Subsensitive melatonin suppression by dim white light: possible biological marker of panic disorder

Light is involved in providing entrainment of circadian rhythms and the suppression of the pineal hormone melatonin. In patients with affective disorders, there have been indications of circadian as well as seasonal variation in illness, which may be reflected in melatonin production. Varying sensitivity to light has been noted within healthy individuals as well as in some patients with affective disorders. Recent evidence suggests that patients with panic disorder may have an altered and phase-delayed melatonin rhythm. The present study examined the nocturnal plasma melatonin rhythm in patients with panic disorder, and also examined their melatonin sensitivity to dim light. The melatonin rhythm was examined in 6 patients with panic disorder and 8 controls. The melatonin sensitivity to dim white light (200 lx) was examined in 8 patients with panic disorder and 63 controls and was compared to that of a group of 7 patients with other anxiety disorders. Patients with panic disorder demonstrated a trend towards higher and delayed peak melatonin levels compared to controls. Patients with panic disorder also had a subsensitive melatonin suppression by dim white light, compared to controls and patients with other anxiety disorders (p<0.005). The phase-delayed circadian rhythm observed in patients with panic disorder may be secondary to the subsensitivity of the melatonin response to light. It is hypothesized that the subsensitivity may be due to abnormal neurotransmitter/receptor systems involved in regulation of melatonin suppression and circadian rhythmicity, and may lead to phase- delayed circadian rhythms. The melatonin subsensitivity to light may be used as a biological marker of panic disorder.     

Melatonin sensitivity to dim white light in different seasons

It is well known that the pineal hormone melatonin is suppressed by light. The melatonin suppression by dim light has also been suggested as a possible trait marker of bipolar disorder. However, there is large inter individual differences in the light responses. It is possible that methodological factors may contribute to the variable responses observed. Most studies in the past have been conducted in different seasons under different lighting conditions. It is possible the external lighting conditions may affect the melatonin suppression to dim light. Hence we examined the melatonin suppression by dim light in (1) a large group of subjects randomly tested once in one of the four seasons (part one) and (2) small group of subjects tested in all seasons (part two). Subjects were placed in a dark room from 2100 h to 0230 h. Light exposure was between midnight and 0100 h in a sitting position. Blood samples were collected at regular intervals for measurement of plasma melatonin. No statistically significant seasonal differences in the percentage suppression of melatonin were found in both parts of the study (p>0·5). The study suggests that seasonal changes in external lighting do not affect the melatonin suppression by dim light in healthy controls. Copyright © 1999 John Wiley & Sons, Ltd.     

Effect of sodium valproate on nocturnal melatonin sensitivity to light in healthy volunteers.

Sensitivity of the pineal hormone melatonin to bright light at night has been proposed as a putative marker of bipolar affective disorder. Patients with bipolar disorder have a super-sensitive melatonin response to light. No studies have investigated whether super-sensitivity is due to agents used to treat the illness or is associated with the disorder per se. We investigated the effect of valproate on this phenomenon. Melatonin sensitivity to light was determined on two nights in 12 healthy volunteers (5M, 7F). Between testing nights participants received 200 mg of valproate b.d. for 5 days. Valproate significantly decreased the sensitivity of melatonin to light. On the other hand, valproate had no effect on overall melatonin secretion or dim light melatonin onset. The ability of valproate to decrease the sensitivity of melatonin to light may relate to its therapeutic effect in bipolar disorder--an ability to lengthen circadian period similar to that of lithium.     

The effect of age and pre-light melatonin concentration on the melatonin sensitivity to dim light.

The hormone melatonin is secreted at night from the pineal gland, with light being a potent inhibitor of its secretion. Age related decreases in plasma melatonin concentrations have indicated that this may be related to pineal calcification with aging. Recently, it was shown that the melatonin sensitivity to light may be a biological marker of bipolar disorder. However, on average, patients were older than the control group in most studies, and it is not known if age has an effect on the melatonin suppression by light. To test this hypothesis, the present study investigated the effect of age on the melatonin sensitivity to dim light (200 lux). Participants were grouped into three age groups. On the testing night, they were placed in a dark room from 21.00 h to 02.30 h. Light exposure was for an hour from midnight to 01.00 h. Blood samples were collected at regular intervals for measurement of plasma melatonin. No significant differences were found in the percentage suppression of melatonin within the age groups defined in the present study (P > 0.5). No correlation was also found between age and percentage suppression of melatonin (r2 = 0.007; P > 0.1). Our results suggest that the melatonin suppression by light (200 lux) is not affected by age.     

