Efficacy of melatonin with behavioural sleep-wake scheduling for delayed sleep-wake phase disorder: A double-blind, randomised clinical trial

Delayed Sleep-Wake Phase Disorder (DSWPD) is characterised by sleep initiation insomnia when attempting sleep at conventional times and difficulty waking at the required time for daytime commitments such as work or school [1,2]. DSWPD is often associated with chronic sleep restriction [3] and adverse academic, occupational, financial, mental health, and social outcomes [4–6].

The intrinsic basis for DSWPD manifests in a delay in endogenous circadian timing [2,3,7]. Current diagnostic criteria [1], however, do not specifically include circadian timing, which may result in misdiagnosis of sleep initiation insomnia as DSWPD [8]. Individuals may also present with delayed sleep-wake behaviour due to differences in homeostatic sleep drive not related to circadian timing and thus still show differences in sleep onset timing relative to those with healthy sleep [9]. Previous trials examining treatments for DSWPD have typically diagnosed the disorder based on sleep symptomology, not circadian timing [10–14].

Although exogenous melatonin has been suggested for clinical treatment of DSWPD [15], standardised evidence-based therapeutic guidelines are lacking. In addition to the circadian phase-shifting effects of melatonin, the hormone has direct, sleep-promoting effects [16]. The therapeutic potential of these sleep-promoting effects has not been evaluated rigorously in a randomised controlled trial in DSWPD patients. Such a treatment approach would be beneficial for this patient group, which may use melatonin to facilitate sleep at an earlier time only as required, for example, on nights before school or work days.

The aim of this study was to test—in a randomised, double-blind, parallel-groups, placebo-controlled outpatient trial—the efficacy of melatonin (0.5 mg) for DSWPD patients with confirmed delay of the endogenous melatonin rhythm relative to desired or required bedtime using a pragmatic, clinically relevant protocol that included behavioural sleep-wake scheduling (sleeping at desired or required bedtime) for all participants. Specifically, we tested the hypothesis that, compared to placebo, administration of melatonin 1 h prior to the patient’s predetermined desired (or required) bedtime for 4 wk would advance the time of sleep onset. As secondary outcomes, we hypothesised that compared to placebo, melatonin treatment would result in (1) increased sleep efficiency in the first third of the sleep episode (SE T1), (2) reduced subjective sleep-related daytime impairments, (3) reduced self-reported sleep disturbances and daytime sleepiness, (4) a greater proportion of change in the clinician-rated change in severity of illness, and (5) an advance in the timing of the endogenous circadian pacemaker.

Preliminary online screening was completed by 3,522 individuals, of whom 307 were enrolled in the study, 187 attended the laboratory-based circadian phase assessment, and 116 were randomised to treatment (Fig 1). Of the 186 who completed the circadian phase assessment, 62 (33.3%) did not have circadian misalignment between DLMO and DBT (defined as DLMO <30 min before or any time after DBT) and were excluded from the trial. Comparison of sleep-wake and mood characteristics of patients with and without circadian misalignment from this trial are presented elsewhere [8].

Patients were initially screened via online questionnaires followed by telephone assessment, and DSWPD symptomology was confirmed by a sleep physician. Circadian phase assessment identified individuals who had delayed DLMO relative to desired or required bedtime, and these individuals were randomly assigned to treatment. The intention-to-treat population included the 116 patients who were randomised. There were 104 patients in the completed treatment analysis.

Demographic and clinical characteristics of participants in each treatment group are presented in Table 1. Participants in the placebo and melatonin treatment groups did not differ in sex, age, body mass index, morningness-eveningness scores, clinician-derived DSWPD severity, baseline DLMO, DBT, phase angle between DLMO and DBT, or phase angle between DLMO and actigraphic habitual bedtime (Table 1; P > 0.05).

On average, patients took capsules (melatonin or placebo) on 21.11 ± 3.18 nights during the 4-wk treatment protocol, with an average of 5.30 ± 1.00 nights per 7-d period. Of the total completed sample (n = 104), 66.3% took capsules for at least 5 consecutive nights per week on at least 3 of the 4 wk. Notably, only 5.0% opted to take capsules for 7 nights per week on all weeks. The total number of nights for which patients complied with the treatment protocol (capsule taken and bedtime as instructed) did not differ between groups (536 versus 614 nights for melatonin and placebo groups, respectively; P > 0.05). The circadian timing of scheduled treatment (timing of capsule relative to baseline DLMO) was not different between the groups (−1.35 ± 0.87 h for melatonin and −1.51 ± 1.07 h for the placebo group; P > 0.05).

