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Suvorexant in Patients with Insomnia: Pooled Analyses of Three-Month Data from Phase-3 Randomized Controlled Clinical Trials

2016; American Academy of Sleep Medicine; Volume: 12; Issue: 09 Linguagem: Inglês

10.5664/jcsm.6116

1550-9397

W. Joseph Herring, Kathleen M. Connor, Ellen Snyder, Duane Snavely, Ying Zhang, Jill Hutzelmann, Deborah Matzura‐Wolfe, Ruth M. Benca, Andrew D. Krystal, James K. Walsh, Christopher Lines, Thomas Roth, David Michelson,

Circadian rhythm and melatonin

Free AccessWomenSuvorexant in Patients with Insomnia: Pooled Analyses of Three-Month Data from Phase-3 Randomized Controlled Clinical Trials W. Joseph Herring, MD, PhD, Kathleen M. Connor, MD, Ellen Snyder, PhD, Duane B. Snavely, MA, Ying Zhang, PhD, Jill Hutzelmann, MS, Deborah Matzura-Wolfe, BS, Ruth M. Benca, MD, Andrew D. Krystal, MD, James K. Walsh, PhD, Christopher Lines, PhD, Thomas Roth, PhD, David Michelson, MD W. Joseph Herring, MD, PhD Address correspondence to: W. Joseph Herring, Merck, UG 4C-13, PO Box 1000, North Wales, PA 19454-1099(267) 305-7933 E-mail Address: [email protected] Merck & Co., Inc., Kenilworth, NJ , Kathleen M. Connor, MD Merck & Co., Inc., Kenilworth, NJ , Ellen Snyder, PhD Merck & Co., Inc., Kenilworth, NJ , Duane B. Snavely, MA Merck & Co., Inc., Kenilworth, NJ , Ying Zhang, PhD Merck & Co., Inc., Kenilworth, NJ , Jill Hutzelmann, MS Merck & Co., Inc., Kenilworth, NJ , Deborah Matzura-Wolfe, BS Merck & Co., Inc., Kenilworth, NJ , Ruth M. Benca, MD University of Wisconsin, Madison, WI , Andrew D. Krystal, MD Department of Psychiatry and Behavioral Sciences, Duke University School of Medicine, Durham, NC , James K. Walsh, PhD Sleep Medicine and Research Center, St. Luke's Hospital, St. Louis, MO , Christopher Lines, PhD Merck & Co., Inc., Kenilworth, NJ , Thomas Roth, PhD Henry Ford Hospital Sleep Center, Detroit, MI , David Michelson, MD Merck & Co., Inc., Kenilworth, NJ Published Online:September 15, 2016https://doi.org/10.5664/jcsm.6116Cited by:28SectionsAbstractPDFSupplemental Material ShareShare onFacebookTwitterLinkedInRedditEmail ToolsAdd to favoritesDownload CitationsTrack Citations AboutABSTRACTStudy Objectives:Suvorexant is an orexin receptor antagonist approved for treating insomnia at a maximum dose of 20 mg. Phase-3 trials evaluated two age-adjusted (non-elderly/elderly) dose-regimes of 40/30 mg and 20/15 mg with the primary focus on 40/30 mg. We report here results from pooled analyses of the 20/15 mg dose-regime, which was evaluated as a secondary objective in the trials.Methods:Prespecified analysis of pooled data from two identical randomized, double-blind, placebo-controlled, parallel-group, 3-month trials in non-elderly (18–64 years) and elderly (≥ 65 years) patients with insomnia. Patients were randomized to suvorexant 20/15 mg (non-elderly/elderly), suvorexant 40/30 mg (non-elderly/elderly), or placebo; by design, fewer patients were randomized to 20/15 mg. Efficacy was assessed by self-reported and polysomnography (PSG; subset of patients) sleep maintenance and onset endpoints.Results:Suvorexant 20/15 mg (N = 493 treated) was effective compared to placebo (N = 767 treated) on patient-reported and PSG sleep maintenance and onset endpoints at Night-1 (PSG endpoints) / Week-1 (subjective endpoints), Month-1 and Month-3, except for effects on PSG sleep onset at Month-3. Suvorexant 20/15 mg was generally well tolerated, with 3% of patients discontinuing due to adverse events over 3 months vs. 5.2% on placebo. Somnolence was the most common adverse event (6.7% vs. 3.3% for placebo). There was no systematic evidence of rebound or withdrawal signs or symptoms when suvorexant was discontinued after 3 months of nightly use.Conclusions:Suvorexant 20/15 mg improved sleep onset and maintenance over 3 months of nightly treatment and was generally safe and well tolerated.Clinical Trial Registration:ClinicalTrials.gov trial registration numbers: NCT01097616, NCT01097629.Citation:Herring WJ, Connor KM, Snyder E, Snavely DB, Zhang Y, Hutzelmann J, Matzura-Wolfe D, Benca RM, Krystal AD, Walsh JK, Lines C, Roth T, Michelson D. Suvorexant in patients with insomnia: pooled analyses of three-month data from phase-3 randomized controlled clinical trials. J Clin Sleep Med 2016;12(9):1215–1225.INTRODUCTIONIn 