Low doses of lithium carbonate reduce melatonin light sensitivity in healthy volunteers

Sensitivity of the pineal hormone melatonin to bright light at night has been posited as a putative marker of affective disorders. Research demonstrates melatonin supersensitivity to light in bipolar disorder, however the role that lithium carbonate plays in this response is unclear. This study assessed the effect of lithium on nocturnal melatonin secretion and sensitivity to light in healthy adults. Ten participants, tested on two nights, had blood samples drawn between 20:00 and 02:30 hours. On testing nights participants were exposed to 200 lux of light between 24:00 and 01:00 hours. Participants took 250 mg of lithium daily for 5 d between testing nights. The results indicated that lithium had a significant effect on sensitivity to light but not on overall melatonin synthesis. This finding has implications on the true magnitude of the melatonin light response in people with bipolar disorder and may elucidate possible mechanisms of action of lithium.     

Role of melatonin in mood disorders and the antidepressant effects of agomelatine

Introduction: Disturbances of circadian rhythms and sleep play an important role in various types of mood disorders like major depressive disorder (MDD), bipolar depressive disorder (BPD) and seasonal affective disorder (SAD). Malfunctioning of the SCN-pineal-melatonin link has been suggested as the main cause for these disorders. As a rhythm-regulating factor and as a hormone involved in the regulation of sleep, melatonin is essential for the control of mood and behavior. Areas covered: Melatonin's involvement in various mood disorders is reviewed based on studies undertaken in patients with MDD, BPD and SAD. The chemistry and metabolism of the newly introduced antidepressant, agomelatine, a MT1/MT2 melatonin receptor agonist and 5-HT2c antagonist in brain areas involved in mood regulation are also discussed. Its clinical role in mood regulation, agomelatine's efficacy, safety and tolerability are also reviewed. Expert opinion: Agomelatine, a melatonergic antidepressant with a rapid onset of action, has been shown effective in various types of mood disorders (e.g., MDD, BPD, SAD). Some studies find it superior to other common antidepressants (SSRIs, SNRIs) that are in clinical use today. Agomelatine's efficacy, good tolerability and safety profile suggest that it may become a preferred antidepressant in the near future.     

Plasma melatonin levels in affective states

Melatonin is a major endocrine product of the pineal gland. It is produced at night when noradrenaline acts on beta-adrenergic receptors to stimulate enzymes which catalyse the formation of melatonin from serotonin. It is believed by some that nocturnal melatonin levels reflect beta-receptor function. The melatonin rhythm is also thought to be an indication of circadian rhythmicity. The nocturnal production of melatonin was studied in patients with depression and panic disorder and in control subjects. Midnight concentrations of melatonin in eleven depressed patients were significantly lower than 18 control subjects (27.1 +/- 5.1 pg/ml compared with 51.6 +/- 4.1 pg/ml; p less than 0.02, t-test). These data support previous reports of reduced melatonin synthesis in depressive illness. In the first report of patients with panic disorders, significantly lower midnight levels of melatonin were found compared with controls (28.4 +/- 6.4 pg/ml versus 51.6 +/- 4.1 pg/ml, p less than 0.02, t-test). In subsequent investigations this finding was confirmed, measuring melatonin levels over the initial phase of synthesis (i.e. 20h00 to 24h00). In these samples the melatonin rhythm also seemed to be delayed. These findings are discussed in terms of beta-receptor function and circadian rhythm alterations in affective disorders.     

Circadian rhythms, melatonin and depression

The master biological clock situated in the suprachiasmatic nuclei of the anterior hypothalamus plays a vital role in orchestrating the circadian rhythms of multiple biological processes. Increasing evidence points to a role of the biological clock in the development of depression. In seasonal depression and in bipolar disorders it seems likely that the circadian system plays a vital role in the genesis of the disorder. For major unipolar depressive disorder (MDD) available data suggest a primary involvement of the circadian system but further and larger studies are necessary to conclude. Melatonin and melatonin agonists have chronobiotic effects, which mean that they can readjust the circadian system. Seasonal affective disorders and mood disturbances caused by circadian malfunction are theoretically treatable by manipulating the circadian system using chronobiotic drugs, chronotherapy or bright light therapy. In MDD, melatonin alone has no antidepressant action but novel melatoninergic compounds demonstrate antidepressant properties. Of these, the most advanced is the novel melatonin agonist agomelatine, which combines joint MT1 and MT2 agonism with 5-HT(2C) receptor antagonism. Adding a chronobiotic effect to the inhibition of 5-HT(2C) receptors may explain the rapid impact of agomelatine on depression, since studies showed that agomelatine had an early impact on sleep quality and alertness at awakening. Further studies are necessary in order to better characterize the effect of agomelatine and other novel melatoninergic drugs on the circadian system of MDD patients. In summary, antidepressants with intrinsic chronobiotic properties offer a novel approach to treatment of depression.     