Earlier bedtime in the placebo condition was associated with longer SOL and lower SE, which was improved with melatonin treatment (Table 2, Fig 2). Relative to baseline, compared to placebo, the melatonin group had 18.2-min-shorter subjective (95% confidence interval [CI] −30.78 to −5.59; P = 0.005) and 11.9-min-shorter actigraphic (95% CI −19.54 to −4.39; P = 0.002) SOL, 44-min-earlier subjective (95% CI −66 to −21; P < 0.001) and 34-min-earlier actigraphic (95% CI −60 to −8; P = 0.011) sleep onset time, 38-min-earlier subjective sleep offset time (95% CI −63 to −13; P = 0.003), 3.0% higher SE for the entire sleep episode (95% CI 1.02–4.99; P = 0.003), and 5.14% higher SE T1 (95% CI 2.52–7.76; P < 0.001) (Table 2, Fig 2a).

We conducted post hoc analyses of all nights of the treatment period (28 d), including the nights on which treatment was not taken (Table 3). The melatonin group compared to the placebo group had a 29-min-earlier actigraphic sleep onset time (95% CI −54 to −4; P = 0.023) and 4.37% greater SE T1 (95% CI 1.91, 6.83; P = 0.001). An example of the treatment effect for a participant administered melatonin is plotted in Fig 3.

Sensitivity analyses were undertaken including only those nights on which patients took treatment and went to bed according to the study protocol. Compared to placebo, the melatonin group had earlier actigraphic sleep onset time (26 min; 95% CI −51 to −2; P = 0.038), higher SE T1 (5.50%; 95% CI 2.41–8.58; P < 0.001), shorter subjective (18.4 min; 95% CI −34.21 to −2.66; P = 0.022) and objective (15.7 min; 95% CI −24.41 to −6.89; P < 0.001) SOL, earlier subjective sleep onset time (40 min; 95% CI −67 to −14; P = 0.004), earlier subjective sleep offset time (42 min; 95% CI −74 to −9; P = 0.013), and higher actigraphic SE for the entire sleep episode (3.27%; 95% CI 1.30–5.24, P = 0.001).

For PROMIS Sleep Disturbance, a treatment by time interaction effect was found (F_4,408 = 3.83, P = 0.005), and a significant main effect of time (F_4,408 = 4.01, P = 0.003) but no main effect of treatment (P = 0.112). Post hoc analysis showed that PROMIS Sleep Disturbance score was lower in the melatonin group at week 3 (P = 0.042) and week 4 (P = 0.016) compared to placebo (Fig 2b upper). PROMIS Sleep Related Impairment showed a treatment by time interaction effect (F_4,408 = 4.29, P = 0.002), a main effect of time (F_4,408 = 37.12, P < 0.0001), but no main effect of treatment (P = 0.102). Melatonin treatment resulted in significantly lower PROMIS score for sleep-related impairment at week 1 (P = 0.035), week 3 (P = 0.042), and week 4 (P = 0.018; Fig 2b lower).

Prior to treatment, participants in the treatment groups were not different on ratings on the ISI, PSQI, ESS, SDS, absenteeism, or presenteeism (Table 4). Compared to placebo, ISI and PSQI were significantly improved with melatonin treatment. Following treatment, the melatonin group reported a lower ISI score (P = 0.035) and included more individuals reporting absent insomnia symptoms on the ISI (P = 0.008). Mean PSQI score post treatment was lower in the melatonin group compared to placebo (P = 0.037). Significant treatment by time interactions were observed for ISI (P = 0.004), PSQI (P = 0.023), and SDS (P = 0.045) (Table 4), with melatonin treatment associated with larger reductions in each score. Absenteeism and presenteeism post treatment were not different between groups.

