Anxiolytics, other Interactions with

Medications that have been used as treatment for anxiety and depression in the postwithdrawal state include antidepressants, benzodia2epines and other anxiolytics, antipsychotics, and lithium. In general, the indications for use of these medications in alcoholic patients are similar to those for use in nonalcoholic patients with psychiatric illness. However, following careful differential diagnosis, the choice of medications should take into account the increased potential for adverse effects when the medications are prescribed to alcoholic patients. For example, adverse effects can result from pharmacodynamic interactions with medical disorders commonly present in alcoholic patients, as well as from pharmacokinetic interactions with medications prescribed to treat these disorders (Sullivan and O Connor 2004). 

From the examination of structure-activity relationships, it has been concluded that a phenyl moiety at C-6 as well as a 4-hydroxypiperidine side-chain attached to C-3 of the pyridazine system is essential for anticonvulsant activity in this class of compounds [184], Compounds (54) and (55) have been found to have similar anticonvulsant profiles in animals (mice, rats and baboons) [165, and literature cited therein] and to represent potent broad-spectrum antiepileptic drugs. Their potency with regard to antagonizing seizures (induced by electro-shock or various chemicals) has been compared with standard anticonvulsants like carbamazepine and phenobarbitone [185, 186], A quantitative electroencephalographic analysis of (55) has been published [187]. From in vitro studies it has been concluded that the anticonvulsant activities of these compounds are not mediated by an enhancement of GABAergic transmission or by an interaction with benzodiazepine receptor sites [ 165,186,187], On the other hand, in vivo experiments showed that (54), at anticonvulsant doses, increases the affinity of flunitrazepam for its central receptor site [ 186], Investigations of (54) and (55) in a behavioural test predictive of antianxiety activity revealed a marked difference in the pharmacological profiles of these structurally closely related compounds the dichloro compound SR 41378 (55) has also been found to possess anxiolytic (anticonflict) properties [165],... 

This section describes the partial agonists and the nonbenzodiazepine drugs that act at the benzodiazepine receptor. What these drugs have in common is that their development has been driven by the search for effective anxiolytics that do not have the adverse effects of sedation, amnesia, ataxia, interaction with alcohol, or the problems of tolerance, dependency, and withdrawal seen with classic benzodiazepines. These problems have been addressed by the development of partial agonists, subtype-selective ligands, and other drugs, the cyclopyrrolones, which do not seem to cause these problems. 

Several partial agonists are currently in development. Some are described in this section, others are described in the sections on subtype-selective drugs and the cyclopyrrolones. The work so far has tended to show the hoped-for features of lack of adverse effects, lack of interaction with alcohol, and reduced liability to cause tolerance, in addition to being effective anxiolytics. 

Nonbenzodiazepine anxiolytic. Busprione (Bu-Spar) is the first in a class of drugs that specifically work as anxiolytics. In addition to exerting no sedative effect, this medication poses few of the disadvantages associated with the benzodiazepines—such as physical or psychological dependency—and does not significantly interact with most other compounds. 

This does not mean, of course, that BZDs represent the ultimate in anxiolytic-hypnotic agents. In spite of their usefulness and apparently greater safety, they are not single-effect drugs. If one were to use them as hypnotics, then one must still consider their muscle-relaxant properties and interactions with alcohol and other CNS-depressant compounds. 

Other drugs The anxiolytic ding buspirone interacts with the S-HT, subclass of brain serotonin receptors as a partial agonist, but the precise mechanism of its anxiolytic effect is unknown. The hypnotics zolpidem and zaleplon are not benzodiazepines but appear to exert their CNS effects via interaction with certain benzodiazepine receptors, classified as BZ, or omega, subtypes their CNS depressant effects are antagonized by flumazenil. 

Buspirone has selective anxiolytic effects, and its pharmacologic characteristics are different from those of other drugs described in this chapter. Buspirone relieves anxiety without causing marked sedative, hypnotic, or euphoric effects. Unlike benzodiazepines, the drug has no anticonvulsant or muscle relaxant properties. Buspirone does not interact directly with GABAergic systems. It may exert its anxiolytic effects by acting as a partial agonist at brain 5-HTia receptors, but it also has affinity for brain dopamine D2 receptors. Buspirone-treated patients show no... 

The effects of rifampicin on the pharmacokinetics and pharmacodynamics of buspirone were investigated in 10 young healthy volunteers. There was a significant reduction in the effects of buspirone in three of the six psychomotor tests used after rifampicin pretreatment. The interaction between rifampicin and buspirone is probably mostly due to increased CYP3A4 activity. Buspirone will most likely have a greatly reduced anxiolytic effect when it is used together with rifampicin or other potent inducers of CYP3A4, such as phenytoin and carbamazepine... 

Pharmacodynamic interactions. Many TCAs cause sedation and therefore co-prescription with other sedative agents such as opioid analgesics, antihistamines, anxiolytics, hypnotics and alcohol may lead to excessive drowsiness and daytime somnolence. The majority of TCAs can have undesirable cardiovascular effects, in particular prolongation of the QT interval. A similar risk of QT prolongation arises with many other cardiovascular drugs including amiodarone, disopyramide, procainamide, propa-... 

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