1998, the gene encoding the hypothalamic orexin neuropeptides OX-1 and OX-2 was described.1,2 Sixteen years later, in 2014, suvorexant became the first agent specifically targeting the orexin system (via orexin receptor antagonism) to be approved as a therapeutic agent, for the treatment of insomnia.3–8 This relatively rapid progress reflects advances in understanding orexin biology. The orexin signaling system comprises of a restricted number (50,000–80,000) of orexin neurons which originate from the lateral hypothalamus and project widely throughout the central nervous system.9 A role for orexin in regulating wakefulness was suggested from studies which showed that orexin neuron loss was associated with narcolepsy in mice, dogs, and humans.10–13 Further research has shown diurnal variation of orexin activity in normal animals, with increased activity during wakefulness and reduced activity during sleep.14,15 Elucidation of orexin's role in regulating wakefulness suggested that orexin receptor antagonists could provide a new approach to treating insomnia by blocking orexin-mediated wake signaling.16 This approach is distinct from current insomnia drugs, most of which promote sleep by enhancing sleep signaling via gamma-aminobutyric acid (GABA) inhibitory effects.17BRIEF SUMMARYCurrent Knowledge/Study Rationale: Suvorexant is a first-in-class orexin receptor antagonist approved for treating insomnia at a maximum dose of 20 mg. We performed a pooled analysis of suvorexant 20/15 mg, which was evaluated as a secondary objective in Phase-3 clinical trials.Study Impact: The results of the pooled analysis showed that suvorexant 20/15 mg improved sleep onset and maintenance over 3 months of nightly treatment and was generally safe and well-tolerated. Our analysis validates orexin receptor antagonism as a novel therapeutic approach for treating insomnia.The suvorexant phase-3 development program in insomnia patients was comprised of two 3-month pivotal trials, each of which evaluated two age-adjusted (non-elderly/elderly) dose regimes of 40/30 mg and 20/15 mg,8 and a 1-year trial of 40/30 mg.7 The primary objective of the trials was to establish the efficacy, safety, and tolerability of the 40/30 mg dose. By design, fewer patients were assigned to 20/15 mg than 40/30 mg and each of the pivotal phase-3 trials were individually not adequately powered with regard to 20/15 mg effects on all efficacy endpoints. The two pivotal efficacy studies were identical in design, and pooled analyses of the results were prespecified in the statistical analysis plan. Here we report the results of these pooled analyses for the Food and Drug Administration (FDA) approved 20/15 mg doses. We also report on additional analyses of suvorexant effects on maintaining sleep hourly over the course of a night, efficacy and tolerability in subgroups such as those defined by age and gender, and efficacy as assessed by responder analyses.METHODSOverviewThe pooled efficacy analyses included data from two phase-3 randomized, double-blind, placebo-controlled, parallel-group, 3-month efficacy and safety trials in non-elderly (18–64 years) and elderly (≥ 65 years) patients with insomnia (protocol 028 [P028] and protocol 029 [P029]).8 P028 also included an optional randomized, double-blind, placebo-controlled, 3-month extension. Suvorexant doses of 40/30 mg (non-elderly/elderly) and 20/15 mg (non-elderly/elderly) were evaluated, with fewer patients randomized to 20/15 mg than 40/30 mg or placebo. Each trial incorporated a 1-week, randomized, double-blind run-out after double-blind treatment (3 months in P029, 3 or 6 months in P028) to assess withdrawal and rebound insomnia.PatientsNon-elderly (18–64) and elderly (≥ 65) patients who met Diagnostic and Statistical Manual of Mental Disorders, 4th edition, text revision (DSM-IV-TR) criteria for primary insomnia18 and were otherwise in good physical and mental health were enrolled. All patients provided subjective sleep estimates using an electronic sleep diary/questionnaire. Approximately 75% of the patients also underwent polysomnography (PSG) over 8 hours. Patients who received only self-report assessments are referred to as the questionnaire (Q)-cohort; those who received self-report and PSG assessments are referred to as the PSG+questionnaire (PQ)-cohort. To enter the