Depression pharmacokinetics

Mechanism of Action An antidepressant that appears to inhibit serotonin and norepinephrine reuptake at CNS neuronal presynaptic membranes is a less potent inhibitor of dopamine reuptake. Therapeutic Effect Relieves depression. Pharmacokinetics Well absorbed from the G1 tract. Protein binding greater than 90%. Extensively metabolized to active metabolites. Excreted primarily in urine and, to a lesser extent, in feces. Half-life 8-17 hr. 

Alderman, J., Wolkow, R., Chung, M., and Johnston, H.E (1998) Sertraline treatment of children and adolescents with obsessive-compulsive disorder or depression pharmacokinetics, tolerability, and efficacy. / Am Acad Child Adolesc Psychiatry 37 386-394. 

Geriatric factors a variety of factors, both pharmacokinetic and pharmacodynamic, that contribute to variable dmg responses in the elderly. These responses are not seen for every class of dmg. Thus, the depressant effects of the glycosides also appear to increase with aging (116,117). 

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). 

Ciraulo DA, Jaffe JH Tricyclic antidepressants in the treatment of depression associated with alcoholism. Clin Psychopharmacol 1 146—150, 1981 Ciraulo DA, Nace E Benzodiazepine treatment of anxiety or insomnia in substance abuse patients. Am J Addict 9 276—284, 2000 Ciraulo DA, Barnhill JG, Jaffe JH, et al Intravenous pharmacokinetics of 2-hydroxy-imipramine in alcoholics and normal controls. J StudAlcohol 51 366-372, 1990 Ciraulo DA, Knapp CM, LoCastro J, et al A benzodiazepine mood effect scale reliability and validity determined for alcohol-dependent subjects and adults with a parental history of alcoholism. Am J Drug Alcohol Abuse 27 339—347, 2001 Collins MA Tetrahydropapaveroline in Parkinson s disease and alcoholism a look back in honor of Merton Sandler. Neurotoxicology 25 117-120, 2004 COMBINE Study Research Group Testing combined pharmacotherapies and behavioral interventions in alcohol dependence rationale and methods. Alcohol Clin Exp Res 27 1107-1122, 2003a... 

Alcohol can affect the metabolism of trichloroethylene. This is noted in both toxicity and pharmacokinetic studies. In toxicity studies, simultaneous exposure to ethanol and trichloroethylene increased the concentration of trichloroethylene in the blood and breath of male volunteers (Stewart et al. 1974c). These people also showed "degreaser s flush"—a transient vasodilation of superficial skin vessels. In rats, depressant effects in the central nervous system are exacerbated by coadministration of ethanol and trichloroethylene (Utesch et al. 1981). 

Benzodiazepines are the evidence-based treatment of choice for uncomplicated alcohol withdrawal.17 Barbiturates are not recommended because of their low therapeutic index due to respiratory depression. Some of the anticonvulsants have also been used to treat uncomplicated withdrawal (particularly car-bamazepine and sodium valproate). Although anticonvulsants provide an alternative to benzodiazepines, they are not as well studied and are less commonly used. The most commonly employed benzodiazepines are chlordiazepoxide, diazepam, lorazepam, and oxazepam. They differ in three major ways (1) their pharmacokinetic properties, (2) the available routes for their administration, and (3) the rapidity of their onset of action due to the rate of gastrointestinal absorption and rate of crossing the blood-brain barrier. 

Compared to antipsychotics, there are even fewer studies on the prescribing patterns of antidepressants done in Asian countries. Pi etal. (1985) conducted a survey of psychotropic prescribing practices reported by psychiatrists in 29 medical schools in 9 Asian countries. Daily dose range of tricyclic antidepressants (TCAs) such as amitriptyline, imipramine, and nortriptyline in Asian countries was comparable to the practice in USA. This is despite differences found between Asian and non-Asian populations in the pharmacokinetics of TCAs (Pi et al, 1993). A questionnaire on the practical prescribing approaches in mood disorders administered to 298 Japanese psychiatrists was reported by Oshima et al. (1999). As first-line treatment, the majority of respondents chose newer TCAs or non-TCAs for moderate depression and older TCAs for severe depression. Combination of antidepressants and anxiolytics was preferred in moderate depression, while an antidepressant and antipsychotic combination was common in severe psychotic depression. Surprisingly, sulpiride was the most favored drug for dysthymia. In a naturalistic, prospective follow-up of 95 patients with major depression in Japan, the proportion of patients receiving 125 mg/day or less of imipramine was 69% at one month and 67% at six months (Furukawa et al., 2000). 

