Hostname: page-component-8448b6f56d-m8qmq Total loading time: 0 Render date: 2024-04-24T00:35:00.637Z Has data issue: false hasContentIssue false
  • English
  • Français

The efficacy of levomilnacipran ER across symptoms of major depressive disorder: a post hoc analysis of 5 randomized, double-blind, placebo-controlled trials

Published online by Cambridge University Press:  13 June 2016

Roger S. McIntyre ,
Carl Gommoll ,
Changzheng Chen  and
Adam Ruth
Roger S. McIntyre*
Affiliation:
Department of Psychiatry and Pharmacology, University of Toronto, Toronto, Ontario, Canada Mood Disorders Psychopharmacology Unit, University Health Network, Toronto, Ontario, Canada
Carl Gommoll
Affiliation:
Department of Clinical Development, Forest Research Institute, Inc. (an Allergan affiliate), Jersey City, New Jersey, USA
Changzheng Chen
Affiliation:
Department of Statistical Science, Forest Research Institute, Inc. (an Allergan affiliate), Jersey City, New Jersey, USA
Adam Ruth
Affiliation:
Prescott Medical Communications Group, Chicago, Illinois, USA
*
*Address for correspondence: Roger S McIntyre, MD, FRCPC, Mood Disorders Psychopharmacology Unit, University Health Network, 399 Bathurst Street, Toronto, ON M5T 2S8, Canada. (Email: roger.mcintyre@uhn.ca)
Rights & Permissions [Opens in a new window]

Abstract

Objective

A post hoc analysis evaluated the effects of levomilnacipran ER on individual symptoms and symptom domains in adults with major depressive disorder (MDD).

Methods

Data were pooled from 5 Phase III trials comprising 2598 patients. Effects on depression symptoms were analyzed based on change from baseline in individual Montgomery–Åsberg Depression Rating Scale (MADRS) item scores. A1dditional evaluations included resolution of individual symptoms (defined as a MADRS item score ≤1 at end of treatment) and concurrent resolution of all 10 MADRS items, all MADRS6 subscale items, and all items included in different symptom clusters (Dysphoria, Retardation, Vegetative Symptoms, Anhedonia).

Results

Significantly greater mean improvements were found on all MADRS items except Reduced Appetite with levomilnacipran ER treatment compared with placebo. Resolution of individual symptoms occurred more frequently with levomilnacipran ER than placebo for each MADRS item (all P<.05), with odds ratios (ORs) ranging from 1.26 to 1.75; resolution of all 10 items was also greater with levomilnacipran ER (OR=1.57; P=.0051). Significant results were found for the MADRS6 subscale (OR=1.73; P<.0001) and each symptom cluster (OR range, 1.39 [Vegetative Symptoms] to 1.84 [Retardation]; all clusters, P<.01).

Conclusion

Adult MDD patients treated with levomilnacipran ER improved across a range of depression symptoms and symptom domains.

Keywords

Antidepressantdepressionremissionsymptom clusterstreatment
Type
Original Research
Information
CNS Spectrums , Volume 21 , Issue 5 , October 2016 , pp. 385 - 392
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© Cambridge University Press 2016

Introduction

Although a diagnosis of major depressive disorder (MDD) requires the presence of several key symptoms, there is wide variation among individual patients in terms of clinical presentation.Reference Rush 1 The symptomatic heterogeneity of MDD was recently documented in a post hoc analysis of the Sequenced Treatment Alternatives to Relieve Depression (STAR*D) trial, which identified 1030 unique symptom profiles based on responses from 3703 patients on the 16-item Quick Inventory of Depression Symptoms (QIDS-16) scale.Reference Fried and Nesse 2 Given such findings, it is not surprising that individuals respond differently to available antidepressants, and optimization of treatment may require selecting medications that target specific types of symptoms.Reference Nutt 3 One such approach has been to identify groups of related symptoms and subsequently evaluate the effects of various pharmacotherapies on the pre-specified symptom clusters.Reference Suzuki, Aoshima and Fukasawa 4 Reference van Loo, Cai and Gruber 7 Although different instruments and statistical models have been used in this area of research, studies have generally indicated that symptom clusters may be an important index of treatment response.

Failure to achieve full symptom remission is also a major challenge in MDD. Residual symptoms after acute treatment have been associated with more recurrent episodes, greater functional impairment and disability, and increased economic costs.Reference McIntyre and O’Donovan 8 Improvements in different symptom domains may have varying effects on social and occupational functioning, as suggested by results indicating that remission of select mood and anxiety symptoms (in the absence of pain) had a stronger association with functional improvements than remission of insomnia symptoms or the absence of pain alone.Reference Romera, Perez and Ciudad 9 Residual fatigueReference Fava, Ball and Nelson 10 and cognitive problemsReference Bortolato, Carvalho and McIntyre 11 have also been associated with greater functional impairment, providing the impetus for characterizing and specifically targeting symptom domains in MDD.