Q-cohort, patients had to report a total sleep time (sTST) < 6.5 h and time to sleep onset (sTSO) ≥ 30 min, both on ≥ 4 of 7 nights during the last week of a 2-week placebo run-in before randomization. For the PQ-cohort, patients had to meet the following PSG criteria for screening and baseline PSG nights: latency to onset of persistent sleep (LPS; the time from the beginning of lights off to the onset of 10 consecutive minutes of sleep) > 20 min, and mean (across screening and baseline) wakefulness after persistent sleep onset (WASO) ≥ 60 min with neither night ≤ 45 min. They were not required to meet the Q-cohort entry criteria. All patients (PQ+Q cohorts) also had to report ≥ 1 h of wakefulness after sleep onset (sWASO) on ≥ 3 of 7 nights each week during the 4 weeks prior to the initial screening visit.Design and ProcedurePatients were discontinued from existing hypnotic medications prior to entering each trial. Patients were randomized to treatment with suvorexant 40/30 mg, suvorexant 20/15mg, or placebo in a 3:2:3 ratio in P028, and a 1:1:1 ratio (Q-cohort) or a 2:1:2 ratio (PQ-cohort) in P029. Doses differed by age to adjust for previously-observed plasma exposure differences (< 65: 40 mg or 20 mg; ≥ 65: 30 mg or 15 mg). Randomization was stratified by age category (non-elderly vs. elderly) in all trials and also by cohort (Q vs. PQ) in P028 and P029. For the run-out phase, patients initially assigned to suvorexant were randomized to either continue on the same dose of suvorexant (suvorexant→suvorexant) or to switch to placebo (suvorexant→placebo) in a 1:1 ratio, while patients initially assigned to placebo continued to receive placebo (placebo→placebo).Patients were blindly assigned to treatment according to a randomization schedule generated by a Merck statistician using a computerized allocation schedule system. Treatment assignment was implemented through an interactive voice response system. Study investigators, site staff, patients, PSG scorers, and Merck monitoring staff remained blinded to treatment allocation throughout the study. Patients were instructed to take medication orally once daily immediately prior to bedtime (within 5 to 10 minutes).The trials were conducted in accordance with principles of Good Clinical Practice and were approved by the appropriate institutional review boards and regulatory agencies for each site. Informed consent was obtained from all patients. The trials were registered at ClinicalTrials.gov (NCT01097616, NCT01097629).AssessmentsPatients used an electronic diary each morning to report sTST (min), sTSO (min), sWASO (min), number of awakenings (sNAW), quality of sleep (sQUAL, 4-point scale), and refreshed feeling on waking (sFRESH, 5-point scale). The Insomnia-Severity-Index (ISI)19 was completed at Months 1 and 3, and clinician and patient ratings of global severity (CGI-S [7-point scale], PGI-S [6-point scale]) and global improvement (CGI-I, PGI-I [7-point scales]) were recorded at Week 2 and Months 1, 2, and 3. PSG measures included LPS, WASO, and total sleep time (TST) assessed at Night 1, Month 1, and Month 3.Safety assessments included open-ended questioning for adverse events (AEs), the Columbia Suicidality Severity Rating Scale,20 and periodic physical, chemistry, hematology, and electrocardiogram assessments. A Motor-Vehicle-Accidents-and-Violations questionnaire was administered during clinic visits or phone calls to assess the occurrence of traffic or motor vehicle accidents (and related injuries) or citations since the last visit when the patient was the driver.A program-wide guidance document containing definitions of prespecified events of clinical interest (ECIs) was provided to investigators. A blinded independent committee comprised of 3 experts in neurology, psychiatry, and sleep, respectively, adjudicated all ECIs potentially suggestive of intrusion of rapid eye movement (REM) sleep into wakefulness (cataplexy) or at initiation of sleep (sleep-onset paralysis). Falls were also adjudicated to ascertain whether they were due to a possible episode of cataplexy.Residual effects were assessed in the PQ-cohort by the Digit Symbol Substitution Test (DSST) within 0.5–1 h following lights-on on the morning after PSG.Potential withdrawal symptoms were assessed after completion of the double-blind treatment period by the