Clonazepam in the long-term treatment of patients with unipolar depression, bipolar and schizoaffective disorder.

The value of a long-term treatment with clonazepam in the prophylaxis of affective disorder is discussed controversially in the scientific literature. Altogether there are only a few reports on the use of this compound as a mood stabilizer, most of them describing patients suffering from bipolar affective disorder. The aim of this investigation was to evaluate clonazepam as a phase prophylactic medication in affective disorder. We conducted a retrospective chart review in 34 out-patients of our lithium clinic (15 suffering from unipolar depression, 15 from bipolar disorder, four from schizoaffective disorder), who had been treated with clonazepam as a long-term medication. Clonazepam was either given as monotherapy, or as in the case of lithium non-responders, as adjunctive therapy. Patients with unipolar depression had significantly (P=0.026) less depressive episodes after initiation of treatment with clonazepam. Patients with bipolar disorder did not benefit from this therapy. Neither manic/hypomanic phases nor depressive episodes were reduced in this group of patients. Interestingly, clonazepam also reduced affective phases in our four schizoaffective patients on a trend level. Our results indicate that patients with unipolar depression may benefit from a maintenance treatment with clonazepam. Due to methodological limitations our results need to be replicated in controlled double-blind randomized clinical trials.     

Supersensitivity to melatonin suppression by light in young people at high risk for affective disorder. A preliminary report

Affective illness aggregates in families and appears to be heritable. Bipolar affective patients have been found to be supersensitive to the suppressive effect of light on the nocturnal secretion of melatonin, both in ill and well states. We tested young people aged 15 to 25 years with one manic-depressive parent (n = 18), major affective disorder on both sides of the family (n = 7), and age-matched controls (n = 20). The subjects in the high-risk groups were more likely to show supersensitivity in melatonin response to light at night than controls. Follow-up studies are necessary to assess the predictive value of this response.     

Altered 5-HT-induced calcium response in the presence of staurosporine in blood platelets from bipolar disorder patients.

We have reported that the platelet intracellular calcium (Ca) mobilization after stimulation by serotonin (5-HT) is specifically enhanced in bipolar disorder among various psychiatric disorders, compared with that in normal control. To explore the mechanisms of enhanced Ca response to 5-HT in the platelets, we first examined the relation between the 5HT-elicited Ca mobilization and 5-HT(2A) receptor density using the platelets from 13 normal subjects. From this study, we found no significant correlation between two measures. Then, we investigated the effects of staurosporine, a protein kinase C (PKC) inhibitor, on Ca response to 5-HT in platelets from patients with major depressive disorder (unipolar), bipolar disorder, and normal controls. While 5-HT-induced Ca mobilization, in the presence of 100 nM staurosporine, was significantly attenuated in normal controls and patients with major depressive disorder, the inhibitory effect of staurosporine was not observed in bipolar disorder. These results suggest that the failure in inhibiting the platelet intracellular Ca response to 5-HT in bipolar disorder may be related to increased activity of PKC rather than increased 5-HT(2A) receptor number. Moreover, the trend of the Ca response towards staurosporine may become a specific biological marker for unipolar-bipolar dichotomy.     

Changes of response to dopaminergic drugs in rats submitted to REM-sleep deprivation

Platelet monoamine oxidase activity was determined in 52 unipolar depressive patients, 26 patients with bipolar affective disorder and 48 controls using phenylethylamine as substrate. Unipolar depressive patients of either sex and bipolar depressive women showed significantly higher platelet MAO activity than controls. Women had higher activity than men. Neither age nor serum lithium level correlated with enzyme activity and there was no significant change in activity after the institution of lithium treatment.     

Extended-release bupropion: an antidepressant with a broad spectrum of therapeutic activity?

Bupropion, a noradrenaline and dopamine re-uptake inhibitor, has long been indicated for the treatment of depression. Recent studies have demonstrated additional benefits in depression, including: prevention of the recurrence of seasonal affective disorder in depressive subtypes with decreased energy, pleasure and interest; in major depression with concomitant anxiety; in elderly depressed patients; for non-response to initial serotonin re-uptake inhibitor therapy or augmentation of partial efficacy with serotonin re-uptake inhibitors; and in bipolar depression. Efficacy in other conditions has also been shown in studies of attention deficit hyperactivity disorder, nicotine dependence, obesity and hypoactive sexual desire disorder. Thus, bupropion has proven effective across a broad spectrum of depressive conditions, subtypes and comorbidities.     