Levomilnacipran extended-release (ER) is a serotonin and norepinephrine reuptake inhibitor (SNRI) that is currently approved for the treatment of MDD in adults. In 3 pivotal trialsReference Asnis, Bose, Gommoll, Chen and Greenberg 12 Reference Sambunaris, Bose and Gommoll 14 and 1 proof-of-concept trial,Reference Montgomery, Mansuy and Ruth 15 the superiority of levomilnacipran ER to placebo was demonstrated on the basis of statistically significant reductions in overall depression symptomatology, as assessed by mean change from baseline in the Montgomery–Åsberg Depression Rating Scale (MADRS)Reference Montgomery and Asberg 16 total score. The current post hoc analysis of 5 studies,Reference Asnis, Bose, Gommoll, Chen and Greenberg 12 Reference Montgomery, Mansuy and Ruth 15 , Reference Gommoll, Greenberg and Chen 17 all of which used MADRS total score as the primary efficacy measure, was conducted in order to evaluate the effects of levomilnacipran ER on individual symptoms and on different symptom clusters. Preliminary analyses were also conducted to explore the relationship between symptom remission and improvements in functional impairment.

Methods

Study designs

Post hoc analyses were conducted on data pooled from 5 randomized, double-blind, placebo-controlled trials of levomilnacipran ER. These included 2 fixed-doseReference Asnis, Bose, Gommoll, Chen and Greenberg 12 , Reference Bakish, Bose and Gommoll 13 and 3 flexible-dose trialsReference Sambunaris, Bose and Gommoll 14 , Reference Montgomery, Mansuy and Ruth 15 , Reference Gommoll, Greenberg and Chen 17 in which patients received 8 weeksReference Asnis, Bose, Gommoll, Chen and Greenberg 12 Reference Sambunaris, Bose and Gommoll 14 , Reference Gommoll, Greenberg and Chen 17 or 10 weeksReference Montgomery, Mansuy and Ruth 15 of double-blind treatment with levomilnacipran ER (40–120 mg/day) or placebo.

Methods for all 5 trials have been previously published. Briefly, they included adults with MDD who had a current major depressive episode. Patients entering the 4 U.S. studies were required to have a MADRS total score ≥26Reference Bakish, Bose and Gommoll 13 or ≥30,Reference Asnis, Bose, Gommoll, Chen and Greenberg 12 , Reference Sambunaris, Bose and Gommoll 14 , Reference Gommoll, Greenberg and Chen 17 with 1 study also requiring a Clinical Global Impression of Severity score ≥4.Reference Bakish, Bose and Gommoll 13 Patients in the non-U.S. studyReference Montgomery, Mansuy and Ruth 15 were required to have a 17-item Hamilton Rating Scale for Depression (HAMD17) total score >22 and Sheehan Disability Scale (SDS) total score ≥10 with at least 1 subscale score ≥6. Patients with a principal Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition, Text Revision (DSM-IV-TR) Axis I diagnosis other than MDD, social anxiety disorder, generalized anxiety disorder, or specific phobia were excluded from the U.S. studies. The non-U.S. study also excluded patients if the onset of an allowed comorbid psychiatric illness (eg, panic disorder, obsessive compulsive disorder, generalized anxiety disorder, posttraumatic stress disorder) preceded the current depressive episode. All of the studies excluded patients who had a history of nonresponse to ≥2 antidepressants after adequate treatment or a significant risk of suicide based on investigator judgment or formal assessment (eg, Columbia-Suicide Severity Rating Scale, Mini-International Neuropsychiatric Interview).

Post hoc analyses

Analyses were conducted in the pooled ITT Population, which was defined as all randomized patients who received ≥1 dose of double-blind study medication and had ≥1 post-baseline MADRS assessment. For each MADRS item, the least squares mean change from baseline at end of treatment and at study visits (Weeks 1, 2, 4, 6, and 8) were analyzed using an analysis of covariance (ANCOVA) model with study, pooled study sites, and treatment as factors and baseline item scores as covariates; missing data were imputed using the last observation carried forward approach. Treatment effect sizes were estimated using the Cohen’s d calculation.

