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Abstract

Objective:

The Predictors of Remission in Depression to Individual and Combined Treatments [PReDICT] study aimed to identify clinical and biological factors predictive of treatment outcomes in major depressive disorder among treatment-naive adults. The authors evaluated the efficacy of cognitive-behavioral therapy (CBT) and two antidepressant medications (escitalopram and duloxetine) in patients with major depression and examined the moderating effect of patients’ treatment preferences on outcomes.

Method:

Adults aged 18–65 with treatment-naive major depression were randomly assigned with equal likelihood to 12 weeks of treatment with escitalopram (10–20 mg/day), duloxetine (30–60 mg/day), or CBT (16 50-minute sessions). Prior to randomization, patients indicated whether they preferred medication or CBT or had no preference. The primary outcome was change in the 17-item Hamilton Depression Rating Scale (HAM-D), administered by raters blinded to treatment.

Results:

A total of 344 patients were randomly assigned, with a mean baseline HAM-D score of 19.8 (SD=3.8). The mean estimated overall decreases in HAM-D score did not significantly differ between treatments (CBT: 10.2, escitalopram: 11.1, duloxetine: 11.2). Last observation carried forward remission rates did not significantly differ between treatments (CBT: 41.9%, escitalopram: 46.7%, duloxetine: 54.7%). Patients matched to their preferred treatment were more likely to complete the trial but not more likely to achieve remission.

Conclusions:

Treatment guidelines that recommend either an evidence-based psychotherapy or antidepressant medication for nonpsychotic major depression can be extended to treatment-naive patients. Treatment preferences among patients without prior treatment exposure do not significantly moderate symptomatic outcomes.
Choosing the initial form of treatment is the most fundamental decision clinicians face in caring for patients with major depressive disorder. Current guidelines recommend that most patients should initially be treated with either an antidepressant medication or an evidence-based psychotherapy (1), based on the roughly equivalent efficacy, on average, of psychotherapy and medication treatments for major depression (2). This average equivalency, however, masks the substantial variability in outcomes that exists across patients. There is great need to develop methods for identifying the best treatment for a particular individual depressed patient. Variously referred to as personalized medicine, precision medicine, or personalized intervention, this approach aims to match each individual patient to a treatment most likely to prove beneficial through identifying moderators of likely outcomes to specific treatment options (3, 4).
Few clinical or socio-demographic variables have emerged as prescriptive factors to allow specific differential recommendations of psychotherapy versus pharmacotherapy, and the identified factors are not consistent across studies. Previously identified moderators from large trials include lower cognitive dysfunction and greater work dysfunction predicting better outcomes with cognitive therapy and imipramine, respectively (5); a history of early childhood trauma and better response to a cognitive-behavioral analysis system of psychotherapy compared with nefazodone (6); being married, being unemployed, experiencing a greater number of recent life events, or prior treatment with antidepressants associated with superior improvement with cognitive therapy compared with pharmacotherapy (7, 8); and psychomotor activation predicting better overall outcome with a selective serotonin reuptake inhibitor (SSRI) compared with interpersonal therapy (9).
Studies of biological measures predicting outcomes in depression have primarily been conducted in studies of a single treatment modality (10). Though valuable, these studies do not inform clinicians about which treatment is likely to be better or worse for a given patient, necessary information for clinical decision making. An exception to this uncertainty was a recent positron emission tomography (PET) study, which found that metabolic activity in the right anterior insula differentially predicted treatment outcomes in patients with major depression treated with the SSRI escitalopram or cognitive-behavioral therapy (CBT) (11, 12). However, this finding awaits replication and formal experimental testing.
In the absence of useful treatment-prediction moderators for major depression, treatment guidelines recommend that patient preferences be considered for making treatment recommendations (1). Surveys of treatment- and non-treatment-seeking depressed patients have found that roughly 70% express a preference for psychotherapy over medication (13). The relative preference for psychotherapy may be even greater among ethnic minority groups, including Latinos (14) and African Americans (15), although these conclusions remain uncertain. In contrast, preference for medication has been associated with greater severity of illness (16).
Most randomized trials evaluating the effects of patient preference for medication or psychotherapy treatment have found no effect of preference on treatment efficacy (17), although two meta-analyses that examined the effects of preference across all studies (not limited to randomized trials) found a small effect of better outcomes among patients receiving their preferred treatment (18, 19). Treatment dropout or attrition is another important outcome related to preferences, with meta-analyses demonstrating that patients who do not receive their preferred treatment are more likely to terminate care prematurely (19).
An important potential confound for prediction medicine and the impact of preference on outcomes is patients’ prior lifetime treatment exposures (20). Prior treatment may introduce a selection bias in that patients’ willingness to participate in a randomized trial comparing active treatments might be affected by their prior experience with a particular treatment. A second, and highly salient, concern for personalized interventions is the possibility of persisting psychological (21, 22) or biological (23, 24) effects from previous treatments that affect response to treatments in a randomized trial. These considerations emphasize the value of treatment-naive patient samples for examining the effects of patient preferences and biological variables in predicting treatment outcomes.
To address the need for personalized medicine approaches for major depression, we conducted the Emory Predictors of Remission in Depression to Individual and Combined Treatments (PReDICT) study that aimed to identify patient-level biological and psychological factors that predict short- and long-term outcomes to three differing treatments: CBT, escitalopram, and duloxetine, a serotonin norepinephrine reuptake inhibitor (SNRI). To minimize confounding of associations between treatments and outcomes that could arise from patients’ prior treatment exposures, participation in this trial was limited to treatment-naive patients with major depressive disorder. Herein, we report the primary clinical results from the initial 12-week randomized monotherapy treatment phase, along with the effects of treatment preferences on outcomes. Based on our prior work (25), we hypothesized that there would be no effect of matching to preference on depression symptom outcomes but that mismatched patients would be more likely to terminate the trial prematurely.

