Selective serotonin reuptake inhibitors (SSRIs) are typically the first-line pharmacological options for major depressive disorder (MDD), but their benefits can be initially modest. Reference Fava, Rush, Trivedi, Nierenberg, Thase and Sackeim1–Reference Cipriani, Furukawa, Salanti, Chaimani, Atkinson and Ogawa4 An early treatment modification seems crucial since the failure or success of a second-attempt treatment is strongly related to long-term outcomes. Reference Macqueen, Santaguida, Keshavarz, Jaworska, Levine and Beyene5 Clinical guidelines suggest various strategies after an initial inadequate response to SSRIs, that is, dose optimisation, switching to another antidepressant (preferably to a different pharmacological class), augmentation with a non-antidepressant agent (such as lithium), combination with another antidepressant with a complementary mechanism of action (such as nortriptyline) or adding psychotherapy. Reference Macqueen, Santaguida, Keshavarz, Jaworska, Levine and Beyene5–Reference Malhi, Bell, Bassett, Boyce, Bryant and Hopwood7 Although controversial, Reference Jakubovski, Varigonda, Freemantle, Taylor and Bloch8,Reference Furukawa, Cipriani, Cowen, Leucht, Egger and Salanti9 SSRI dose optimisation is still one of the preferred initial steps in clinical practice. Reference Gauthier, Guérin, Zhdanava, Jacobson, Nomikos and Merikle10 Randomised clinical trials have examined the efficacy of many of these strategies with varied results, but virtually none have compared them simultaneously. The most extensive study to investigate the efficacy of different treatment approaches is the STAR*D, which enrolled more than 1200 patients with MDD who eventually failed to respond to the initial SSRI. Reference Rush, Trivedi, Wisniewski, Nierenberg, Stewart and Warden11,Reference Castle, Schweitzer and Tiller12 Patients were then assigned to various switching, combination or augmentation strategies in parallel and sequential steps using an equipoise-stratified randomisation design that considered the patient’s preferences, with no control arm and self-rated measures as primary outcomes. Despite its significant contributions, several methodological aspects have been criticised. Reference Castle, Schweitzer and Tiller12,Reference Pigott13 In this pragmatic, assessor-blinded, randomised trial (the DEPRE’5 study), we evaluated the most effective strategy for patients with MDD who had an inadequate response to the initial SSRI, a critical clinical point. We compared SSRI dose optimisation (control arm) with SSRIs plus lithium augmentation, SSRIs plus nortriptyline, switching to venlafaxine and SSRIs plus focused problem-solving psychotherapy. We aimed to address two questions: (a) is SSRI dose optimisation a worthless second-line strategy after a failed SSRI? (b) Is any particular second-line strategy more effective than dose optimisation?
Method
Trial design
This study adhered to the Consolidated Standards of Reporting Trials (CONSORT; Fig. 1) guidelines. Reference Juszczak, Altman, Hopewell and Schulz14 A five-arm, multicentre, parallel, pragmatic, assessor-blinded, randomised clinical trial for patients with MDD and an insufficient response to SSRIs was designed and conducted at specialised mental health services in ten Spanish hospitals between 2008 and 2012 (the first participant’s first visit was on 16 October 2008).
Fig. 1 Flow diagram for study participants. SSRI, serotonin reuptake inhibitor; Opt, dose optimisation; Li, lithium; NTP, nortriptyline; PST, problem-solving therapy; VEN, venlafaxine; ITT, intention to treat.
The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2013. All procedures involving human participants/patients were approved by the Ethical Committee of each site, and written informed consent was obtained before any study procedure (EudraCT registration; 2007-002130-11: https://www.clinicaltrialsregister.eu/ctr-search/trial/2007-002130-11/ES).
Participants
Participants from both genders, aged between 18 and 75 years and receiving in-patient or out-patient treatment, were eligible providing that they (a) met the criteria for MDD (DSM-IV-TR criteria), 15 (b) presented an insufficient response to appropriate doses of a SSRI after a minimum of 6 weeks, having a score ≥14 on the 17-item Hamilton Depression Rating Scale (HDRS-17), Reference Hamilton16 (c) were using an accepted contraception method (if women of childbearing potential) and (d) were capable of giving consent.