Symptom resolution, defined as no/minimal symptoms after treatment (MADRS item score ≤1), was analyzed in patients from the ITT Population who completed the final study visit at Week 8 (Week 10 in the non-U.S. study). Symptom resolution was analyzed for each individual MADRS item in all study completers, as well as in completers who had moderate-to-severe symptom severity at baseline, defined as a MADRS item score ≥4. These cut-offs were based on the defined scale steps (ie, scores 0, 2, 4, and 6) for the MADRS items; for each MADRS item, these steps are accompanied by descriptors that suggest no/minimal symptoms (score 0 or 1), mild symptoms (score 2 or 3), moderate symptoms (score 4 or 5), or severe symptoms (score 6). Also analyzed was the percentage of patients after treatment who had no/minimal symptoms on all 10 MADRS items and on all 6 items that constitute the MADRS6 Subscale (items 1 [Apparent Sadness], 2 [Reported Sadness], 3 [Inner Tension], 7 [Lassitude], 8 [Inability to Feel], and 9 [Pessimistic Thoughts]).Reference Bech, Tanghøj, Andersen and Overø 18

Based on symptom clusters that have been previously defined in the literature,Reference Suzuki, Aoshima and Fukasawa 4 analyses were conducted to determine the percentage of patients with remission on all items in each of the following clusters: Dysphoria (items 2 [Reported Sadness], 9 [Pessimistic Thoughts], 10 [Suicidal Thoughts]); Retardation (items 1 [Apparent Sadness], 6 [Concentration Difficulties], 7 [Lassitude], 8 [Inability to Feel]); and Vegetative Symptoms (items 3 [Inner Tension], 4 [Reduced Sleep], 5 [Reduced Appetite]). Since anhedonia is a core feature of MDD,Reference Treadway and Zald 19 an Anhedonia cluster (items 5 [Reduced Appetite], 7 [Lassitude], 8 [Inability to Feel], 10 [Suicidal Thoughts]) was defined for this post hoc analysis. For all symptom resolution outcomes, odds ratios (ORs) with 95% confidence intervals (95% CI) were estimated using a logistic regression model with treatment as a factor and baseline scores as covariates.

Results

In the pooled ITT Population, demographics and baseline characteristics were similar between treatment groups (Table 1). The highest mean baseline scores were found for MADRS items 1 (Apparent Sadness), 2 (Reported Sadness), and 8 (Inability to Feel).

Table 1 Patient demographics and baseline characteristics

BMI, body mass index; ER, extended release; MADRS, Montgomery–Åsberg Depression Rating Scale; SD, standard deviation.

In this overall population, significantly greater mean improvements from baseline to end of treatment were seen with levomilnacipran ER compared with placebo on all MADRS items except Reduced Appetite (Figure 1). The largest effect sizes were found in Apparent Sadness, Reported Sadness, Concentration Difficulties, and Inability to Feel (all Cohen’s d ≥0.2). By Week 1 of double-blind treatment, statistically significant differences between treatment groups were detected for Apparent Sadness, Reported Sadness, Lassitude, and Inability to Feel (Figure 2). By Week 2, significant differences in favor of levomilnacipran ER were detected for Concentration Difficulties, Pessimistic Thoughts, and Suicidal Thoughts.

Figure 1 Mean improvements in MADRS items at end of treatment. *P<.05; ***P<.001 versus placebo. ER, extended release; LS, least squares; LSMD, least squares mean difference between treatment groups; MADRS, Montgomery–Åsberg Depression Rating Scale.

Figure 2 Statistical separation between levomilnacipran ER and placebo in MADRS items by study visit. Analysis was based on least squares mean changes from baseline in individual MADRS item scores using last observation carried forward. Color change from white to black indicates the first study visit at which a statistically significant (P<.05) difference between treatment groups was detected and remained significant at every subsequent study visit. Analysis does not include Week 10 data from the non-U.S. study.Reference Montgomery, Mansuy and Ruth 15 ER, extended release; MADRS, Montgomery–Åsberg Depression Rating Scale.

Among study completers, the percentage of patients with symptom resolution (ie, no/minimal symptoms, defined as MADRS item score ≤1) at end of treatment was significantly higher with levomilnacipran ER than placebo for each MADRS item, with ORs ranging from 1.26 (Reduced Sleep, Reduced Appetite) to 1.75 (Apparent Sadness) (Figure 3A). In study completers who had moderate-to-severe depression symptoms at baseline (MADRS item score ≥4), the percentage of patients with symptom resolution was significantly higher with levomilnacipran ER versus placebo on all MADRS items except for Suicidal Thoughts, which only included 85 patients (Figure 3B). The ORs in the group with moderate-to-severe baseline symptoms were similar to those found in the overall completer population, ranging from 1.32 (Reduced Sleep) to 2.07 (Suicidal Thoughts).