Method

Study Overview

We previously published a detailed description of the PReDICT study rationale, methods, and design (26). The study was conducted through the Emory University Mood and Anxiety Disorders Program and involved two clinics: 1) the primary Mood and Anxiety Disorders Program Clinic at Emory University, including a satellite location in Stockbridge, Georgia, and 2) a purely Spanish-speaking clinic at Grady Hospital in Atlanta (27). The Emory Institutional Review Board and the Grady Hospital Research Oversight Committee granted study approval.

Patients

Patients were recruited primarily through advertising, although a minority of patients were referred from primary care clinics. All patients provided written, informed consent prior to beginning study procedures. The study enrolled men and women, aged 18–65 years, who met DSM-IV criteria for current major depressive disorder and who had never previously received treatment for a mood disorder. We defined “previous treatment” as patient-reported treatment for major depression, dysthymia, or depressive disorder not otherwise specified with either 1) a marketed antidepressant at a minimum effective dose for 4 or more consecutive weeks or 2) 4 or more sessions of an evidence-based and structured psychotherapy for depression (i.e., CBT, behavior therapy, interpersonal therapy, or behavioral marital therapy). Patients who had received prior supportive therapy were eligible, but they were not permitted to participate in such psychotherapy during the study.
Eligible patients had a primary psychiatric diagnosis of nonpsychotic major depressive disorder and a 17-item Hamilton Depression Rating Scale (HAM-D) (28) total score ≥18 at screening and ≥15 at the baseline visit. Exclusion criteria included a lifetime history of bipolar disorder, primary psychotic disorder, or dementia, or a current (past 12 months) diagnosis of obsessive-compulsive disorder, eating disorder, or dissociative disorder. Additionally, patients were excluded if they met DSM-IV criteria for substance abuse within 3 months, substance dependence within 12 months of the randomization visit, or if their urine tested positive for drugs of abuse. Additional exclusionary criteria included any lifetime treatment with citalopram, escitalopram, or duloxetine. Women who were, or planned on becoming, pregnant or breast-feeding during the trial were excluded, as were any patients with significant uncontrolled medical conditions, or any condition that could interfere with the study or the interpretation of the study results.

Diagnostic and Outcome Measures and Procedures

The diagnosis of major depressive disorder was made using the Structured Clinical Interview for DSM-IV Axis I Disorders (29) and confirmed through an evaluation by a study psychiatrist. In addition to the HAM-D, depressive symptoms were evaluated using the Montgomery-Åsberg Depression Rating Scale (MADRS) (30), and two patient self-report measures, the Beck Depression Inventory-I (BDI) (31) and the Quick Inventory of Depressive Symptomatology, Self-Report (32). Anxiety was assessed with the Hamilton Anxiety Rating Scale (HAM-A) (33). Demographic variables and family history of psychiatric illness were collected via self-report.

Assessment of Preferences

As part of the informed consent process, patients read paragraphs describing the medication and CBT treatments used in the study. The study physician also explained that, on average, people with major depression are equally likely to benefit from CBT or medication, and that the study’s goal was to identify characteristics of individuals that could be used to choose specific treatments for patients in the future. Patients were informed that their preference would not influence the treatment they received because treatment was assigned randomly and that in order to take part in the study they needed to be willing to start the type of treatment assigned to them. Preference was assessed by a single question asking patients if their preferred treatment was: “no preference,” “cognitive behavior therapy,” or “medication.” Those who expressed a preference then indicated whether the strength of their preference was “mild,” “moderate,” or “very strong” (25).

Randomization

Patients were randomly assigned 1:1:1 to one of three possible treatments: 1) escitalopram 10–20 mg/day, 2) duloxetine 30–60 mg/day, or 3) CBT, 16 individual sessions. In order to ensure equal allocation across treatment groups, prior to opening the study for enrollment, the treatment assignment was generated using randomized permuted blocks. Separate randomization blocks were stratified for the English- and Spanish-language clinics. The treatment assignments were placed in sealed opaque envelopes by Emory employees uninvolved in the study. At a patient’s baseline visit, after the study psychiatrist confirmed that all eligibility criteria for randomization had been met, within the patient’s clinic the study coordinator opened the next-in-sequence envelope to determine the treatment assignment.

Study Visits and Treatments

After randomization, patients returned at weeks 1–6, 8, 10, and 12 to complete the symptom rating scales conducted by trained raters blind to treatment assignment, self-reports, and a brief assessment by a study physician. Spanish-speaking raters and physicians also performed assessments at the English-speaking site in order to enhance treatment and assessment consistency. Patients received gift cards worth approximately $5.00 per visit to offset travel-related costs. Patients who did not achieve remission (defined below) at the end of week 12 were eligible to enter a 12-week combined treatment phase, in which combined psychotherapy and medication was provided; results of this phase of the study will be reported in a subsequent article.