Exclusion was determined by (a) pregnancy or breastfeeding, (b) HDRS-17 suicide-item score ≥3, (c) severe organic disease, (d) delusions or hallucinations, (e) currently meeting criteria for substance and alcohol misuse or dependence, (f) use of any psychopharmacological agents, other than prescribed benzodiazepines and SSRIs, (g) structured psychotherapeutic treatment and (h) patients with a history of non-response, side-effects or contraindications for any of the study drugs.
Randomisation and blinding
Patients were randomised to one of five groups: (a) SSRI dose optimisation (SSRI-Opt), (b) lithium augmentation (SSRI + Li), (c) SSRI + nortriptyline (SSRI + NTP), (d) switch to venlafaxine (VEN) or (e) SSRI + problem-solving therapy (SSRI + PST). Randomisation was performed by a contract research organisation (CRO). A single randomisation list was obtained using the SAS Software (v.9.1.3; SAS Institute Inc., Cary, NC, USA). Assessments were at baseline and weeks 1, 2, 4 and 6 post-randomisation. Outcome assessors were blinded to group allocation. The allocation ratio was 1:1:1:1:1. One of 20 lists generated to ensure blinding was selected for the study.
Treatment arms
SSRI-Opt: The SSRI dose was increased up to the maximum dose approved by the European Medicines Agency (EMA): 60 mg/day for fluoxetine, 50 mg/day for paroxetine, 200 mg/day for sertraline, 60 mg/day for citalopram, 20 mg/day for escitalopram and 300 mg/day for fluvoxamine. Higher doses were allowed if deemed necessary and well tolerated.
SSRI + Li: Lithium was started at 400 mg daily. Psychiatrists were encouraged to modify the dose (during weeks 1 and 2) to achieve therapeutic levels between 0.5 and 0.8 mmol/l.
SSRI + NTP: The starting dose of nortriptyline was 25 mg daily, which increased to 50–75 mg during weeks 1 and 2 and remained stable.
VEN: The starting dose of extended-release venlafaxine was 75 mg daily, increasing to 150 mg per day during week 1 and reaching a final maximum dose of 225–300 mg/day. Simultaneously, the SSRI dose was gradually tapered down during week 1.
SSRI + PST: This protocol consisted of structured 30-min psychotherapy sessions over 6 weeks. A detailed manual was prepared to guarantee protocol adherence. Two random sessions per therapist were videotaped and supervised.
Flexible dosing was allowed based on clinical judgement to reflect routine clinical practice better. If benzodiazepines were present, their doses remained constant during the study. In those groups where SSRIs were maintained, doses remained constant.
Outcome and measures
Primary outcomes were response (≥50% decrease from baseline in HDRS-17 score) and remission (HDRS-17 score <8) rates at the end-point (week 6). Secondary outcomes were changes in HDRS-17 scores from baseline and the Clinical Global Impression-Improvement (CGI-I) scale. Reference Busner and Targum17
Medication adherence was assessed at each visit by pill count for lithium, nortriptyline and venlafaxine and by verbal report for SSRIs. Lithium plasma levels were obtained at weeks two and six and as needed. Safety assessments included vital signs, physical examination, weight and height, blood tests and pregnancy tests at baseline and study end. Adverse events were monitored throughout the study and coded using the Medical Dictionary for Regulatory Activities (MedDRA) system (v.15.1).
Sample size estimation
Previous studies Reference Rush, Trivedi, Wisniewski, Nierenberg, Stewart and Warden3,Reference Tadić, Wachtlin, Berger, Braus, van Calker and Dahmen18 indicate that approximately 20% of patients who show no response to first-line SSRIs achieve remission rates after a second-line treatment. Based on 80% power to detect 23% of differences between control (SSRI-Opt) and each of the other groups, a bilateral significance level of 0.05 and assuming an attrition rate of 10%, the required sample was 99 participants per group (495 in total). A slower-than-expected recruitment rate in some sites led to the study’s premature termination, not achieving the targeted sample size.
Statistical analysis
Baseline characteristics were compared using the chi-squared test, Fisher’s exact test or one-way analysis of variance (ANOVA) as needed. We first assessed SSRI dose optimisation against all other second-line strategies. Then, we compared efficacy and safety outcomes between SSRI-Opt and each individual second-line strategy. Fisher’s exact test evaluated primary outcomes, safety and adherence to treatment. Results were expressed as odds ratios and absolute risk differences with 95% confidence intervals. Mixed models for repeated measures (MMRMs) were used for secondary outcomes, using rank transformation for ordinal variables. Subject and error were random effects, and treatment group, visit and treatment-group-by-visit interaction fixed effects, and baseline values were entered as covariates. The within-patient variance–covariance matrix was assumed to be unstructured. Treatment effects were estimated using least square means (LSM) and a 95% confidence interval.