Tyrer Withdrawal Symptom Questionnaire21 administered prior to dosing on 3 consecutive evenings at the start of the run-out.Efficacy EndpointsThe primary efficacy endpoints were change from baseline in sleep diary and PSG measures of sleep maintenance (sTST, WASO) and sleep onset (sTSO, LPS). Monthly values for the self-report endpoints were the mean of the daily values for the last week (Week 1, Month 1) or 2 weeks (Month 3) of the month. Changes from baseline on other diary endpoints (sWASO, sNAW, sQUAL, sFRESH), PSG endpoints (TST), and rating scale endpoints (ISI, CGI-S, PGI-S, CGI-I, PGI-I) were also assessed. PSG sleep efficiency (SE [%]), defined as TST/time in bed (fixed at 8 h for PSG recording) × 100, was assessed post hoc. SE provides an additional parameter of interest to practitioners but is effectively double reporting of TST results in situations where time in bed is fixed, as in the present studies. Subjective sleep efficiency could not be calculated because time in bed was not captured on the patient diaries. In addition, we assessed: WASO by hour of night; the percentage of responders using various definitions (ISI ≥ 6 point improvement from baseline22; sTSO and sTST ≥ 15% improvement from baseline, with the cutoff corresponding to the degree of change likely to exceed the mean placebo change from baseline based on historical data from similarly designed clinical trials conducted by Merck); and efficacy in subgroups defined by age, gender, race, region, baseline severity (above or below the median for the corresponding baseline values of the endpoint), cohort (Q or PQ), and, for the PQ-cohort only, by Q-cohort entry criteria (those who met Q-cohort entry criteria versus those who did not).Statistical AnalysisA pooled analysis of phase-3 efficacy and safety data was prespecified, to allow a more robust evaluation of the 20/15 mg dose given that each individual trial was underpowered for this dose. It should be noted that for some analyses (of AEs, measures of rebound and withdrawal) the analysis plan prespecified that the placebo arm for the 20/15mg comparison would also include 0- to 3-month placebo data from the P009 1-year trial of 40/30 mg.7 However, given that 20/15 mg was not included in P009 and because 20 mg is the maximum FDA approved dose, we decided it would be most valid to restrict the placebo dataset to P028+P029 for the 20/15 mg comparison.The efficacy analyses included all patients who took ≥ 1 dose of treatment, had ≥ 1 post-treatment efficacy measure, and had baseline data (for analyses requiring baseline data). Efficacy endpoints (i.e., change from baseline in sTST, WASO, sTSO, LPS) were assessed using a longitudinal data analysis model with terms for baseline value, age group (non-elderly vs. elderly), region, gender, treatment, trial, time, and interaction of treatment-by-time; cohort was also included in the models for sTST and sTSO and other subjective endpoints. Analysis of responders was based on a generalized linear mixed model using the same terms.No formal multiplicity strategy was employed for these pooled analyses since the primary purpose was to provide improved precision in the estimates of the treatment group comparisons; note that nominal p values were computed as a measure of strength of effect rather than a formal test of hypothesis.The safety analysis included all patients who took ≥ 1 dose of treatment. The percentages of patients with AEs, including prespecified ECIs, were calculated. Summary statistics were calculated for predefined limits of change in laboratory, vital signs, or ECG measures.Rebound insomnia on diary endpoints was assessed in patients who entered the 1-week run-out at the end of treatment (3 months or 6 months). The proportion of patients in each treatment group with lower sTST (or greater sTSO) relative to pretreatment baseline, regardless of the magnitude of the difference, was calculated for each of the first 3 nights of run-out as well as on any of the 3 nights. For PSG parameters (WASO and LPS), values during the first night of the run-out at the end of 3 months of treatment were compared to those obtained at pretreatment baseline. The primary comparisons were between the suvorexant→placebo groups and the placebo→placebo group. Additionally, rebound effects were assessed by between group comparisons