Pharmacotherapy.

Study medications were compounded in the Emory Investigational Drug Service pharmacy and contained the equivalent of either 10 mg of escitalopram or 30 mg of duloxetine. Patients randomly assigned to medication were started on one capsule per day, and if the patient had not meaningfully improved by week 4, the dose was increased to two capsules once daily, though the treating psychiatrist could raise the dose at week 3 if deemed clinically necessary. If the response to treatment plateaued during the trial, or if remission was not achieved by week 6, an increase to two capsules per day was required. If adverse events were sufficiently distressing to the patient, the dose was reverted to one capsule per day. To assess adherence, serum concentrations of escitalopram and duloxetine were measured at week 12. The week-12 sample was also tested for the presence of 10 other antidepressants to ensure that patients were not surreptitiously using other antidepressants.

CBT.

Doctoral-level and experienced master's-level providers trained in the specific CBT protocol for the study provided the therapy utilizing a standardized treatment protocol (34). To complete the 16 visits during the 12 weeks of intervention, patients randomly assigned to CBT met with their therapist twice per week for the first 4 weeks and then weekly for the remaining 8 weeks, though some flexibility in the timing of visits was permitted when necessary. Therapist supervision occurred weekly, sessions were videotaped, and competency was rated, using the Cognitive Therapy Scale (35), by the Beck Institute for Cognitive Therapy and the Academy of Cognitive Therapy. Anytime a session score dropped below 40, the session was reviewed in weekly supervision with the therapist and additional training was undertaken to assure improvement and continued scores above 40.

Concomitant Medications

Medications used to manage acute chronic medical conditions were permitted. Patients were not permitted to use other psychoactive medications, with the exception of hypnotics, which were permitted up to three times per week when requested by patients.

Statistical Analysis

Baseline characteristics were compared across treatment groups using one-way analyses of variance for continuous variables and chi-square for categorical variables. For treatment outcomes, three analysis sets were defined. The primary analysis for this article was the change in HAM-D score, performed on the intent-to-treat population, defined as all randomly assigned patients. Change in HAM-D score over the course of treatment was modeled using a linear-mixed model, with time as a continuous predictor (growth curve model) and individual-level random effects for both intercept (initial depression severity) and slope (change in depression severity over time). The effects of interest were the treatment group-by-time interactions. Main and interaction effects of clinic (Spanish versus English language) were tested, as well as time, treatment group, and time-by-treatment group interactions. Similar models were developed to assess change in scores on the MADRS, BDI, Quick Inventory of Depressive Symptomatology, Self-Report, and HAM-A.
Secondarily, for the purpose of assessing categorical outcomes, we used a last observation carried forward data set, defined as all randomly assigned patients who initiated treatment and had at least one follow-up rating assessment. Four mutually exclusive categorical outcomes were defined based on the last valid HAM-D rating: 1) nonresponse: <30% reduction from baseline; 2) partial response: 30%−49% reduction from baseline; 3) response without remission: ≥50% reduction from baseline, but HAM-D score >7; and 4) remission: HAM-D score ≤7. For these outcomes, we tested for clinic-by-treatment group interactions.
Because the PReDICT study was designed to identify biomarkers predictive of treatment outcome, we also analyzed a per-protocol completer data set. This sample comprised randomly assigned patients who met all inclusion/exclusion criteria, had no major protocol violations, completed the 12 weeks of treatment, and whose week-12 pharmacokinetic measures did not contradict the randomized treatment assignment (i.e., patients assigned to medication who had no detectable drug, or those assigned to CBT who had a detectable antidepressant at week 12). Categorical outcomes in the per-protocol sample employed the same definitions as the last observation carried forward sample, with the exception that remission was defined as a HAM-D score ≤7 at both weeks 10 and 12 (the a priori definition specified in the protocol).
For testing predictors of remission and completion, we performed two sets of analyses for each outcome: a set with each measure as a predictor of remission (main effect) and another set testing each measure as a possible moderator of the remission effect (simultaneous main and interaction effects). All analyses were performed using logistic regression with a similar structure. However, the effects of preference and preference matching on remission were assessed using logistic regression with targeted coding of the baseline groups, reflecting the fact that both preference and preference matching were also treatment specific. To assess odds of remission in various preference groups, appropriate frequency weights were used to account for the fact that the probability of a match was not the same in the medication and CBT groups.

Results

The disposition of patients through the study is presented in Figure S1 in the data supplement accompanying the online version of this article. Five hundred fifteen individuals consented to participate in the trial, and 344 were randomly assigned: 114 to escitalopram, and 115 each to the CBT and duloxetine arms. Twenty-eight patients did not return for a postrandomization assessment, and thus the last observation carried forward data set comprised 316 patients; 234 met all criteria for inclusion in the per-protocol completer sample.