Role of melatonin in mood disorders and the antidepressant effects of agomelatine

Introduction: Disturbances of circadian rhythms and sleep play an important role in various types of mood disorders like major depressive disorder (MDD), bipolar depressive disorder (BPD) and seasonal affective disorder (SAD). Malfunctioning of the SCN–pineal–melatonin link has been suggested as the main cause for these disorders. As a rhythm-regulating factor and as a hormone involved in the regulation of sleep, melatonin is essential for the control of mood and behavior.

Areas covered: Melatonin's involvement in various mood disorders is reviewed based on studies undertaken in patients with MDD, BPD and SAD. The chemistry and metabolism of the newly introduced antidepressant, agomelatine, a MT1/MT2 melatonin receptor agonist and 5-HT2c antagonist in brain areas involved in mood regulation are also discussed. Its clinical role in mood regulation, agomelatine's efficacy, safety and tolerability are also reviewed.

Expert opinion: Agomelatine, a melatonergic antidepressant with a rapid onset of action, has been shown effective in various types of mood disorders (e.g., MDD, BPD, SAD). Some studies find it superior to other common antidepressants (SSRIs, SNRIs) that are in clinical use today. Agomelatine's efficacy, good tolerability and safety profile suggest that it may become a preferred antidepressant in the near future.     

Bright light therapy in seasonal affective disorder--does it suffice?

Bright light therapy (BLT) has been proposed as treatment of choice for seasonal affective disorder (SAD). However, conventional antidepressants have also been found to be effective in this condition. We examined the psychopharmacologic medication in a clinical sample of 553 SAD patients, who had been treated with BLT, to assess the importance of drug treatment and to critically question the effectiveness of BLT. Forty-nine percent of our patients received psychopharmacologic treatment and about one third (35.4%) was treated with antidepressants, suggesting that BLT does not suffice as only antidepressant regimen for all SAD patients. Furthermore, our results show that only few patients with bipolar affective disorder were willing to accept long-term medication. Opposed to treatment guidelines, patients with several depressive episodes did not receive antidepressant maintenance medication or mood stabilizers more often than patients with only a few episodes.     

Bupropion

Bupropion was initially developed and licensed for the treatment of major depressive disorder in the United States in 1989. It was licensed as a pharmacotherapy for smoking cessation in the United States in 1997 and in the United Kingdom in 2000, and for the prevention of seasonal major depressive episodes in patients with seasonal affective disorder in the United States in 2006. Its main mechanism of action is believed to be via dopamine and noradrenalin reuptake inhibition. In addition to proven clinical efficacy for the treatment of major depression, the prevention of depressive episodes in patients with seasonal affective disorder, and as an aid to smoking cessation treatment, bupropion has demonstrated efficacy for attenuation of symptoms of attention deficit hyperactivity disorder, and more recently it has shown anti-inflammatory action against proinflammatory cytokines such as tumor necrosis factor-alpha (TNF-alpha), which may be implicated in a number of inflammatory diseases such as Crohn's disease. The twice-daily sustained-release formulation has been extensively evaluated for smoking cessation and has shown continuous smoking abstinence rates at one year of the order of 20% across many clinical groups including healthy smokers, and smokers with cardiovascular disease, chronic obstructive airways disease, depression and schizophrenia. Bupropion is well tolerated with side effects including insomnia, headache, dry mouth, dizziness and nausea. Bupropion is a cytochrome p450 2D6 inhibitor and care must be taken when coprescribing with drugs cleared by this enzyme and when coprescribing with drugs that lower seizure threshold. Despite the clinical effectiveness and cost-effectiveness of bupropion as an aid to smoking cessation, its uptake for this indication remains low when compared with nicotine replacement therapy.     

Long-term and preventative treatment for seasonal affective disorder

Recurrent major depressive disorder with regular seasonal patterns, commonly known as seasonal affective disorder (SAD), has evoked substantial research in the last two decades. It is now recognised that SAD is a common condition with prevalence rates between 0.4% and 2.9% of the general population, and that patients with SAD experience significant morbidity and impairment in psychosocial function.There is good evidence that bright light therapy and antidepressant medications are effective for the short-term treatment of SAD; however, given that SAD is characterised by recurrent major depressive episodes, long-term and maintenance treatment must be considered. Unfortunately, there are few studies of longer term (>8 weeks) and maintenance (preventative) treatments for SAD. The weight of evidence suggests that light therapy usually needs to be continued daily throughout the winter season because of rapid relapse when light is stopped too early in the treatment period. However, some studies support the use of antidepressants to continue the response from a brief (1-2 weeks) course of light therapy early in the depressive episode, as soon as the first symptoms emerge in autumn. Only small studies have examined preventative treatment (before onset of symptoms) with light therapy, all of which have methodological limitations. The best evidence for preventative treatment in SAD comes from antidepressant studies. Three large, randomised, placebo-controlled studies have shown that preventative treatment with bupropion XL reduces the recurrence rate of depressive episodes in patients with SAD.Given the limitations in the evidence base and the inconsistent recurrence rate of winter depressive episodes, clinical recommendations for long-term and preventative treatment must individualise treatment choices and weigh potential benefits against possible adverse effects.     