of the mean changes from pretreatment baseline (in minutes) during the run-out for sTST, sTSO, WASO, and LPS.To assess withdrawal symptoms, the proportion of patients with ≥ 3 newly emergent or worsened (compared to the last treatment measurement) symptoms on the 20-item Tyrer Withdrawal Symptom Questionnaire for each of the first 3 nights of run-out as well as across all 3 nights was calculated. The primary comparisons were between the suvorexant→suvorexant groups and the suvorexant→placebo groups.Next-morning residual effects were assessed by the number of attempts and number of correct items on the DSST.PowerBased upon pooled sample sizes of 1,260 (493 for suvorexant 20/15 mg, 767 for placebo) for self-report efficacy endpoints and 930 (343 for suvorexant 20/15 mg, 587 for placebo) for PSG efficacy endpoints, and assuming an overall dropout rate of approximately 1% at Night 1 (for PSG endpoints), 5% at Week 1 (for self-report endpoints), 10% at Month 1, and 20% at Month 3, the marginal power for the comparison of suvorexant 20/15 mg versus placebo was > 99% to detect standardized effect sizes ranging from 33% to 76% for the maintenance endpoints (sTST, WASO) and > 93% to detect standardized effect sizes ranging from 29% to 50% for the onset endpoints (sTSO, LPS). The primary purpose of the subgroup analyses was to evaluate the consistency of the treatment effect across various subgroups; therefore, no power calculations were made for the subgroup analyses.RESULTSPatient AccountingPatient accounting for the 3-month treatment periods of the pooled data sets are shown in Figure S1 in the supplemental material. Completion rates for 3 months were high (85–89%) and similar among treatment groups.Patient CharacteristicsPatient characteristics and baseline symptom severity were generally similar among treatment groups and are summarized in Table 1. At baseline, patients reported a mean sTST of ∼5 h and a mean sTSO of ∼1.25 hours.Table 1 Baseline characteristics of treated patients for P028+P029.Table 1 Baseline characteristics of treated patients for P028+P029.EfficacyMean changes-from-baseline in each treatment group for diary sleep measures, PSG sleep measures, and global rating scales are shown in Table S1 in the supplemental material. Suvorexant 20/15 mg differences from placebo are summarized in Table 2. Suvorexant 20/15 mg provided improvement compared to placebo for all endpoints except sNAW, and LPS at Month-3.Table 2 Summary of efficacy for suvorexant 20/15 mg over 3 months for P028+P029: difference (95% CI) between suvorexant and placebo in least squares mean change from baseline.Table 2 Summary of efficacy for suvorexant 20/15 mg over 3 months for P028+P029: difference (95% CI) between suvorexant and placebo in least squares mean change from baseline.Effects of suvorexant 20/15 mg on sleep maintenance and sleep onset over time are illustrated graphically in Figure 1 (self-report measures) and Figure 2 (PSG measures). It can be seen that suvorexant effects were apparent on the first PSG night or first week of diary data and were maintained throughout 3 months of nightly use (except for LPS at Month 3). Standardized effect sizes for suvorexant 20/15 mg on self-report measures at Week 1 were 34% for sTST and 20% for sTSO; standardized effect sizes for PSG measures at Night-1 were 89% for WASO and 31% for LPS. At Month 3, standardized effect sizes for suvorexant 20/15 mg on self-report measures were 29% for sTST and 17% for sTSO, and standardized effect sizes for PSG measures were 54% for WASO and 14% for LPS.Figure 1: Adjusted means and 95% CIs for change from baseline in self-report endpoints for P028+P029.Download FigureFigure 2: Adjusted means and 95% CIs for change from baseline in PSG endpoints for P028+P029.Download FigureEffects of suvorexant 20/15 mg on WASO by hour of the night are shown in Figure 3. Suvorexant generally improved WASO from 2–8 h, except for hours 7 and 8 at Month 3.Figure 3: Adjusted means and 95% CIs for change from baseline (BL) in WASO by hour of the night for P028+P029.Download FigureThe analyses of the percentages of responders according to the various definitions are shown in Table 3. A greater odds of responding was evident for suvorexant 20/15 mg versus placebo, except for the “sTSO ≥ 15% improvement” definition at Month 3.Table 3 