Baseline characteristics and primary outcomes were analysed on the intention-to-treat (ITT) population, which included all randomised subjects with baseline efficacy data and at least one post-baseline efficacy measurement. The safety analysis included all randomised subjects. Missing data for primary variables were treated using the last observation carried forward (LOCF). Basal-observation-carried-forward (BOCF) and available-data-only (ADO) approaches were used for sensitivity analyses.
Results
Participants’ baseline characteristics
A total of 257 participants were randomised (245 included in the ITT set and 254 in the safety set): 51 were allocated to SSRI-Opt, 46 to SSRI + Li, 48 to SSRI + NTP, 55 to VEN and 57 to SSRI + PST (Fig. 1). Demographic and clinical baseline characteristics did not differ among groups (Table 1).
Table 1 Demographic and baseline clinical features
SSRI, serotonin reuptake inhibitor; Opt, dose optimisation; Li, lithium; NTP, nortriptyline; PST, problem-solving therapy; VEN, venlafaxine.
Missing data in certain features may change the percentage calculation denominator, affecting comparisons with the total count.
Before randomisation, 30% were on escitalopram, 20.8% on fluoxetine, 22% on paroxetine, 20% on citalopram, 6.8% on sertraline and 0.4% on fluvoxamine. Mean daily doses of SSRIs (as fluoxetine equivalents) increased from 33.2 to 55 mg for the SSRI-Opt group and remained constant for the other groups: 31.7mg for SSRI + Li, 34.6 mg for SSRI + NTP and 30.7 mg for SSRI + PST (see Supplementary Tables S1 and S2). At the study’s end, mean daily doses were 493.8 mg lithium (mean plasma level 0.54 mM), 51.3 mg nortriptyline and 151.4 mg VEN (75.9% received at least 150 mg, 22.2% received higher doses).
Medication adherence differed significantly among groups (p < 0.001): participants in the SSRI + Li group had the lowest adherence (38.6%) compared to the others (98.2% in SSRI + PST, 96.4% in VEN, 72% in SSRI-Opt and 68.8% in SSRI + NTP). Note that any deviation from the prescribed regimen in at least two visits was considered low adherence. Participants attended an average of 7.1 PST sessions (s.d. = 1.9), and 89.5% completed the intervention. Thirty-three patients (13.5% of the ITT sample) withdrew without significant group differences. The main reasons included lack of efficacy (SSRI, SSRI + PST), adverse events (SSRI + Li, SSRI + NTP) and patient choice (VEN).
SSRI dose optimisation versus second-line strategies
Patients receiving second-line treatments (SSRI + Li, SSRI + NTP, VEN or SSRI + PST) had higher response rates (28.2%) than those on SSRI-Opt (14.3%, odds ratio = 2.36, 95% CI = 1.0–5.6; p = 0.05; Fig. 2(a)). Dose optimisation significantly reduced the likelihood of response by 13.9% (95% CI = 12.6, 25.6; p = 0.0193). The alternative strategies had a higher remission rate (16.9%) compared to the SSRI-Opt group (12.2%), but the difference was not significant (odds ratio = 1.46, 95% CI = 0.57–3.71; p = 0.27).
Fig. 2 Response/remission rates at week 6 and mean Hamilton Depression Rating Scale (HDRS) score change from baseline. SSRI, serotonin reuptake inhibitor; Opt, dose optimisation; Li, lithium; NTP, nortriptyline; PST, problem-solving therapy; VEN, venlafaxine; ITT, intention to treat; MMRM, mixed model for repeated measures.
MMRM analysis revealed a treatment-by-assessment point effect (p = 0.023), showing a significant difference in the mean HDRS-17 change from baseline between patients who received an alternative second-line strategy and those on SSRI dose optimisation alone (HDRS-17 reduction difference = −2.6, 95% CI = −4.9 to −0.4; p = 0.021; Fig. 2(b)). Alternative second-line strategies were associated with more significant improvements in CGI-I scores: 49.2% showed ‘much improvement’ compared to 30.6% in the SSRI group (odds ratio = 2.20, 95% CI = 1.12, 4.29; p = 0.02).