Demographic and Clinical Characteristics

Baseline clinical and demographic characteristics of the randomized sample are summarized in Table 1. Demographic characteristics did not differ between the treatment groups. The only clinical characteristic that significantly differed between the groups was age at onset, which was slightly younger in the duloxetine group. The mean HAM-D score indicated moderate severity (mean=19.8 [SD=3.8]), and more than half (52%) of the participants were in their first major depressive episode. Hispanic participants were more socio-economically disadvantaged than black or white participants, with lower levels of full-time employment and education, and were less likely to have private insurance.
TABLE 1. Clinical and Demographic Characteristics at Baseline
CharacteristicAll Patients (N=344)Cognitive-Behavioral Therapy Group (N=115)Escitalopram Group (N=114)Duloxetine Group (N=115)Analysis
 MeanSDMeanSDMeanSDMeanSDFdfp
Age (years)40.011.740.011.341.612.138.311.42.272, 3410.105
Age at first episode (years)30.714.231.813.532.815.227.513.44.592, 3360.011
Current episode duration (weeks)119.0232.7117.7232.3101.2153.9137.6290.3a 0.601
Measure           
 Hamilton Depression Rating Scale (17-item)19.83.819.73.720.13.719.63.90.5602, 3410.572
  Quick Inventory of Depressive Symptomatology, Self-Report14.04.013.94.014.13.914.04.20.1172, 3380.890
  Beck Depression Inventory22.97.322.27.523.17.223.47.30.8952, 3380.410
  Hamilton Anxiety Rating Scale16.15.216.24.916.75.415.45.21.8552, 3410.158
 N%N%N%N%χ2dfp
Sex        0.33220.847
 Male14843.05144.35043.94740.9   
 Female19657.06455.76456.16859.1   
Race        7.6440.106
 White16447.76153.04741.25648.7   
 Black6418.61311.32824.62320.0   
 Other11633.74135.73934.23631.3   
Ethnicity        0.38720.824
 Hispanic10229.73227.83631.63429.6   
 Non-Hispanic24270.38372.27868.48170.4   
Married/cohabitating        0.12120.941
 Yes16949.15749.65750.05547.8   
 No17550.95850.45750.06052.2   
Education level        2.09640.718
 ≤12 years or trade school10530.53732.23228.13631.3   
 Some college9627.92723.53429.83530.4   
 ≥4-year college degree14341.65144.34842.14438.3   
Employed full-time        0.65920.719
 Yes18554.16153.55951.86557.0   
 No15745.95346.55548.24943.0   
Current anxiety disorder        0.33720.845
 Yes20559.67161.76758.86758.3   
 No13940.44438.34741.24841.7   
Previous episodes        5.60340.231
 117752.26759.85952.75144.3   
 26318.61715.22017.92622.6   
 ≥39929.22825.03329.53833.0   
Chronic episode (≥2 years)10631.53833.93127.93732.51.0120.603
History of suicide attempt257.487.043.61311.45.1220.077
Insurance status        3.1240.538
 Private13741.64238.25045.54541.3   
 Public30.921.810.900   
 None18957.46660.05953.66458.7   
a
The chi-square value is 1.02, nonparametric test of medians.
Of the 344 randomly assigned patients, 21 (6.1%) had previously received an antidepressant medication of inadequate dose or duration to meet our definition of previous treatment. Seventy-eight (22.3%) reported receiving a non-evidence-based psychotherapeutic intervention or <4 sessions of an evidence-based psychotherapy for depression. Among patients having had prior psychotherapy, 43.8% (32/73) remitted compared with 48.9% (119/243) of those who had not (χ2=0.593, df=1, p=0.441). Remission rates also did not significantly differ between patients with (5/20, 25%) and without (146/296, 49.3%) prior antidepressant exposure (χ2=3.52, df=1, p=0.061). Similarly, treatment completion was unrelated to prior psychotherapy (p=0.98) or antidepressant exposure (p=0.107).

Treatment Features

The mean number of CBT sessions attended was 11.4 (SD=4.7) for the intent-to-treat sample and 14.3 (SD=1.4) for the completer sample. Sessions 2, 8, and 12 were rated for slightly over 35% of the CBT patients. The average Cognitive Therapy Scale scores were above 40 for all therapists except two whose average was just slightly below 40. Of the nine scheduled pharmacotherapy visits for medication-treated patients, the mean number of visits attended was 8.2 (SD=2.0) for the medication-treated intent-to-treat sample and 8.9 (SD=0.4) for the completer sample. The mean escitalopram dose at endpoint was 16.2 mg/day (SD=5.1), and 16.9 mg/day (SD=4.5) at week 12 for completers. The mean duloxetine dose at endpoint was 48.0 mg/day (SD=15.0), and 49.6 mg/day (SD=14.1) for completers. Among the drug-treated completers, 80% receiving escitalopram were titrated to 20 mg/day, and 71% of duloxetine-treated patients were titrated to 60 mg/day at some point during the 12 weeks. The mean serum drug concentrations at endpoint were 30.9 ng/ml (SD=19.7) for escitalopram and 44.6 ng/ml (SD=59.1) for duloxetine. Sedative medications were used by 22.4% of the CBT and duloxetine groups and by 25.4% of the escitalopram group; these counts did not significantly differ (χ2=0.48, p=0.79).

Per-Protocol Completion Rates

Patients randomly assigned to CBT were less likely to be per-protocol completers than patients in either of the medication groups (CBT: 60.0%; escitalopram: 75.4%; duloxetine: 68.7%, χ2=6.31, df=2, p=0.043). Per-protocol completers, compared with noncompleters, had lower depression severity (HAM-D: mean=19.2 [SD=3.5] compared with mean=21.1 [SD=4.0]) and lower anxiety (HAM-A: mean=15.4 [SD=4.7] compared with mean=17.4 [SD=5.9]) at baseline.

