On central effects of serotonin re-uptake inhibitors: Quantitative EEG and psychometric studies with sertraline and zimelidine

Saletu, B.; Grünberger, J; Linzmayer, L

doi:10.1007/bf01243351

Cited by 74 publications

(47 citation statements)

References 24 publications

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“…In the 50 to 300 mg dose range, it exhibited a typical desipramine profile with a marked increase in alpha activity and, even with the highest dose, an increase in beta energies [16,17]. These activating properties were confirmed by improvements in attention and concentration evidenced by psychometric tests [16].…”

Section: Eegmentioning

confidence: 56%

EEG profile of litoxetine after single and repeated administration in healthy volunteers.

Patat¹,

Trocherie²,

Thebault³

et al. 1994

Brit J Clinical Pharma

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1 Litoxetine is a selective serotonin reuptake inhibitor with antidepressant activity in animal models and in depressed patients. 2 This double-blind, cross-over, placebo-controlled study was carried out in 12 healthy young male volunteers. The aim was to assess the EEG profile of litoxetine in parallel with its pharmacokinetics after a single dose or multiple administrations for 4 days (6 doses) of two dosages (10 mg and 25 mg). Spectral analysis of four EEG leads (F4-T4, F3-T3, T4-02 and T3-01) was done up to 12 h post-dose. 3 In single or multiple doses, litoxetine induced EEG changes characterised by a doserelated increase in fast beta energies, mainly beta 2, without any changes in slow waves (delta and theta). A slight reduction in alpha activity occurred only after repeated doses. 4 EEG changes occurred after a single oral administration and lasted at least 12 h with litoxetine blood concentrations ranging from 4 to 10 ng ml-'. With repeated administrations, the pharmacodynamic steady-state was achieved as the increase in beta 2 energies was the same before and 12 h post-dose. These effects occurred with litoxetine blood concentrations ranging from 3 to 7 ng ml-1 with the 10 mg dosage and from 8 to 18 ng ml-1 with the 25 mg dosage. The EEG profile did not change after 4 days of repeated administration, indicating that tolerance did not develop. 5 Cmax and AUC showed proportionality between the administered dosages of 10 and 25 mg. Mean tmax ranged from 3 to 4 h and mean elimination half-life from 7 to 9 h independently of the dosage. Pharmacokinetic steady-state was achieved on day 4. Litoxetine did not accumulate with a twice daily regimen. 6 In conclusion, the EEG profile of litoxetine resembles those previously described with non-sedative antidepressants. Such EEG changes generally occur at therapeutic dosages.

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Section: Eegmentioning

confidence: 56%

EEG profile of litoxetine after single and repeated administration in healthy volunteers.

Patat¹,

Trocherie²,

Thebault³

et al. 1994

Brit J Clinical Pharma

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Section: Discussionmentioning

confidence: 74%

“…This was surprising, considering the mydriatic effects demonstrated in a study of citalopram [12] and studies of other SSRIs [12,20,21]. The mydriatic effect of SSRIs has previously been explained by an increased sympathetic outflow of noradrenaline [12,21,22], but this may not be the case. Several SSRIs, including escitalopram and citalopram, have actually been demonstrated to decrease the firing activity of the noradrenergic neurons [23,24].…”

Section: Discussionmentioning

confidence: 74%

Impact of CYP2C19 phenotypes on escitalopram metabolism and an evaluation of pupillometry as a serotonergic biomarker

Noehr-Jensen

Zwisler

Larsen³

et al. 2009

Eur J Clin Pharmacol

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Purpose To investigate the impact of cytochrome P450 2C19 (CYP2C19) phenotypes on escitalopram metabolism and to evaluate pupillometry as a serotonergic biomarker. Methods This was a double-blind, crossover design study with single and multiple doses of 10 mg escitalopram and placebo in panels of CYP2C19 extensive (EM) and poor metabolisers (PM). Pupillometry was measured by a NeurOptics Pupillometer-PLR. Results Five PM and eight EM completed the study. The CYP2C19 phenotype significantly affected the metabolism of escitalopram. The area under the time-plasma concentration curve (AUC 0-24 ) was 1.8-fold higher in PM than in EM after both single and multiple doses. Escitalopram treatment did not affect the maximum pupil size, but it did statistically significantly decrease the relative amplitude of the pupil light reflex compared to the placebo; this effect was equal in both phenotype groups. Conclusions The CYP2C19 polymorphism affects escitalopram metabolism, but the difference does not justify dose adjustment. The puzzling results from pupillometry can be due to interplay between a central and a local serotonergic effect. Based on these results, pupillometry can not be recommended as a serotonergic biomarker.