SSRI dose optimisation versus specific second-line strategies
There were no significant differences in response and remission rates when comparing the SSRI group with any other second-line therapeutic strategy (Fig. 2(c)). The likelihood of response was twice for each of the four second-line strategies compared to SSRI alone. However, differences only reach a marginally significant effect for the VEN and SSRI + PST groups: SSRI + Li versus SSRI, odds ratio = 2.00 (95% CI = 0.68, 5.85; p = 0.206); SSRI + NTP versus SSRI, odds ratio = 2.36 (95% CI = 0.85, 6.59; p = 0.100); VEN versus SSRI, odds ratio = 2.53 (95% CI = 0.94, 6.80; p = 0.067); SSRI + PST versus SSRI, odds ratio = 2.46 (95% CI = 0.92, 6.62; p = 0.074; Fig. 2(d)).
A significant reduction in total HDRS-17 scores was found for the SSRI + PST group compared to the SSRI-Opt group (−3.1, 95% CI = −5.8, −0.3; p = 0.032). Marginally significant reductions were also observed for the VEN (−2.7, 95% CI = −5.5, 0.0; p = 0.054) and SSRI + Li groups (−2.6, 95% CI = −5.6, 0.4, p = 0.086). Sensitivity analyses using MMRMs with the BOCF and ADO approaches revealed significant differences favouring SSRI + PST (p = 0.028 and p = 0.032, respectively), VEN (p = 0.033 and p = 0.016, respectively) and SSRI + Li (p = 0.066 and p = 0.027, respectively).
The number of patients achieving ‘much improvement’ or better rating on the CGI-I scale at the study end was significantly higher in the SSRI + NTP group (51.1%; odds ratio = 2.37, 95% CI = 1.02, 5.51; p = 0.04) and in the VEN group (50.9%; odds ratio = 2.35, 95% CI = 1.05, 5.30; p = 0.04) compared to the SSRI-Opt group (30.6%). Participants receiving SSRI + PST (47.3%; odds ratio = 2.03, 95% CI = 0.91, 4.55; p = 0.08) and SSRI + Li (47.5%; odds ratio = 2.05, 95% CI = 0.86, 4.89; p = 0.10) showed a more significant improvement on the CGI-I scale, although not statistically significant.
Safety outcomes
The SSRI + PST group reported the fewest treatment-emergent adverse events, while the SSRI + NTP group experienced the most (28.1% v. 75%, respectively; p < 0.01). Largely, adverse events were mild (81.2%) or moderate (17.8%). Compared to others, dry mouth was more frequent in the SSRI + NTP group (p < 0.01), and bowel movements and diarrhoea were more frequent in the SSRI + Li group (p ≤ 0.01). Compared to the SSRI-Opt group, the SSRI + NTP group presented more constipation (p = 0.05), and the SSRI + Li group was associated with more tremors and gastrointestinal complaints (p = 0.04). Sweating was associated with venlafaxine use (p = 0.06). One participant in the SSRI + PST group presented a low-lethality suicide attempt (Fig. 3).
Fig. 3 Incidence of adverse effects occurring in more than 5% of patients in each treatment group. SSRI, serotonin reuptake inhibitor; Opt, dose optimisation; Li, lithium; NTP, nortriptyline; PST, problem-solving therapy; VEN, venlafaxine.
Discussion
The DEPRE’5 study, a pragmatic multicentre five-arm randomised controlled trial, assessed the efficacy of different treatment strategies for patients with MDD after an unsuccessful SSRI treatment. SSRI dose optimisation resulted in the lowest response rates, suggesting other alternatives should be considered. No significant differences in primary outcomes were found when comparing each strategy individually with the SSRI optimisation arm. However, the lower-than-planned recruitment rate could explain the lack of greater benefits of some of the explored treatments. Switching to venlafaxine, combining SSRIs with psychotherapy and, to a lesser extent, lithium augmentation offered better outcomes in terms of response rate, change in depressive symptoms and/or global improvement compared to dose optimisation. All conditions were safe, but patients receiving psychotherapy experienced fewer adverse events.