Outcomes

There were no significant clinic-by-treatment group interactions on HAM-D, and thus clinic effects were removed from the presented models. The mean estimated overall improvement on the primary outcome of the HAM-D was 10.9 points for the intent-to-treat sample, which did not differ significantly across the three groups (CBT: 10.2; escitalopram: 11.1; duloxetine: 11.2; F=0.53, df=2, 257, p=0.589). Among completers, the mean reduction in HAM-D score was 10.5, which also did not significantly differ between the CBT (mean=9.8), escitalopram (mean=11.1), and duloxetine (mean=10.7) groups (F=0.88, df=2, 231, p=0.415). The raw data means over time for the three treatment arms are shown in Figure 1; there was no significant time-by-treatment interaction, indicating the change over time did not differ across treatments. The rates of remission and response by treatment group are summarized in Table 2 and Table 3. Among the last observation carried forward sample, 47.8% remitted and an additional 12.3% achieved response without remission. Among completers, 46.6% remitted and another 21.4% achieved response without remission. Remission rates did not significantly differ between treatment arms in either the last observation carried forward (CBT: 41.9%; escitalopram: 46.7%; duloxetine: 54.7%; χ2=3.55, df=2, p=0.170) or per-protocol (CBT: 43.5%; escitalopram: 44.2%; duloxetine: 51.9%; χ2=1.36, df=2, p=0.507) samples.
FIGURE 1. Modeled Change in the Mean Hamilton Depression Rating Scale (HAM-D) Score by Weeka
a CBT=cognitive-behavioral therapy; Error bars represent 95% confidence intervals.
TABLE 2. Response and Remission Rates in the Intent-to-Treat Last Observation Carried Forward Sample
 Cognitive-Behavioral Therapy (N=105)Escitalopram (N=105)Duloxetine (N=106)Total Sample (N=316)
OutcomeN%N%N%N%
Non-responsea3230.52624.82119.87925.0
Partial responseb1918.11211.41615.14714.9
Response without remissionc109.51817.11110.43912.3
Remissiond4441.94946.75854.715147.8
a
Endpoint Hamilton Depression Rating Scale (HAM-D) score <30% improved from baseline.
b
Endpoint HAM-D score 30%–49% improved from baseline.
c
Endpoint HAM-D score ≥50% reduction from baseline, without meeting remission criteria.
d
HAM-D score ≤7 at both week 10 and week 12 visits (or final two ratings visits for noncompleters in the last observation carried forward sample).
TABLE 3. Response and Remission Rates in the Per-Protocol Completer Sample
 Cognitive-Behavioral Therapy (N=69)Escitalopram (N=86)Duloxetine (N=79)All Completers (N=234)
OutcomeN%N%N%N%
Non-responsea1521.71517.41012.74017.2
Partial responseb1318.81011.61215.23515.0
Response without remissionc1115.92326.71620.35021.4
Remissiond3043.53844.24151.910946.6
a
Endpoint Hamilton Depression Rating Scale (HAM-D) score <30% improved from baseline.
b
Endpoint HAM-D score 30%–49% improved from baseline.
c
Endpoint HAM-D score ≥50% reduction from baseline, without meeting remission criteria.
d
HAM-D score ≤7 at both week 10 and week 12 visits.
The modeled outcomes for each of the four depression scales and for the HAM-A are presented in Table S1 in the online data supplement. The primary result of no significant difference between the treatment groups in mean change on the HAM-D was replicated for the MADRS, Quick Inventory of Depressive Symptomatology, Self-Report, and BDI. Mean change on the HAM-A also did not significantly differ between the treatment arms.