Figure 3 Percentage of patients with no/minimal symptoms at end of treatment. No/minimal symptoms defined as a MADRS item score ≤1 at Week 8/10. Analyses were conducted in the following groups: (A) all patients who completed the study (placebo, n=834; levomilnacipran ER, n=1181); and (B) study completers who had moderate-to-severe symptoms at baseline, defined as a MADRS item score ≥4 (n-values for each item indicated in the figure). *P<.05; **P<.01; ***P<.001 versus placebo. CI, confidence interval; ER, extended release; MADRS, Montgomery-Asberg Depression Rating Scale.

The percentage of patients with concurrent resolution of all 10 MADRS items, all MADRS6 Subscale items, and all items in each symptom cluster (Dysphoria, Retardation, Vegetative Symptoms, Anhedonia) was also significantly greater with levomilnacipran ER compared with placebo (Figure 4). The largest between-group rate differences were found in the Retardation cluster (8.3%; OR=1.84; P<.0001) and Anhedonia cluster (8.3%; OR=1.65; P<.0001).

Figure 4 Percentage of patients with no/minimal symptoms across different symptom clusters. **P<.01; ***P<.001 versus placebo. CI, confidence interval; ER, extended release; MADRS, Montgomery-Åsberg Depression Rating Scale.

Figure 5 SDS remission in patients with no/minimal residual symptoms. *P<.05 versus placebo. ER, extended release; MADRS, Montgomery–Åsberg Depression Rating Scale; SDS, Sheehan Disability Scale.

Discussion

A previous post hoc analysis of the 5 clinical trials included in this report showed that adults with MDD who were treated with levomilnacipran ER had clinically relevant and statistically significant improvements in overall depression severity as assessed using MADRS total score, including greater rates of response and remission.Reference Montgomery, Gommoll, Chen and Greenberg 20 The current post hoc analysis was conducted using individual MADRS items as outcome measures in order to assess the effects of levomilnacipran ER on specific symptoms and the probability of achieving resolution of individual symptoms and symptom clusters.

Results of the current analysis showed significantly greater mean improvements on 9 of the 10 MADRS items, with the highest Cohen’s effect sizes found in Apparent Sadness, Concentration Difficulties, Reported Sadness, and Inability to Feel. Onset of symptom improvement with levomilnacipran ER was rapid for Apparent Sadness, Reported Sadness, Lassitude, Inability to Feel, Concentration Difficulties, Pessimistic Thoughts, and Suicidal Thoughts as indicated by statistical separation from placebo within the first 2 weeks of double-blind treatment. These early improvements may be clinically relevant, as suggested by an analysis of STAR*D data, which found that Week 2 improvements in similar QIDS-16 items (ie, feeling sad, view of myself, energy level, feeling slowed down, feeling restless) were significantly associated with achieving remission of overall depression at Week 14.Reference Sakurai, Uchida and Abe 21 The broader importance of early symptom improvement has been established in a meta-analysis of 41 MDD clinical trials that included different classes of antidepressant medications.Reference Szegedi, Jansen and van Willigenburg 22 Results of this analysis showed that a ≥20% decrease in overall depression severity at Week 2 was highly predictive of “stable” response and symptom remission, as observed at Week 4 and maintained at all subsequent study visits.

Results indicating resolution of each MADRS item (ie, score ≤1 at Week 8/10 of double-blind treatment) suggest a possible relationship between early levomilnacipran ER effects and end-of-treatment outcomes, although this association was not formally investigated in the current post hoc analysis. The 7 MADRS items that had shown significant treatment–placebo differences at Week 1 or 2 were the same items with the greatest ORs for symptom resolution at end of treatment in the overall completer population (range, 1.42 [Lassitude] to 1.75 [Apparent Sadness]). However, the high percentage of patients in this analysis who had no/minimal symptoms for the Suicidal Thoughts item (>85% in each treatment group), coupled with the relatively low mean score changes for both placebo and levomilnacipran ER (–0.4 and –0.6, respectively), suggest possible ceiling and floor effects that may have been due to low mean baseline scores, which probably resulted from the exclusion of patients with suicidal ideation or behavior. To adjust for such effects, symptom resolution was analyzed in study completers who had moderate-to-severe symptoms at baseline, defined as MADRS item scores of 4 or higher. Three items (ie, Reduced Appetite, Pessimistic Thoughts, and Suicidal Thoughts) were found for which<50% of the completer population had a baseline score ≥4. The ORs for these 3 items in patients with moderate-to-severe baseline symptoms (1.62, 1.67, and 2.07, respectively) were higher than in the overall completer population (1.26, 1.43, and 1.69, respectively), indicating the need for clinicians to inquire about the severity of specific depression-related symptoms when making treatment decisions.