Summary of responder analyses for suvorexant 20/15 mg over 3 months for P028+P029: number (%) of responders and odds ratio (95% CI) for the difference between suvorexant and placebo.Table 3 Summary of responder analyses for suvorexant 20/15 mg over 3 months for P028+P029: number (%) of responders and odds ratio (95% CI) for the difference between suvorexant and placebo.Suvorexant 20/15 mg differences versus placebo for sleep maintenance and sleep onset endpoints in subgroups defined by age, gender, race, region, baseline severity, cohort, and entry criteria are shown in Figure S2 (sleep maintenance) and Figure S3 (sleep onset) in the supplemental material. The findings were generally consistent across the subgroups (95% CIs overlapped) and mirrored those for the overall population.SafetyAEs over 3 months are summarized in Table 4. Patients treated with suvorexant 20/15mg had generally similar incidences of any AEs or discontinuations due to AEs compared with placebo. The proportion of patients with serious adverse events was similar among the treatment groups and there was no important difference between treatment groups in the specific types of serious adverse events that were reported. The proportion of patients that had drug-related AEs was somewhat higher with suvorexant, but none of the drug-related AEs were serious. The most common AE that was increased for suvorexant versus placebo was next-day somnolence (6.7% versus 3.3%). As shown in Table 5, somnolence rarely resulted in discontinuation and was mostly mild or moderate in severity. Among patients assigned to suvorexant who reported somnolence within 3 months, 62% experienced it within the first week and 93% experienced it within the first month (Table 5). Of the 33 patients on suvorexant 20/15 mg who initially reported somnolence within 3 months, 2 had a subsequent report.Table 4 Summary of adverse events over 3 months for P028+P029: number (%) of patients by treatment.Table 4 Summary of adverse events over 3 months for P028+P029: number (%) of patients by treatment.Table 5 Summary of somnolence adverse events over 3 months for P028+P029: number (%) of patients by treatment except where noted.Table 5 Summary of somnolence adverse events over 3 months for P028+P029: number (%) of patients by treatment except where noted.The incidence of predefined ECIs over 3 months is shown in Table 4. The most common category for both suvorexant and placebo was events that could potentially indicate abuse, but most appeared to be drug administration errors without evidence of intentional misuse (investigators were instructed to report potential study medication misuse when a patient returned less study medication than expected and denied taking extra study medication; review of these cases suggested that the majority of events were due to accidental loss of study medication). Other ECIs reported in ≥ 1 patient on suvorexant but no patients on placebo included hypnagogic hallucination (n = 1), hypnopompic hallucination (n = 1), and sleep paralysis (n = 1). The proportions of patients reporting excessive daytime sleepiness (defined as more persistent daytime sleepiness than typical next-day residual somnolence and associated with impairment) were low in all groups but higher for suvorexant (0.6%, n = 3) versus placebo (0.1%, n = 1). There were no reports of cataplexy confirmed by adjudication in either group. The proportions of patients with falls and motor vehicle accident or violation events were similar in both treatment groups.Over 3 months, based on clinician's assessments of adverse events and patient responses to the Columbia Suicide Severity Rating Scale, suicidal ideation was reported by 1 patient on suvorexant and 1 patient on placebo. Both reports were associated with clearly identified precipitating stressful life events. No suicidal behavior was reported.The number of patients with ≥ 1 AE and with somnolence by age and gender subgroups for each treatment group are summarized in Table S2 in the supplemental material. Across all treatment groups, the elderly tended to have more AEs than the non-elderly and women tended to have more AEs than men. The pattern of findings for suvorexant versus placebo in age and gender subgroups generally mirrored those for the overall population, except that men receiving suvorexant did not