CGI Global Improvement ratings were significantly different between treatment groups (P = 0.011), with 52.8% (n = 28) of the melatonin group classified as very much/much improved compared to 24.0% (n = 12) of the placebo group (Table 5). CGI Efficacy Index was lower following melatonin treatment compared to placebo (P = 0.045). The proportion of patients in the CGI Severity categories did not change following treatment (Table 5). Post-treatment PGI-C scores did not differ between groups.

Post-treatment DLMO could not be calculated for 6 of the subset of 49 participants; melatonin concentrations were above threshold (2.3 pg/ml) at the start of the collection phase in 4 participants (n = 3 melatonin, n = 1 placebo), with higher levels in 1 participant indicating that melatonin treatment was taken on the night of assessment. Concentrations did not cross threshold for 2 participants (n = 1 melatonin, n = 1 placebo). Following melatonin treatment (n = 23), DLMO was advanced by 0.73 ± 1.21 h, compared to 0.24 ± 1.11 h following placebo (n = 20) although this difference did not reach statistical significance (P > 0.05).

No deaths or serious adverse events were reported for either treatment group, and no participants discontinued due to adverse events. Adverse event rates did not differ between the treatment groups (Table 6). Adverse events did not occur in more than 5% of patients taking melatonin. Unusual dreaming was reported by 7% of the placebo group compared to 2% of the melatonin group.

In post hoc analysis, we assessed whether the degree of ‘social jetlag’ observed in our patients was affected by our melatonin treatment protocol. Social jetlag has been described as the discrepancy between sleep timing on work and free days, thought to reflect the discrepancy between social and biological time [39]. We operationalised this definition in our protocol by comparing sleep timing on nights when medication was taken compared to when medication was not taken because this was thought to reflect work and free nights, respectively. Data were included when at least 2 nonmedication nights were available for each participant (n = 83). Consistent with previous studies, sleep timing was defined by mid-sleep, calculated here as the midpoint between actigraphic sleep onset and sleep offset time. Median social jetlag was not different between the melatonin group (1.17 [0.70–1.75], median [IQR]) and the placebo group (0.89 [0.58–1.62]) (P > 0.05).

In a sample of DSWPD patients with confirmed circadian misalignment, compared to placebo, 0.5 mg melatonin taken 1 h prior to patient-DBT in a pragmatic treatment protocol resulted in earlier timing of sleep onset, improved sleep quality, and reduced sleep-related impairments. Melatonin treatment reduced patient-reported sleep disturbance, insomnia severity, and daytime functional disability and was associated with larger clinician-rated improvements in symptoms. This is the largest placebo-controlled trial to assess the clinical efficacy of melatonin to improve sleep initiation and sleep quality in DSWPD. The trial has assessed the effects of melatonin when sleep is attempted at the patient-DBT in DSWPD patients with confirmed circadian misalignment, using patient-reported (PROMIS, PSQI, ISI, SDS, PGI-C), clinician-assessed (CGI-Global Improvement and Efficacy), and objective (actigraphic sleep onset time, SOL, SE) assessments of sleep quality and daytime function.

We instructed patients to attempt sleep at their DBT during treatment, which resulted in the sleep episode starting, on average, 2 h earlier than habitual bedtime during baseline. The earlier timing in bedtime resulted in longer SOL for those on placebo, as expected for individuals attempting to sleep earlier in their circadian cycle [40]. Treatment with melatonin reduced the time taken to fall asleep to near baseline levels and resulted in a 34-min-earlier sleep onset and 36-min-earlier self-reported sleep offset time compared to placebo, exceeding consensus recommendations of critical clinical significance thresholds for improvements in these outcomes in DSWPD (15 min in both cases) [15]. Actigraphically recorded SE during the first tertile of sleep and overall SE were also improved with melatonin treatment.