Effect of Preferences on Outcomes

Preference data were obtained for 341 (99.1%) of the patients, of whom 225 (66%) expressed a treatment preference (CBT: N=121 [35.5%]; medication: N=104 [30.5%]). The 28 patients who did not return after randomization did not significantly differ from the rest of the sample in their expressed treatment preferences and were excluded from the outcome analyses.
Treatment preferences did not differ between patients with and without private insurance (Pearson χ2=0.254, p=0.88), but white non-Hispanic, black non-Hispanic, and Hispanic patients did significantly differ in their treatment preferences. In contrast to white non-Hispanic patients, who showed roughly equal distribution across the no-, CBT-, and medication-preference options, nearly one-half (47.5%) of black non-Hispanic patients preferred CBT, and few (19.8%) Hispanics preferred medication (Figure 2). The preference differences across the groups was statistically significant (χ2=17.16, df=4, p=0.002). The numbers of patients matched versus mismatched within each level of preference strength were as follows: mild: N=26 compared with N=24; moderate: N=54 compared with N=53; very strong: N=26 compared with N=40, respectively. Strength of preference did not differ between those preferring CBT compared with those preferring medication (Z=−1.74, p=0.08).
FIGURE 2. Treatment Preferences by Race and Ethnicitya
a CBT=cognitive-behavioral therapy.
Preferred treatment type did not significantly predict completion across the medication-, CBT-, and no-preference groups (completion rates: 77.9%, 71.9%, and 69.8%, respectively; χ2=1.93, df=2, p=0.38). However, among those expressing a preference, the completion rate was significantly higher among those matched compared with those mismatched to their preferred treatment (82.2% compared with 67.8%, respectively, χ2=6.19, df=1, p=0.013). This differential completion rate among matched and mismatched patients was driven by those with moderate or very strong preferences (mild: χ2=0.42, p=0.517; moderate: χ2=4.24, p=0.039; very strong: χ2=3.13, p=0.077) (Figure 3). There was also a main effect of baseline HAM-D severity on completion rates (greater severity among those less likely to complete: p=0.016), but this effect did not significantly differ between those matched compared with those mismatched to their preferred treatment (interaction effect: p=0.154).
FIGURE 3. Completion and Remission Rates by Preference Strength Among Patients Matched or Mismatched to Their Preferred Treatmenta
a Completion rates are based on all randomly assigned patients; remission rates are based on the last observation carried forward sample. A) Completion rates were significantly lower overall among mismatched compared with matched patients. B) Matched and mismatched patients did not significantly differ in overall remission rates (see the article text). No preference: N=88; mild preference: N=50; moderate preference: N=107; very strong preference: N=66.
Of the 225 patients expressing a preference, 107 (47.6%) were matched to their preferred treatment, and 118 (52.4%) were mismatched. Last observation carried forward outcomes were available for 207 of the 225 patients who expressed a preference. Having any preference was associated with a non-significantly lower likelihood of remission on the HAM-D (odds ratio=0.74, p=0.31), which was similar among those preferring CBT (odds ratio=0.72) or medication (odds ratio=0.76) (Table 4). Being randomly assigned to the preferred treatment did not significantly increase the overall remission rate (odds ratio=1.42, p=0.31) or the remission rate specific to CBT or medication (Table 4 [also see Table S2 in the online data supplement]). Strength of preference also did not significantly affect remission rates (mild: 56.3%; moderate: 41%; very strong: 45.6%, χ2=3.04, df=2, p=0.22). As shown in Figure 3, remission rates among matched and mismatched patients did not significantly differ by strength of preference (mild: χ2=2.93, p=0.09; moderate: χ2=0.077, p=0.78; very strong: χ2=0.102, p=0.24).
TABLE 4. Last Observation Carried Forward Remission Odds Ratios by Treatment Preference and Matching to Preference
 Treatment Preference (N=313)aPreference Matching (N=207)b
 Preference for Cognitive-Behavioral Therapy (N=112)Preference for Medication (N=95)Any Preference (N=207)Matched to Cognitive-Behavioral Therapy (N=38)Matched to Medication (N=65)Matched to Preference (N=103)
Outcome/MeasureOdds Ratio95% CIpOdds Ratio95% CIpOdds Ratio95% CIpOdds Ratio95% CIpOdds Ratio95% CIpOdds Ratio95% CIp
Hamilton Depression Rating Scale (17-item)0.720.36–1.420.340.760.40–1.460.420.740.42–1.320.311.240.55–2.770.601.680.72–3.900.231.420.72–2.800.31
Beck Depression Inventory0.920.46–1.860.821.030.53–2.020.930.980.54–1.770.941.510.66–3.460.331.910.78–4.670.161.680.84–3.360.14
a
Odds ratio for treatment preference represents the odds of remission with “no preference” (N=106) as the baseline rate (odds ratio=1).
b
Odds ratio for preference matching is the odds of remission with “mismatched to preference” (N=104) as the baseline rate (odds ratio=1); all odds ratios for remission are calculated from weighted data accounting for the 2:1 medication to the cognitive-behavioral therapy allocation ratio.

Other Clinical Predictors of Outcomes

The logistic regression analyses of other clinical and sociodemographic variables found that baseline depression severity (HAM-D), baseline anxiety (HAM-A), and presence of a current anxiety disorder all predicted lower likelihood of remission in both the completer and last observation carried forward samples, but age, gender, race, chronicity, employment, marital status, and chronicity of episode did not (see Tables S3 and S4 in the online data supplement). Completion rates were also predicted by baseline depression and anxiety severity, with the additional finding that minority race/ethnicity patients were significantly less likely to complete the study than white patients (African American: 65.6%; Hispanic: 66.7%; Caucasian: 82.1%) (see Table S5 in the online data supplement). None of these analyses identified a statistically significant moderator of remission or completion between the three treatment groups.