show an increase in somnolence versus placebo whereas women did.No clear trends were seen between treatment groups with regard to the percentages of patients who met predetermined criteria on vital signs or ECG measures (Table S3 in the supplemental material), or with regard to changes in laboratory measures.Rebound InsomniaAnalyses of rebound insomnia for self-report endpoints during the first 3 nights of the run-out, and PSG endpoints on the first night, are summarized in Table 6. There were no statistically significant differences between the suvorexant→placebo group and the placebo→placebo group on any measure on any night. The supportive approach looking at mean changes from baseline in minutes also showed that in both groups (suvorexant→placebo and placebo→placebo) self-report and PSG endpoints either continued to be improved from baseline during the run-out nights or were comparable to baseline (in the case of suvorexant→placebo for sTSO on Night 1), i.e., the mean values did not worsen relative to baseline (Table S4 in the supplemental material).Table 6 Number and percentage of patients meeting criteria for rebound insomnia on self-report endpoints during the first 3 nights of the run-out phase, and meeting criteria for rebound insomnia on PSG endpoints during the first night of the run-out for P028+P029.Table 6 Number and percentage of patients meeting criteria for rebound insomnia on self-report endpoints during the first 3 nights of the run-out phase, and meeting criteria for rebound insomnia on PSG endpoints during the first night of the run-out for P028+P029.WithdrawalAnalyses of change in Tyrer Withdrawal Symptom Questionnaire scores during the first 3 nights of the run-out are summarized in Table S5 in the supplemental material. There were no significant differences in the numbers of patients meeting the prespecified withdrawal criteria for the comparisons of the suvorexant→suvorexant group versus the suvorexant→placebo group.Residual EffectsNo statistically significant differences were observed between suvorexant and placebo in terms of baseline-adjusted number of correct responses or attempted responses on the DSST (Table S6 in the supplemental material).DISCUSSIONThese prespecified analyses of pooled data from phase-3 trials8 showed that 20/15 mg doses of suvorexant improved self-report and PSG measures of sleep onset and sleep maintenance at the initiation of treatment and over 3 months of nightly use. Generally, effects were greater on objective than subjective measures. Suvorexant 20/15 mg also improved patients' ratings of sleep quality and feeling refreshed in the morning. The global benefits of these improvements in sleep were reflected in patient and clinician global assessments of insomnia severity and improvement, and in a variety of responder analyses including changes in ISI. The efficacy of suvorexant 20/15 mg was consistent across subgroups including those defined by age and gender.Of particular interest was the observation that the PSG measure of hour-by-hour wake time during the night generally showed improvement for suvorexant 20/15 mg versus placebo from 2 through 8 hours, although this effect was somewhat diminished at Month 3. This pattern of findings differs from that reported for extended release zolpidem which improves PSG sleep maintenance during the first 4 to 5 hours of the night.23 However, this difference has not been examined in a direct head-to-head study. Importantly, for most patients the greatest amount of wake time is in the last 3 hours of the night, as is evidenced in the placebo group. This is probably due to the circadian timing of histamine and orexin release and the dissipation of homeostatic sleep drive.24This pooled analysis also showed that suvorexant 20/15 mg was generally well tolerated over 3 months, and most patients completed the planned 3 months of treatment. The most common AE associated with suvorexant was somnolence which mostly occurred early during treatment (within the first week to month), was generally mild-to-moderate in severity, and rarely resulted in discontinuation. Severe and impairing daytime somnolence, prospectively defined as the ECI of “excessive daytime sleepiness,” occurred in more patients on suvorexant 20/15 mg than placebo but was infrequent (0.6%). DSST scores suggested that suvorex