Melatonin treatment produced considerable improvements in subjective sleep complaints. Patients taking melatonin reported improved sleep quality and reduced severity of insomnia symptoms. A higher proportion of those taking melatonin also reported an absence of insomnia symptoms. To assess the clinical utility of melatonin for DSWPD, the observed effect sizes should be compared to other treatments for DSWPD, ideally. Unfortunately, to our knowledge, such studies are lacking. The effects reported for subjective SOL are comparable to those of first-line therapies for insomnia, including cognitive behavioural therapy for insomnia [41] and Z-class hypnotic agents [42]. The reduction in subjective insomnia severity is greater than reported with Suvorexant for treatment of primary insomnia [43]. Our findings of reduced functional impairments in work/school, social, and family life extend previous reports of improvements in school performance in adolescents [44] and quality of life in adults [45] following melatonin treatment. After only 1 wk of treatment with melatonin, patient-reported sleep-related impairment was significantly improved relative to placebo. The 4-point reduction in PROMIS sleep-related impairment is comparable to the 5-point larger reduction reported for cognitive behavioural therapy for insomnia modified for bipolar disorder compared to psychoeducation [46] as well as the 4-point difference reported between individuals with a recent mild traumatic brain injury and matched controls [47]. We suggest that these improvements in daytime functional measures were secondary to the observed improvements in sleep quality.

Melatonin treatment advanced the timing of DLMO by 36 min more than with placebo (0.73 versus 0.24 h), although this difference was not significant. There are several possible reasons for this lack of difference in circadian phase shifting. Melatonin was scheduled to be taken 1 h prior to DBT to facilitate sleep onset primarily through the direct, sleep-promoting effects of the hormone [16] during the wake maintenance zone, when sleep propensity is low [2,48]. In contrast, most previous trials of melatonin for DSWPD have focussed on the circadian phase shifting properties of melatonin, which require that treatment be administered several hours before the timing of habitual sleep or endogenous melatonin onset [13,14]. Although melatonin was administered on average 1.4 h before DLMO—which may be expected to induce a modest phase advance [33,49]—because assessment of circadian phase shifting was performed in only a subset of patients, the study may have been underpowered to detect significant differences. Second, by instructing patients to attempt sleep at their DBT (which may be the required bedtime for some individuals), the light-dark cycle was phase advanced, resulting in an advance in the timing of the circadian pacemaker in both groups [50]. Finally, our pragmatic treatment protocol required patients to take melatonin and sleep at their DBT—which is typically earlier than the habitual bedtime—on at least 5 nights per week, to accommodate work or school activities. On nights when patients did not sleep at their DBT or take melatonin, the circadian pacemaker may have reverted to a delayed pattern, thus counteracting the previous melatonin-induced phase advances. As an indirect consequence of a protocol that allows patients to choose their own sleep-wake schedule, social jetlag (i.e., the difference in timing between treatment and nontreatment nights) could be increased, which may have health implications [51]. We did not find a significant difference in the degree of social jetlag between the melatonin and placebo groups.

Current melatonin treatment protocols for DSWPD vary in patient diagnostic and selection criteria as well as in the dose, formulation, and timing of melatonin, and they may result in low compliance, thus limiting translation into clinical practice. We improved on previous academic-led trials by selecting patients who have an endogenous circadian basis to their symptoms [52]. Furthermore, we have developed a pragmatic treatment protocol that allows patients to improve sleep initiation when needed to accommodate daytime commitments the following morning and found a high rate of compliance. This approach of allowing patients to optimise treatment administration to align with clinical and lifestyle needs is highly novel and, to our knowledge, has not been previously reported in the literature. The behavioural intervention of attempting sleep at the earlier DBT facilitated earlier timing of sleep onset, as reflected by the significant improvements in sleep outcomes in the placebo group (Tables 2 and 4). These findings demonstrate that behavioural approaches for managing DSWPD appear to be highly effective, potentially through altered light-dark cues. The improvements in sleep produced by the behavioural intervention were, however, considerably enhanced by melatonin administration. This is important information for clinicians seeking an evidence-based therapeutic approach for DSWPD. We used a lower dose formulation than those typically used previously (3–5 mg) [10–12,14,44,53]. Our results demonstrate that large doses of melatonin are not required for improvements in sleep initiation and daytime functioning in DSWPD patients, noting, however, that a dose-response relationship has previously been reported [36].

Treatment of a circadian disorder with melatonin would be preferable to a traditional hypnotic given that melatonin both facilitates sleep and shifts the timing of the circadian pacemaker [16]. There is a lack of evidence of the value of hypnosedatives in the treatment of phenotyped DSWPD and a large body of literature on the adverse effects of such medications. In addition to the properties of benzodiazepines as a muscle relaxant, the use of this class of drugs is often associated with residual sleepiness the following morning, cognitive impairments including memory, and issues of dependence and withdrawal [54]. The overdose death rate with benzodiazepine use has increased from 0.58 to 3.07 per 100,000 adults [55]. A potentially important clinical application for melatonin is in its use to facilitate discontinuation of benzodiazepines [56].