Perhaps more important than the analyses based on individual MADRS item scores was the analysis of concurrent symptom resolution on all 10 MADRS items. Although the percentage of patients who met this definition was significantly higher with levomilnacipran ER than with placebo (11.2% vs 7.8%; P<.01), the rates in both groups were lower than the percentage of patients who had met the more conventional definition of MADRS remission (total score ≤10)Reference Zimmerman, Posternak and Chelminski 23 in the previous post hoc analysis (27.7% vs 21.5%; P<.05).Reference Montgomery, Gommoll, Chen and Greenberg 20 This difference suggests that although the criteria for remission may seem mathematically similar between the 2 post hoc analyses, the criteria used in the present analysis represent a more stringent benchmark of complete symptom remission. The difference between MADRS item-level remission and MADRS total score remission also suggests that there may have been a heterogeneity of treatment response in the levomilnacipran ER studies. In other words, results from the current analysis suggest that some patients with a MADRS total score ≤10 may have had complete remission (score of 0) on certain clusters of items and residual symptoms (score ≥2) on other items, with likely variation across individual patients.

The question of whether specific types or clusters of symptoms may have been more responsive to levomilnacipran ER treatment was addressed by conducting analyses in symptom domains that have been previously reported in the literature. These included the MADRS6 subscale,Reference Bech, Tanghøj, Andersen and Overø 18 , Reference Bech, Tanghøj, Cialdella, Andersen and Pedersen 24 3 symptom clusters (Dysphoria, Retardation, Vegetative Symptoms) that were derived using a factor analysis of individual MADRS items,Reference Suzuki, Aoshima and Fukasawa 4 and an Anhedonia cluster defined for this post hoc analysis to include MADRS items 5, 7, 8, and 10 based on symptoms that indicate lack of pleasure or volition.Reference Der-Avakian and Markou 25 Although changes in factor scores have been used to evaluate the effects of antidepressant treatment and nonpharmacologic therapies on the Dysphoria, Retardation, and Vegetative Symptoms clusters,Reference Higuchi, Sato and Yoshida 26 Reference Alonzo, Chan, Martin, Mitchell and Loo 28 this is the first analysis (to our knowledge) to examine symptom resolution within the clusters. The results indicate that a significantly higher percentage of levomilnacipran ER-treated patients than placebo-treated patients had substantial improvements in all 3 symptom domains, as well as in the Anhedonia cluster and in core depression symptoms as represented by the MADRS6 subscale.

Results from our analyses, however, also suggest that levomilnacipran ER may have had differential effects across the various symptom domains. For example, the largest treatment effect in this post hoc analysis was found in the Retardation cluster (OR=1.84), which was greater than the effect seen in patients who had resolution on core items comprising the MADRS6 subscale (OR=1.73) or even on all 10 MADRS items (OR=1.57). These results may have been partly due to the effects of levomilnacipran ER on symptoms that are associated with deficits in noradrenergic transmission such as reduced energy and alertness, difficulties with concentration and attention, and loss of interest in surroundings and activity.Reference Nutt 3

Conversely, although still statistically significant, the smallest treatment effect was seen in the Vegetative Symptoms cluster (OR=1.39), which includes items (ie, Inner Tension, Reduced Sleep, Reduced Appetite) that are associated with increased noradrenergic activity and activation of the stress response system.Reference Gold and Chrousos 29 However, some patients—such as those with atypical depression—have symptoms that are associated with decreased noradrenergic activity, including feelings of disconnectedness and emptiness, lethargy, excessive sleep, increased food intake, and weight gain. Given the effects of levomilnacipran ER on certain items in the Retardation cluster (eg, Concentration Difficulties, Lassitude, Inability to Feel), it seems reasonable to surmise that this agent would have similar effects on depression-related hypersomnolence and overeating. This presumption could not be tested in the current patient population, since such symptom assessments are not included in either of depression scales (MADRS, HAMD17) used in the levomilnacipran ER studies. However, the known limited effects of serotonergic antidepressants on atypical depression,Reference Rapaport and Thase 30 coupled with findings that symptoms of atypical depression significantly predict treatment response to the SNRI duloxetine,Reference Howland, Wilson and Kornstein 31 suggest that MDD patients who have increased sleep and/or appetite may benefit from medications that elevate norepinephrine levels.