Discussion

This study represents the largest randomized clinical trial, to our knowledge, conducted at a single institution in patients with major depressive disorder. Furthermore, none of the patients had ever previously received a minimally adequate course of an evidence-based treatment. Among the 344 randomly assigned patients, the average benefit from 12 weeks of treatment with CBT, escitalopram, or duloxetine did not meaningfully differ in terms of mean change in symptom severity or proportion of patients achieving remission. These results are consistent with other studies of depression that have reported roughly equivalent mean outcomes with evidence-based psychotherapy and medication treatments (3640).
We found that patients matched to their preferred treatment did not achieve remission significantly more frequently than mismatched patients. This absence of difference in remission occurred despite a significantly higher rate of treatment completion among the matched patients. These results replicate a similarly designed randomized trial that compared escitalopram and CBT among previously treated patients (22). The results of these two trials, considered along with similar results from other large trials (16, 37, 38, 4144), suggest that overall remission rates are roughly equivalent regardless of preference matching, even if dropout is greater among mismatched patients. However, retention itself is an important outcome of relevance, particularly for patients with chronic forms of depression. We found a clinically meaningful number needed to treat for increasing completion (6.94 for matched compared with mismatched patients). Thus, until better predictors of remission probability are identified (as reported in our companion study to the present article [see reference 45]), there may be value in using patient preferences to select initial treatments, particularly for those with moderate or strong preferences.
Consistent with other reports, we found that Hispanic and black non-Hispanic patients had treatment preferences that differed from white non-Hispanic patients (14, 15). Specifically, black patients were significantly more likely to prefer psychotherapy, and few Hispanic patients preferred medication.
The impact of matching to preference on the outcome of attrition is less clear. Consistent with prior work (44), we found that patients were more likely to complete the trial if they were matched to their treatment preference, though others have not found this effect (42, 4648). Previous findings (25, 49) that preference for medication treatment (regardless of treatment received) predicted attrition were not replicated in the current analysis. The inconsistent results across studies may derive from differences in socioeconomic status or prior treatment experiences of the samples enrolled.
Other investigators have reported that preferences may affect indirect measures of outcome, such as treatment engagement (50), adherence (43), and working alliance. Of these, only the association between preference and strength of therapeutic alliance has been replicated across studies (44, 50, 51). These results suggest that patients who receive their preferred treatment may invest more fully in their treatment, which makes the finding that preference does not affect improvement all the more striking. This discrepancy implies that biological or psychosocial factors are stronger determinants of treatment efficacy than patient preference.
Strengths of the study include the large number of randomly assigned patients within a single institution, thereby minimizing confounding arising from potentially differing applications of treatments across study sites (52). The generalizability to the broader population of major depression patients would appear to be strong, given the diverse racial and ethnic composition of our sample. Because the PReDICT study enrolled treatment-naive patients, preferences were not influenced by prior treatment experiences, though this may limit generalization to patients with prior treatment experiences. The CBT treatment was delivered with high fidelity; however, dissemination may be hampered by the limited availability and quality of systematic CBT in community settings (53). The completion rate in the CBT arm (60%) was on the lower end of the range of psychotherapy arm completion rates from other large medication versus psychotherapy trials (55%−87%) (3640). The completion rate across the two medication arms was 72%, similar to the rates observed in other trials (56%−89%) (3640).
A potential limitation is that the maximum dose of duloxetine used was 60 mg/day; higher doses are often used in clinical practice, which suggests that the full efficacy of duloxetine may not have been detected. Another limitation, which is unavoidable in psychotherapy versus medication trials, is that patients were not blind to their treatment assignment and that CBT patients had substantially greater contact with the treatment providers. The majority of the randomly assigned patients were recruited through advertising, which may limit generalizability to spontaneously treatment-seeking samples. Other limitations to generalizability include the exclusion of patients with mild depressive symptoms or concomitant substance use disorders and those with very strong treatment preferences who were unwilling to be randomly assigned. Because many patients expressed no treatment preference, our analyses of the impact of preference on outcomes were underpowered, and larger samples might have detected statistically significant effects. Without a “patient’s choice” treatment arm, we could not address whether receiving one’s preferred treatment by choice, rather than by chance via randomization, would have led to improved outcomes. Assessing patients prior to randomization about their ambivalence toward continuing in treatment, particularly if they experienced side effects or minimal early improvement, may have informed the treatment discontinuation analyses (54).
There are two important implications of our results that can inform treatment guidelines. First, guideline recommendations that psychotherapy or antidepressant medications are equally appropriate for the initial treatment of major depression can be extended to treatment-naive patients. Second, because ethnic minorities comprised more than one-half of our study’s population, these treatment recommendations can be extended with confidence beyond the white non-Hispanic population, who comprised the majority of all prior randomized treatment studies comparing pharmacotherapy with psychotherapy.
In contrast to the finding that no clinical or socio-demographic variables significantly moderated differential remission rates in the PReDICT study, our neuroimaging data have proven to have predictive value. In the companion study to this article, we report that resting-state functional connectivity predicted remission and nonresponse rates with roughly 80% accuracy (45). This finding is consistent with our prior PET study that also found anterior insula metabolism to predict symptomatic outcomes among CBT- and SSRI-treated patients (11, 12). Other biological assessments examined to date in the PReDICT data set have not proven to serve as moderators of outcomes. Pharmacokinetic analyses and an ex-vivo assay measuring the degree of inhibition of the serotonin and norepinephrine transporters were not predictive of outcomes among the medication-treated patients (55). We also found that hypothalamic-pituitary-adrenal axis sensitivity, as measured by the dexamethasone-corticotropin-releasing hormone test, did not moderate remission outcomes (56). Given the poor replication of demographic and clinical moderators of outcomes to medication compared with psychotherapy treatments, the advancement of precision medicine for major depressive disorder hinges on the identification and refinement of biological markers.

Acknowledgments

The authors thank Flavia Mercado, M.D., for her assistance in operationalizing the study at the Grady Hospital location. The authors also thank Leslie Sokol, Ph.D., and Jesus Salas, Ph.D., for performing the Cognitive Therapy Scale competency ratings.