Limitations of the study should be considered. The original sample size was not reached due to slower-than-anticipated recruitment and financial constraints. Statistical significance was still achieved in the main outcomes, probably because we only included patients with delayed circadian phase relative to DBT, melatonin treatment was timed before DLMO, and we continued treatment for 4 wk, compared to the variable protocols used in the studies that informed our original sample size estimate [11,57–59]. The implications of smaller sample size should be considered, including internal and external validity of the findings. Testing of efficacy and safety were limited to a 4-wk interval. We did not assess clinical benefits or safety of melatonin with long-term treatment, nor did we do a follow-up assessment after treatment was discontinued. Furthermore, it remains unknown whether the same treatment regime would benefit all patients who meet current (ICSD symptom-based) diagnostic criteria for DSWPD but do not undergo further classification based on circadian phase. In our study, patients were diagnosed via clinical interview based on ICSD-2 criteria. An updated version of the ICSD incorporating recommendations to consider objective assessments, including circadian phase, is now available.

Patients experiencing DSWPD symptoms without a circadian delay are not likely to be sleeping in their wake maintenance zone, and therefore the soporific effects of melatonin may be diminished. One-third of patients diagnosed with DSWPD in the current study did not present circadian misalignment between DLMO and DBT. It is important to include circadian phase assessment in the diagnosis and management of DSWPD. It should also be noted that some individuals with delayed sleep due to non-circadian reasons could ultimately experience delayed circadian timing due to delayed light-dark exposure on an ongoing basis. This has implications for the growing prevalence of DSWPD and for treatment protocols such as cognitive behavioural therapy for insomnia, which includes the practice of stimulus control, in which patients can be encouraged to rise from bed in the evening if they are unable to fall asleep, subsequently exposing themselves to phase-delaying light.

Although the formulation of melatonin used in this trial was certified for its purity and quality, access to pharmaceutical-grade melatonin is variable across different countries. In numerous countries, a compounding pharmacist must deliver an accurate dosage of melatonin. In countries such as the United States in which melatonin is not regulated, however, issues of quality, dose, and preparation are likely to be a concern for clinicians. These practical limitations, together with the lack of access to circadian phase assessments, present some barriers to translation of the current findings. This trial does, however, support the clinical utility of circadian diagnostic and treatment approaches in order to bring clinical practice in line with scientific discoveries in the field.

We showed that short-term, low-dose melatonin administration in a pragmatic treatment protocol with behavioural sleep-wake scheduling is an efficacious and safe treatment for DSWPD patients with confirmed circadian misalignment, resulting in improvements in objective and subjective sleep quality, daytime function, and clinical symptom severity.

In addition to the authors, members of the Delayed Sleep on Melatonin (DelSoM) study group are: Elena Armstrong, Melbourne, VIC.; Khalid Chohan, Sydney, NSW; Yasmina Djavadkhani, Sydney, NSW; Kirsty Dodds, Sydney, NSW; Shaminka Gunaratnam, Melbourne, VIC; Margaret Hardy, Sydney, NSW; Simon Joosten, Melbourne, VIC; Joy Lee, Melbourne, VIC; Gorica Micic, Adelaide, SA; Bhairavi Raman, Melbourne, VIC; Elizabeth Roese, Sydney, NSW; Mark Salkeld, Adelaide, SA; Erin Verberne, Melbourne, VIC; Keith Wong, Sydney, NSW; Brendon Yee, Sydney, NSW; Aeneas Yeo, Adelaide, SA; Kewei Yu, Melbourne, VIC. The authors are grateful to David P. White MD and Charles A. Czeisler PhD MD for contributions to protocol design, and Stephen Pittman for assisting with participant recruitment.

All relevant data are within the paper and its Supporting Information files.

The study was funded by a project grant from the National Health and Medical Research Council (NHMRC; 1031513) to SMWR, SWL, RRG, LCL, DJK and research support from the NHMRC Australasian Sleep Trials Network. Financial support for recruitment advertising was provided by Philips Respironics. RRG is supported by a NHMRC Senior Principal Research Fellowship (1106974). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.