg.64]    [Pg.66]    [Pg.954]    [Pg.194]    [Pg.48]    [Pg.170]    [Pg.351]    [Pg.678]    [Pg.693]    [Pg.91]    [Pg.328]    [Pg.328]   


SEARCH



Neuroleptics

© 2024 chempedia.info