Although antidepressant dose optimisation is debated, Reference Jakubovski, Varigonda, Freemantle, Taylor and Bloch8,Reference Furukawa, Cipriani, Cowen, Leucht, Egger and Salanti9 real-world prescription patterns show that it is still a common approach for managing depressive episodes. Reference Gauthier, Guérin, Zhdanava, Jacobson, Nomikos and Merikle10 Surprisingly, SSRI monotherapy remains popular even after a second treatment failure, with long delays before exploring alternative strategies such as augmentation or combination. Reference Jain, Higa, Keyloun, Park, Bonafede and Tung19,Reference Gillain, Degraeve, Dreesen, De Bruecker, Buntinx and Beke20 While higher SSRI doses may boost efficacy, Reference Jakubovski, Varigonda, Freemantle, Taylor and Bloch8 we found that using a second-line approach – either expanding the mechanism of action or adding psychotherapeutic interventions – doubled the likelihood of response in the case of inadequate SSRI response.
Switching to venlafaxine showed potential as one of the more beneficial second-line strategies in our sample. While somewhat controversial, previous literature supports the increased effectiveness of dual-acting antidepressants in patients with severe depression or inadequate SSRI response. Reference Papakostas, Fava and Thase21,Reference Bradley and Lenox-Smith22 In this trial, most patients on venlafaxine received at least 150 mg/day, a dose modulating both monoaminergic pathways without compromising tolerability. Reference Furukawa, Cipriani, Cowen, Leucht, Egger and Salanti9
Lithium augmentation showed a trend towards greater symptom reduction at the end-point. However, the small sample size may have limited the ability to demonstrate more robust benefits. Although mean plasma levels were within the desired range, the SSRI + Li group showed lower adherence, which may have also affected the outcomes. Lithium users experienced more tremors and gastrointestinal discomfort but with no differences in drop-out rates. Meta-analyses support the efficacy of lithium augmentation in cases of inadequate antidepressant response, even when combined with SSRIs. Reference Bauer, Adi, Ricken, Sverus and Pilhatsch23,Reference Strawbridge, Carter, Marwood, Bandelow, Tsapekos and Nikolova24 Preliminary analyses suggest it may be more cost-effective than other augmentation strategies, such as atypical antipsychotics, with similar acceptability and tolerability. Reference Edwards, Hamilton, Nherera and Trevor25 The low usage rate may be because of clinicians’ inexperience, the need to monitor lithium levels or concerns about its narrow safety range. Despite less promotion and research, lithium remains a long-standing, consistent strategy in MDD. Further research should clarify whether lithium augmentation’s benefits are specific to certain groups of patients. Reference Bauer, Adi, Ricken, Sverus and Pilhatsch23,Reference Álvarez, Pérez-Solá, Pérez-Blanco, Queraltó, Torrubia and Noguera26
Our results support the utility of PST, a structured and goal-oriented cognitive–behavioural intervention, chosen for its effectiveness, applicability and limited duration, comparable to the other treatment arms. Reference Bell and D’zurilla27 Beyond the STAR*D study, Reference Thase, Friedman, Biggs, Wisniewski, Trivedi and Luther28 limited research has compared the effectiveness of combining psychotherapy with antidepressants in patients with previous treatment failures. Initial evidence suggests that combined treatment may be more effective than single treatments. Reference Malhi, Bell, Bassett, Boyce, Bryant and Hopwood7,Reference Cuijpers, Noma, Karyotaki, Vinkers, Cipriani and Furukawa29 Although SSRIs relieve some symptoms faster than psychotherapy, the latter, when combined with antidepressants, can be more effective in achieving behavioural activation and positive experiences, crucial aspects for a full recovery. Psychotherapy, alone or combined, is often better accepted by patients with mild to moderate depression. This matches the strong adherence seen in the SSRI + PST group and the lower adverse event rate.
The low remission rates are consistent, albeit slightly lower than those observed in comparable pragmatic studies. Reference Mohamed, Johnson, Chen, Hicks, Davis and Yoon30,Reference Lindhiem, Bennett, Trentacosta and McLear31 In contrast to the STAR*D study, which relied on an equipoise-stratified randomisation scheme, our participants were randomised using a classic randomisation approach regardless of the patient and clinician preferences, and raters were blinded. These factors influence expectations, treatment adherence and perceived efficacy. Reference Dunlop, Kelley, Aponte-Rivera, Mletzko-Crowe, Kinkead and Ritchie32 In clinical practice, choosing a particular second-line strategy relies on the degree of the previous antidepressant response (i.e. optimisation, augmentation or combination in the case of a partial response versus switching in the case of null response) or the type of predominant symptoms. Reference Bauer, Severus, Möller and Young33–Reference Korte, Prins, Krajnc, Hendriksen, Oosting and Westphal35 Unfortunately, we could not assess differences between groups based on the previous dose or the degree of response to the initial SSRI. The presence of specific stressful life events or maladaptive coping strategies could make psychotherapy the most appropriate option. Further research should identify clinical and neurobiological features that could moderate treatment responses to these alternatives, leading to more effective therapeutic decisions.
