Status
Conditions
Treatments
About
Major depressive disorder is associated with several sleep Polysomnograph (PSG) findings: (1) impaired sleep continuity; (2) non-REM (NREM) changes; and (3) enhanced rapid eye movement (REM) sleep. The first two patterns are common in other psychiatric disorders, while the REM pattern is very characteristic in depression, so the phase-advance theory was accepted by most of psychiatrists. Many researchers have focused on the biological rhythm to investigate the etiological and pathophysiology of depression, and they think depression can be cured if its sleep abnormality is ameliorated.
It is well known that most of antidepressants treat depression through 5-hydroxytryptamine (5-HT) neurons. 5-HT also affects the regulation of the sleep-wake cycle and the sleep microarchitecture. Many all-night PSG studies have shown tricyclic antidepressants can ameliorate the sleep architecture abnormality in depression by producing rapid suppression of REM sleep.
Compared to TCAs, SSRIs are generally less sedating because of its high selectivity for serotonin receptors. SSRIs can suppress REM sleep and delay REM latency too, but they increase awakenings and reduce SWS at the same time. One PSG study shown sertraline minimally increases sleep efficiency and reduces nocturnal wakefulness time, which may benefit depressive patients. However, this study compared the sleep architecture before and after 12 weeks of pharmacotherapy, so the tolerance to the disturbance of sleep architecture in antidepressants appears to develop over several weeks of treatment. Sertraline has a greater potency against 5-HT reuptake as well as better selectivity for 5-HT reuptake relative to NE reuptake than any other SSRIs, and the relative selectivity of sertraline for inhabiting 5-HT reuptake relative to DA reuptake is somewhat less than of any other SSRIs. So it has chance to exhibit better effect on sleep architecture in depressive patients.
Finally, it is difficult to be determined that the unique phenomenon of sertraline is its genuine characteristics or the tolerance after 12-week treatment, so it is crucial to assess the effect of sertraline on sleep architecture in acute treatment. We hypothesized that sertraline could suppress the REM sleep, and have little damage to the sleep architecture of depressive patient.
Full description
[Abstract] Purpose of the study: To evaluate the effect of sertraline on polysomnographic (PSG) variables and clinical improvement in the treatment of depressive patients with insomnia. Methods used: The study design was 8-week and open-label trial. Patients were diagnosed as major depressive disorder. Their Hamilton Rating Scale for Depression (HRSD) score was more than 18, and HRSD-sleep disturbance score was more than 3. After 7-day wash-out period and 2 nights PSG (the first night as adaptive and the second night as baseline), 31 depressive patients were administered by sertraline as 50 mg in 8 am in the 1st day. The dosage of sertraline would be titrated during the 8-week treatment, and the maximum was lower than 200 mg/day. The primary endpoints were the changes of PSG variables from baseline to the 56th Day. The secondary endpoints were the changes of subjective sleep quality and clinical performance from baseline to the 56th Day. Their sleep quality was evaluated with Epworth Sleepiness Scale (ESS) and Pittsburgh Sleep Quality Index (PSQI), and their clinical performance was evaluated with HRSD and Clinical Globe Impression (CGI). Summary of results containing real data and appropriate statistical assessments: The Intent-to-Treat analysis included 31 subjects. The final dosage was titrated as 130.6±47.8 mg/day. The Rapid Eye Movement (REM) sleep latency was prolonged significantly in the 1st day and throughout 8-week treatment. The percentage of REM sleep decreased significantly in the 1st day, but increased gradually along the following treatment. AI reached the highest level in the 1st day (13.8±7.2), and decreased along the following treatment. SL decreased significantly and reached normal range (<30minutes) after the visit of 14th day. The percentage of stage 3 increased gradually, and became higher in the 14th, 28th, 56th days. HRSD score was similar between baseline and the 1st day, and became significantly lower in the 14th, 28th, and 56th day. Similar pattern was shown in CGI. Scores of HRSD-sleep disturbance, PSQI, ESS decreased gradually throughout the treatment. The sleep latency in multiple sleep latency test maintained stable throughout treatment. The reducing score rates of HRSD and CGI-GI significantly correlated with the reducing score rate of REM latency in all visits, and they also significantly correlated with sleep latency, sleep efficiency, and stage 3 in some visits. Further, significant correlation was shown between the reducing score rate of HRSD in the 56th day and the the reducing score rate of REM latency in the 1st day (r=-0.733, P=0.003). Conclusions: Sertraline was an effective antidepressant, and its effectiveness had relationship with the reduction of REM latency during the 8-week treatment. Further, the final clinical improvement could be predicted by the extent of shorten REM latency in the first night. So the suppression of REM sleep might be the key mechanism of antidepressive[1]. On the other hand, Sertraline had little alerting property without sleep disturbance in the treatment[2]. This property of sertraline must benefit the remission of depression, and the remission contributed the sleep improvement in turn. It was virtuous cycle in depressive treatment.
Enrollment
Sex
Ages
Volunteers
Inclusion criteria
For inclusion in the study patients must fulfil all of the following criteria:
Exclusion criteria
Any of the following is regarded as a criterion for exclusion from the study:
Primary purpose
Allocation
Interventional model
Masking
31 participants in 1 patient group
Loading...
Data sourced from clinicaltrials.gov
Clinical trials
Research sites
Resources
Legal