Polymorphisms in wolframin (WFS1) gene are possibly related to increased risk for mood disorders

Wolfram syndrome gene (WFS1) has been suggested to have a role in the susceptibility for mood disorders. A 26-fold increased risk for psychiatric disorders in WFS1 mutation carriers has been suggested. In this study we tested the hypothesis that the WFS1 gene is related to the risk for mood disorders. We analysed 28 single-nucleotide polymorphisms (SNPs) of the WFS1 gene in 224 unrelated patients with major depressive disorder and bipolar disorder and in 160 healthy control subjects. Patients were further stratified according to their comorbidity with anxiety disorders. We applied arrayed primer extension (APEX)-based genotyping technology followed by association and haplotype analysis. Five SNPs in the WFS1 gene were associated with major depressive disorder, and three SNPs with bipolar disorder. Haplotype analysis revealed a common GTA haplotype, formed by SNPs 684C/G, 1185C/T and 1832G/A, conferring risk for affective disorders. Specifically, for major depression the GTA haplotype has an OR of 1.59 (p = 0.01) and for bipolar disorder an OR of 1.89 (p = 0.03). These results support the hypothesis that the WFS1 gene is involved in the genetic predisposition for mood disorders.     

Increased mitochondrial complex I activity in platelets of schizophrenic patients

It is believed that dopamine and alterations of energy metabolism in cortical and subcortical structures are involved in the pathophysiology of schizophrenia. Recently, we and others have shown that dopamine may affect energy metabolism by interacting with mitochondrial complex I activity in rats both in vivo and in vitro. In this study activity of complexes I and IV was assessed in mitochondria isolated from blood platelet of schizophrenic patients and compared to patients with affective disorders and healthy control subjects. Seventy-seven in-patients who met DSM-IV criteria for schizophrenia (in acute exacerbation), bipolar disorder depressed type (BP), or recurrent major depressive disorder (MDD) and 24 control subjects participated in the study. A highly significant increase (240%, p < 0.001) in complex I activity but not in complex IV, was detected in medicated and unmedicated schizophrenic patients compared to controls. No such change was observed in patients with affective disorders. The data demonstrate a specific and selective, alteration in platelet complex I activity in schizophrenic patients, which is not related to medication. If this abnormality in platelet mitochondria reflects brain alterations, it may further support the relevance of alterations in energy metabolism to the pathophysiology of schizophrenia. Finally in the lack of any clinically relevant biological marker for schizophrenia, complex I activity in platelets might become a useful peripheral marker for this disorder.     

Neutrophil beta(2)-adrenoceptor function in major depression: G(s) coupling, effects of imipramine and relationship to treatment outcome

Abnormal beta(2)-adrenoceptor density and beta(2)-adrenoceptor-mediated cyclic adenosine monophosphate (cAMP) responses were inconsistently reported in major depressive disorder. Tricyclic antidepressants downregulate beta-adrenoceptor density and decrease coupling to G(s) protein. Abnormal beta-adrenoceptor coupling may exist in major depressive disorder and may relate to treatment response. We investigated beta(2)-adrenoceptor coupling to G(s) protein in 25 controls, 23 major depressive disorder drug-free patients and 16 major depressive disorder patients after chronic imipramine treatment using agonist displacement experiments. Pretreatment beta(2)-adrenoceptor coupling and density were normal in patients as a whole. Chronic imipramine induced beta(2)-adrenoceptor uncoupling. This effect was observed in treatment responders who had increased beta(2)-adrenoceptor density in the high-conformational state and supercoupling prior to treatment. Beta(2)-adrenoceptor density decreased after imipramine treatment. Treatment non-responders had seemingly normal pretreatment beta(2)-adrenoceptor function, which was not changed by imipramine. Differences in beta(2)-adrenoceptor regulation in major depressive disorder may underlie treatment response. The results indirectly implicate abnormal agonist-mediated beta(2)-adrenoceptor gene expression, protein kinase A, and protein kinase C in major depressive disorder.