In addition to symptom improvement, patients who received levomilnacipran ER in the trials included herein had significant improvements in functional impairment, as demonstrated in 2 previously published analyses based on different SDS outcomes including response, remission, and categorical shifts.Reference Sambunaris, Gommoll, Chen and Greenberg 32 , Reference Cutler, Gommoll, Chen, Greenberg and Ruth 33 Such findings are not surprising, since a number of other MDD studies have shown that reduced symptom severity is associated with increased functional ability.Reference Lam, Filteau and Milev 34 The results of the current post hoc analysis, however, may shed some light on the types of symptoms that may have been driving SDS improvements in the levomilnacipran ER studies. Of the 8 MADRS items that were included in the 2 groups with the largest treatment effects, Concentration Difficulties was unique to the Retardation cluster, and Apparent Sadness, Lassitude, and Inability to Feel were common to both the Retardation cluster and the MADRS6 subscale. Further analyses would be needed to evaluate how improvements in these types of symptoms might affect functional outcomes.

The major limitation of these analyses is that they were conducted post hoc, and no efficacy outcomes based on individual MADRS items had been defined a priori. In addition, any inferences about the differential treatment effects on symptom clusters are limited to acute treatment with levomilnacipran ER; such differences may be more or less apparent with longer treatment durations. Because there were no active comparators in any of the trials, no conclusions can be drawn regarding the effects of levomilnacipran ER relative to other antidepressants. Finally, findings from this study population may not be generalizable to more diverse clinic- and hospital-based populations.

Conclusions

This post hoc analysis of MADRS item data from 5 Phase III studies indicates that patients treated with levomilnacipran ER versus placebo had significantly greater mean improvements and higher rates of symptom resolution across a range of depression symptoms and in different symptom domains. Moreover, levomilnacipran ER–treated patients had significantly greater odds of achieving resolution across multiple symptom domains, including all 10 MADRS items. The strongest treatment effect was found in the Retardation cluster, suggesting that fatigue- and cognition-related symptoms of depression may be particularly responsive to levomilnacipran ER.

Disclosures

Roger McIntyre has the following disclosures: consulting and speaker, consulting fee: AstraZeneca, Eli Lilly, Johnson & Johnson, Takeda, Pfizer, Lundbeck, Otsuka, Sunovion, Allergan, and BMS. Carl Gommoll has the following disclosure: Actavis pic, employee, salary, stock/stock options. Changzheng Chen has the following disclosure: Actavis pic, employee, salary, stock/stock options. Adam Ruth has the following disclosure: Prescott Medical Communications Group (at time of the studies), a contractor of Forest Research Institute, employee, salary.

Footnotes

This analysis and the studies included in the analysis were supported by Forest Laboratories, LLC, an Allergan affiliate.

The authors thank William Greenberg for his contributions to the planning and early development of this manuscript. At the time of the studies, Dr. Greenberg was a full-time employee of Forest Research Institute, an Allergan affiliate. Writing and editorial assistance was provided by Mildred Bahn at Prescott Medical Communications Group (Chicago, IL), a contractor for Forest Research Institute.