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Section: Previous Studies Have Shown That Changes In Brain Functionmentioning

confidence: 99%

“…Prior work with "pharmaco-EEG" techniques has shown that the administration of antidepressant compounds yields reproducible changes in EEG activity in healthy control subjects within a few hours of dosing (Saletu et al 1982(Saletu et al , 1983(Saletu et al , 1986(Saletu et al , 1987(Saletu et al , 1987Grunberger 1985, 1988;Sannita et al 1983;Sannita 1990;Itil et al 1984;Herrmann et al 1991;Luthringer et al 1996). The relationship of these immediate EEG changes in control subjects to eventual clinical response in a depressed population is unclear.…”

mentioning

confidence: 99%

Early Changes in Prefrontal Activity Characterize Clinical Responders to Antidepressants

Cook¹,

Leuchter

Morgan

et al. 2002

Neuropsychopharmacology

182

169

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Previous studies have shown that changes in brain functionClinicians long have observed a lag time of several weeks between the initiation of antidepressant treatment and clinical response for many patients (Hyman and Nestler 1996;Katz et al. 1996). Some individuals do have early symptomatic improvement, and this has been reported to predict further improvement over the next several weeks (Nierenberg et al. 1995). Reports have suggested that some physiologic changes are seen shortly after initiation of treatment (Sulser 1989;Beck 1995;Dahmen et al. 1997). No clinically practical physiologic predictor of treatment response has yet been identified with these techniques, however, and the relationship of early physiologic changes to eventual clinical outcome remains incompletely understood.Quantitative electroencephalography (QEEG) has been used as a physiologic measure in efforts to address these questions. Prior work with "pharmaco-EEG" techniques has shown that the administration of antidepressant compounds yields reproducible changes in EEG activity in healthy control subjects within a few hours of dosing (Saletu et al. 1982(Saletu et al. , 1983(Saletu et al. , 1986(Saletu et al. , 1987(Saletu et al. , 1987 Grunberger 1985, 1988;Sannita et al. 1983;Sannita 1990; Early Prefrontal Changes in Depression 121Itil et al. 1984;Herrmann et al. 1991;Luthringer et al. 1996). The relationship of these immediate EEG changes in control subjects to eventual clinical response in a depressed population is unclear. Other QEEG work with depressed subjects has found that changes from baseline in theta power early in the course of treatment may characterize groups of depressed patients who are more likely to respond to antidepressant treatment (Ulrich et al. 1994). Unfortunately, the overlap in the value of these changes between responder and nonresponder groups precluded the use of this measure in response prediction for individual subjects, and prior research did not indicate how to relate changes in theta power to other measures of regional brain activity (e.g., regional cerebral blood flow or metabolism). We previously have shown that absolute and relative power are complementary measures of brain activity (Leuchter et al. 1993). A relatively new QEEG measure, "cordance," combines information from both absolute and relative power measures (Leuchter et al. 1994a(Leuchter et al. , 1994b. The algorithm yields two indicators: a categorical value ("concordant" or "discordant" state) and a numerical value for each electrode. In an earlier report with the categorical measure , we observed that depressed subjects exhibiting the concordant state prior to treatment had better treatment outcomes when treated with fluoxetine than did subjects with the discordant state. In this report, we use the num*erical values of cordance, because they allow examination of changes in regional brain activity with treatment. In validation against data collected simultaneously with [H 2 15O]-positron emission tomography (PET), cordance values in the the...

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On central effects of serotonin re-uptake inhibitors: Quantitative EEG and psychometric studies with sertraline and zimelidine

Cited by 74 publications

References 24 publications

EEG profile of litoxetine after single and repeated administration in healthy volunteers.

EEG profile of litoxetine after single and repeated administration in healthy volunteers.

Impact of CYP2C19 phenotypes on escitalopram metabolism and an evaluation of pupillometry as a serotonergic biomarker

Early Changes in Prefrontal Activity Characterize Clinical Responders to Antidepressants

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