Drug interactions with the BZs are generally pharmacodynamic or pharmacokinetic (Table 68-11). The combination of BZs with alcohol or other CNS depressants may be fatal. 

For more information on the side effects, pharmacokinetics, and drug interactions of specific agents, refer to Chap. 71 on Schizophrenia, Chap. 70 on Major Depressive Disorder, and Chap. 52 on Epilepsy. 

Thus, the long tradition of hypericum as a treatment for depression has been well supported by modern scientific research. Several active constituents have been identified, including naphthodianthrones (e.g., hypericin), phloroglucinols (e.g., hyperforin) and flavonoids (amentoflavone). Research has delineated its pharmacokinetic properties, and many of its neurochemical mechanisms have been identified enhancing monoamine... 

Kerb R, Brockmoiier J, Staffeldt B, Ploch M, Roots I. (1996). Single-dose and steady-state pharmacokinetics of hypericin and pseudohypericin. Antimicrob Agents Chemother. 40(9) 2087-93. Kim HL, Streltzer J, Goebert D. (1999). St. John s wort for depression a meta-analysis of well-defined clinical trials. J Nerv Ment Dis. 187(9) 532-38. 

The excellent clinical efficacy of the TCAs has been well documented and the pharmacokinetic profiles are favourable. The most serious disadvantage of the TCAs lies in their cardiotoxicity. Thus, with the exception of lofepramine, all the tricyclic antidepressants, including maprotiline, block the fast sodium channels in the heart which can lead to heart block and death. Approximately 15% of all patients with major depression die by suicide and a high proportion of these (up to 25%) do so by taking an overdose of TCAs. Such a dose can be as low as 5-10 times the recommended daily dose. 

Pharmacology Bretylium tosylate inhibits norepinephrine release by depressing adrenergic nerve terminal excitability, inducing a chemical sympathectomy-like state. Bretylium blocks the release of norepinephrine in response to neuron stimulation. Peripheral adrenergic blockade causes orthostatic hypotension but has less effect on supine blood pressure. It has a positive inotropic effect on the myocardium. Pharmacokinetics Peak plasma concentration and peak hypotensive effects are seen within 1 hour of IM administration. However, suppression of premature ventricular beats is not maximal until 6 to 9 hours after dosing, when mean plasma concentration declines to less than 50% of peak level. Antifibrillatory effects occur within minutes of an IV injection. Suppression of ventricular tachycardia and other ventricular arrhythmias develops more slowly, usually 20 minutes to 2 hours after parenteral administration. 

Patients 13 years of age and older- 0.3 mg IM or slow IV, every 6 hours, as needed. Repeat once (up to 0.3 mg) if required, 30 to 60 minutes after initial dosage, giving consideration to previous dose pharmacokinetics use thereafter only as needed. In high-risk patients (eg, elderly, debilitated, presence of respiratory disease) or in patients where other CNS depressants are present, such as in the immediate postoperative period, reduce dose by about 50%. Exercise extra caution with the IV route of administration, particularly with the initial dose. 

Pharmacokinetics Dimenhydrinate has a depressant action on hyperstimulated labyrinthine function. The precise mode of action is not known. The antiemetic effects are believed to be caused by the diphenhydramine, an antihistamine also used as an antiemetic agent. 

In normal subjects the tricyclics only show anticholinergic and sedative activity but have no mood elevating action. In depressed subjects their mood elevating effect has a delay of 2-3 weeks. The reasons for this delay are unknown and could be both pharmacokinetic or pharmacodynamic in natme. 

---