References

1. Rush, AJ. The varied clinical presentations of major depressive disorder. J Clin Psychiatry. 2007; 68(Suppl 8): 410.Google ScholarPubMed
2. Fried, EI, Nesse, RM. Depression is not a consistent syndrome: an investigation of unique symptom patterns in the STAR*D study. J Affect Disord. 2014; 172C: 96102.Google Scholar
3. Nutt, DJ. Relationship of neurotransmitters to the symptoms of major depressive disorder. J Clin Psychiatry. 2008; 69(Suppl E1): 47.Google Scholar
4. Suzuki, A, Aoshima, T, Fukasawa, T, et al. A three-factor model of the MADRS in major depressive disorder. Depress Anxiety. 2005; 21(2): 9597.Google Scholar
5. Paavonen, V, Kampman, O, Illi, A, et al. A cluster model of temperament as an indicator of antidepressant response and symptom severity in major depression. Psychiatry Investig. 2014; 11(1): 1823.Google Scholar
6. Schacht, A, Gorwood, P, Boyce, P, Schaffer, A, Picard, H. Depression symptom clusters and their predictive value for treatment outcomes: results from an individual patient data meta-analysis of duloxetine trials. J Psychiatr Res. 2014; 53: 5461.Google Scholar
7. van Loo, HM, Cai, T, Gruber, MJ, et al. Major depressive disorder subtypes to predict long-term course. Depress Anxiety. 2014; 31(9): 765777.Google Scholar
8. McIntyre, RS, O’Donovan, C. The human cost of not achieving full remission in depression. Can J Psychiatry. 2004; 49(3 Suppl 1): 10S16S.Google Scholar
9. Romera, I, Perez, V, Ciudad, A, et al. Residual symptoms and functioning in depression, does the type of residual symptom matter? A post-hoc analysis. BMC Psychiatry. 2013; 13: 51.Google Scholar
10. Fava, M, Ball, S, Nelson, JC, et al. Clinical relevance of fatigue as a residual symptom in major depressive disorder. Depress Anxiety. 2014; 31(3): 250257.Google Scholar
11. Bortolato, B, Carvalho, AF, McIntyre, RS. Cognitive dysfunction in major depressive disorder: a state-of-the-art clinical review. CNS Neurol Disord Drug Targets. 2014; 13(10): 18041818.Google Scholar
12. Asnis, G, Bose, A, Gommoll, C, Chen, C, Greenberg, WM. The efficacy and safety of levomilnacipran SR 40 mg, 80 mg, or 120 mg in major depressive disorder: a phase III, randomized, double-blind, placebo-controlled study. J Clin Psychiatry. 2013; 74(3): 242248.Google Scholar
13. Bakish, D, Bose, A, Gommoll, C, et al. Levomilnacipran ER 40 mg and 80 mg in patients with major depressive disorder: a phase III, randomized, double-blind, fixed-dose, placebo-controlled study. J Psychiatry Neurosci. 2014; 39(1): 4049.Google Scholar
14. Sambunaris, A, Bose, A, Gommoll, C, et al. A phase III, double-blind, placebo-controlled, flexible-dose study of levomilnacipran ER in patients with major depressive disorder. J Clin Pscyhopharmacol. 2014; 34(1): 4756.Google Scholar
15. Montgomery, SA, Mansuy, L, Ruth, A, et al. Efficacy and safety of levomilnacipran sustained release in moderate to severe major depressive disorder: a randomized, double-blind, placebo-controlled, proof-of-concept study. J Clin Psychiatry. 2013; 74(4): 363369.Google Scholar
16. Montgomery, SA, Asberg, M. A new depression scale designed to be sensitive to change. Br J Psychiatry. 1979; 134(4): 382389.Google Scholar
17. Gommoll, CP, Greenberg, WM, Chen, C. A randomized, double-blind, placebo-controlled study of flexible doses of levomilnacipran ER (40–120 mg/day) in patients with major depressive disorder. Journal of Drug Assessment. 2014; 3(1): 1019.Google Scholar
18. Bech, P, Tanghøj, P, Andersen, HF, Overø, K. Citalopram dose-response revisited using an alternative psychometric approach to evaluate clinical effects of four fixed citalopram doses compared to placebo in patients with major depression. Psychopharmacology (Berl). 2002; 163(1): 2025.CrossRefGoogle ScholarPubMed
19. Treadway, MT, Zald, DH. Reconsidering anhedonia in depression: lessons from translational neuroscience. Neurosci Biobehav Rev. 2011; 35(3): 537555.Google Scholar
20. Montgomery, SA, Gommoll, CP, Chen, C, Greenberg, WM. Efficacy of levomilnacipran extended-release in major depressive disorder: pooled analysis of 5 double-blind, placebo-controlled trials. CNS Spectr. 2015; 20(2): 148156.Google Scholar
21. Sakurai, H, Uchida, H, Abe, T, et al. Trajectories of individual symptoms in remitters versus non-remitters with depression. J Affect Disord. 2013; 151(2): 506513.Google Scholar
22. Szegedi, A, Jansen, WT, van Willigenburg, AP, et al. Early improvement in the first 2 weeks as a predictor of treatment outcome in patients with major depressive disorder: a meta-analysis including 6562 patients. J Clin Psychiatry. 2009; 70(3): 344353.Google Scholar
23. Zimmerman, M, Posternak, MA, Chelminski, I. Derivation of a definition of remission on the Montgomery-Asberg depression rating scale corresponding to the definition of remission on the Hamilton rating scale for depression. J Psychiatr Res. 2004; 38(6): 577582.Google Scholar
24. Bech, P, Tanghøj, P, Cialdella, P, Andersen, HF, Pedersen, AG. Escitalopram dose-response revisited: an alternative psychometric approach to evaluate clinical effects of escitalopram compared to citalopram and placebo in patients with major depression. Int J Neuropsychopharmacol. 2004; 7(3): 283290.CrossRefGoogle ScholarPubMed
25. Der-Avakian, A, Markou, A. The neurobiology of anhedonia and other reward-related deficits. Trends Neurosci. 2012; 35(1): 6877.Google Scholar
26. Higuchi, H, Sato, K, Yoshida, K, et al. Predictors of antidepressant response to fluvoxamine obtained using the three-factor structures of the Montgomery and Asberg Depression Rating Scale for major depressive disorders in Japanese patients. Psychiatry Clin Neurosci. 2008; 62(3): 301306.Google Scholar
27. Okazaki, M, Tominaga, K, Higuchi, H, et al. Predictors of response to electroconvulsive therapy obtained using the three-factor structure of the Montgomery and Asberg Depression Rating Scale for treatment-resistant depressed patients. J ECT. 2010; 26(2): 8790.Google Scholar
28. Alonzo, A, Chan, G, Martin, D, Mitchell, PB, Loo, C. Transcranial direct current stimulation (tDCS) for depression: analysis of response using a three-factor structure of the Montgomery-Asberg depression rating scale. J Affect Disord. 2013; 150(1): 9195.Google Scholar
29. Gold, PW, Chrousos, GP. Organization of the stress system and its dysregulation in melancholic and atypical depression: high vs low CRH/NE states. Mol Psychiatry. 2002; 7(3): 254275.Google Scholar
30. Rapaport, MH, Thase, ME. Translating the evidence on atypical depression into clinical practice. J Clin Psychiatry. 2007; 68(Suppl 3): 3136.Google Scholar
31. Howland, RH, Wilson, MG, Kornstein, SG, et al. Factors predicting reduced antidepressant response: experience with the SNRI duloxetine in patients with major depression. Ann Clin Psychiatry. 2008; 20(4): 209218.Google Scholar
32. Sambunaris, A, Gommoll, C, Chen, C, Greenberg, WM. Efficacy of levomilnacipran extended-release in improving functional impairment associated with major depressive disorder: pooled analyses of five double-blind, placebo-controlled trials. Int Clin Psychopharmacol. 2014; 29(4): 197205.CrossRefGoogle ScholarPubMed
33. Cutler, AJ, Gommoll, CP, Chen, C, Greenberg, WM, Ruth, A. Levomilnacipran ER treatment in patients with major depressive disorder: improvements in functional impairment categories. Prim Care Companion CNS Disord. 2015; 17(3). doi:10.4088/PCC.14m01753.Google Scholar
34. Lam, RW, Filteau, MJ, Milev, R. Clinical effectiveness: the importance of psychosocial functioning outcomes. J Affect Disord. 2011; 132(Suppl 1): S9S13.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Patient demographics and baseline characteristics