Footnotes

PReDICT Team: Treating Psychotherapists: Carla Alvarez, Ph.D., Julie Etzel, Ph.D., Rosario Falero, M.D., Ph.D., Maryrose Gerardi, Ph.D., Mary Heekin, LCSW, Meredith Jones, M.A., Noriel Lim, Ph.D., Vivianna Mahoney, Ph.D., Cynthia Ramirez, Ph.D., Sheethal Reddy, Ph.D., Lorie Ritschel, Ph.D., Jill Rosenberg, LCSW, Diana Simeonova, Ph.D., Patrick Sylvers, M.A., and Alexandra Zagoloff, Ph.D. Therapy supervisors: WEC and Linda Wilcoxon Craighead, Ph.D. Treating Physicians: BWD, Nicole Almeida, M.D., VAR, Corey Beck, M.D., Steve Garlow, M.D., Ph.D., Ebrahim Haroon, M.D., Maryann Jacob, M.D., Jeffrey Rakofsky, M.D., Dylan Wint, M.D. Clinical Coordinators: Yara Betancourt, Beatriz Blastos, Ronald Chismar, R.N., Melanie Galanti, Rachelle Gibson, R.N., Lauren Marx, Melissa McKenzie, and Tanja Mletzko Crowe.
Supported by NIH grants P50 MH077083; RO1 MH080880; UL1 RR025008; M01 RR0039; and K23 MH086690. Forest Laboratories and Elli Lilly donated the study medications, escitalopram and duloxetine, respectively, and were otherwise uninvolved in the study design, data collection, data analysis, or interpretation of findings.
Clinicaltrials.gov Identifier: NCT00360399

Supplementary Material

File (appi.ajp.2016.16050517.ds001.pdf)

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Information & Authors

Information

Published In

Go to American Journal of Psychiatry
Go to American Journal of Psychiatry
American Journal of Psychiatry
Pages: 546 - 556
PubMed: 28335624

History

Received: 5 May 2016
Revision received: 11 October 2016
Revision received: 15 November 2016
Accepted: 21 November 2016
Published online: 24 March 2017
Published in print: June 01, 2017

Keywords

  1. Mood Disorders-Unipolar
  2. Outcome Studies
  3. Cognitive Therapy
  4. Antidepressants

Authors

Details

Boadie W. Dunlop, M.D. [email protected]
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
Mary E. Kelley, Ph.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
Vivianne Aponte-Rivera, M.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
Tanja Mletzko-Crowe, M.A.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
Becky Kinkead, Ph.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
James C. Ritchie, Ph.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
Charles B. Nemeroff, M.D., Ph.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
W. Edward Craighead, Ph.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
Helen S. Mayberg, M.D.
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.
for the PReDICT Team
From the Department of Psychiatry and Behavioral Sciences, Emory University School of Medicine, Atlanta; the Department of Biostatistics and Bioinformatics, Rollins School of Public Health, Emory University, Atlanta; the Department of Psychiatry and Behavioral Sciences, Tulane University School of Medicine, New Orleans; the Department of Clinical Pathology, Emory University School of Medicine, Atlanta; the Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami; the Department of Psychology, Emory University, Atlanta; and the Department of Radiology and Imaging Sciences, Emory University School of Medicine, Atlanta.

Notes

Address correspondence to Dr. Dunlop ([email protected]).

Author Contributions

Drs. Craighead and Mayberg contributed equally to this study.

Funding Information

National Institute of Mental Health10.13039/100000025: K23 MH086690, P50 MH077083, RO1 MH080880
National Center for Research Resources10.13039/100000097: M01 RR0039, UL1 RR025008
Dr. Dunlop has received research support from Assurex, Bristol-Myers Squibb, Forest, Janssen, GlaxoSmithKline, NIMH, Otsuka, Pfizer, and Takeda; and he has served as a consultant to Pfizer and Medavante. Dr. Ritchie has received research support from NCI and NIMH; and he has conducted research and development contracts for Beckman Coulter, Bio Rad, T2 Biosystems, Roche Diagnostics, Sebia, and Waters, Inc. Dr. Nemeroff has received research support from NIH; he has served as a consultant to Allergan, Clintara/Bracket, Lilly, Lundbeck, Mitsubishi Tanaba Pharma Development America, Prismic Pharmaceuticals, SK Pharma, Sunovion, Taisho Pharmaceutical, Inc., Takeda, Total Pain Solutions, and Xhale; he has served on the scientific advisory boards of the American Foundation for Suicide Prevention, Anxiety Disorders Association of America, Brain and Behavior Research Foundation, Clintara/Bracket, Laureate Institute for Brain Research, RiverMend Health, LLC, Skyland Trail, and Xhale; he has served on the board of directors for ADAA, AFSP, and Gratitude America; he is a shareholder with Abbvie, Celgene, Seattle Genetics, Titan Pharmaceuticals, and Xhale; he has received income sources or equity of $10,000 or more from American Psychiatric Association Publishing, Clintara/Bracket, and Xhale; and he holds a patent on the method and devices for transdermal delivery of lithium (U.S. 6,375,990 B1) and the method of assessing antidepressant drug therapy via transport inhibition of monoamine neurotransmitters by ex vivo assay (U.S. 7,148,027B2). Dr. Craighead is a board member of Hugarheill EHF; he receives royalties from John Wiley and Sons; he is a consultant to the George West Mental Health Foundation; he is a member of the Scientific Advisory Board of ADAA; and he receives research support from the Mary and John Brock Foundation and the Fuqua family foundations. Dr. Mayberg has received consulting fees from Eli Lilly and St. Jude Medical Neuromodulation; and she has received intellectual property licensing fees from St. Jude Medical Neuromodulation. All other authors report no financial relationships with commercial interests.

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