Figure 1

Figure 1 Mean improvements in MADRS items at end of treatment. *P<.05; ***P<.001 versus placebo. ER, extended release; LS, least squares; LSMD, least squares mean difference between treatment groups; MADRS, Montgomery–Åsberg Depression Rating Scale.

Figure 2

Figure 2 Statistical separation between levomilnacipran ER and placebo in MADRS items by study visit. Analysis was based on least squares mean changes from baseline in individual MADRS item scores using last observation carried forward. Color change from white to black indicates the first study visit at which a statistically significant (P<.05) difference between treatment groups was detected and remained significant at every subsequent study visit. Analysis does not include Week 10 data from the non-U.S. study.15 ER, extended release; MADRS, Montgomery–Åsberg Depression Rating Scale.

Figure 3

Figure 3 Percentage of patients with no/minimal symptoms at end of treatment. No/minimal symptoms defined as a MADRS item score ≤1 at Week 8/10. Analyses were conducted in the following groups: (A) all patients who completed the study (placebo, n=834; levomilnacipran ER, n=1181); and (B) study completers who had moderate-to-severe symptoms at baseline, defined as a MADRS item score ≥4 (n-values for each item indicated in the figure). *P<.05; **P<.01; ***P<.001 versus placebo. CI, confidence interval; ER, extended release; MADRS, Montgomery-Asberg Depression Rating Scale.

Figure 4

Figure 4 Percentage of patients with no/minimal symptoms across different symptom clusters. **P<.01; ***P<.001 versus placebo. CI, confidence interval; ER, extended release; MADRS, Montgomery-Åsberg Depression Rating Scale.

Figure 5

Figure 5 SDS remission in patients with no/minimal residual symptoms. *P<.05 versus placebo. ER, extended release; MADRS, Montgomery–Åsberg Depression Rating Scale; SDS, Sheehan Disability Scale.