The duration of the depressive episode is one of the factors most clearly associated with the risk of persistence and treatment failure. Reference Bartova, Dold, Kautzky, Fabbri, Spies and Serretti36 In our study, almost 30% of the participants had an episode lasting over a year, over half had experienced previous episodes, 48% had at least one first-degree relative with a psychiatric history and nearly 10% had a lifetime history of suicidal behaviour. These factors could have influenced our patients’ likelihood of remission within 6 weeks. Reference Bartova, Dold, Kautzky, Fabbri, Spies and Serretti36
Judging by the symptom progression over the follow-up period, some participants may have achieved remission with the assigned treatment beyond that end-point. The VAST-D study, which tested the efficacy of different strategies in a sample of US veterans with MDD unresponsive to a first-line antidepressant, Reference Mohamed, Johnson, Chen, Hicks, Davis and Yoon30 showed even lower remission rates at week 6 compared to our study, with improvements in the subsequent weeks. Eight to 12 weeks may be necessary to achieve the maximum symptomatic reduction with a new line of antidepressant treatment, especially after initial treatment failure. Reference Bauer, Severus, Möller and Young33 In any case, our results support that the failure of one treatment reduces the odds of remission Reference Rush, Trivedi, Wisniewski, Nierenberg, Stewart and Warden3 and underscores the need to use other strategies than dose optimisation.
Several limitations have to be acknowledged. First, the low recruitment rate resulted in a lower-than-expected sample size and compromised our statistical power. Recruitment was challenging because participating sites often encountered participants who had been treated with multiple therapeutic lines at the initial assessment. Site was not included as a covariate, although the centres’ homogeneity, standardised protocols and centralised randomisation likely mitigated site-related variability. In addition, the study’s lack of a double-blind design and the use of the LOCF approach for imputing missing data may have influenced our findings. Since depressive symptoms tend to improve over time, a more extended follow-up period would have been needed. The degree of prior SSRI response, as well as clinical and patient’s expectations are rarely assessed in similar trials but may influence real-world treatment choices and outcomes. For some, optimising the dose of an ineffective antidepressant can be discouraging; for others, concerns about trying a new therapeutic option may make adjusting the dose of a known antidepressant preferable. Baseline doses of SSRIs were mostly appropriate but not maximal, supporting flexible adjustments in the SSRI-Opt group based on prior response, tolerability and perceived efficacy. The neutral way in which participants were informed about the common use and potential benefits of each arm, along with randomised treatment allocation and blinded assessment, may have helped mitigate these effects. Finally, other treatment alternatives (i.e. atypical antipsychotic augmentation, SSRI with α2-antagonist combination or other psychotherapeutic approaches) were not explored. Reference Strawbridge, Carter, Marwood, Bandelow, Tsapekos and Nikolova24,Reference Davies, Ijaz, Williams, Kessler, Lewis and Wiles37
In conclusion, patients with MDD who do not respond to SSRIs may benefit from exploring alternative second-line strategies beyond simply increasing doses. With limited statistical power, switching to venlafaxine and adding psychotherapy yielded more consistent results compared to dose optimisation.
Supplementary material
The supplementary material can be found at https://doi.org/10.1192/bjp.2025.13
Data availability
The data supporting this study’s findings are available from the corresponding author, M.E., upon reasonable request.
Author contributions
V.P.S, D.P. and J.D.D.A.: conceptualisation; methodology; analysis, supervision; writing, review and editing. M.E.: writing and editing. J.G.C: supervision, review and editing. F.C.: analysis, editing and review. I.L., M.C., L.G.F., J.U., A.G.N., E.L. and R.L.C.: recruitment, review. R.R.J., M.A.A.M., E.A.G., M.J.E., A.L.M., J.M.M., J.B., M.U.S., J.L.A.M, A.G.P. and A.O.: conceptualisation, recruitment and editing.
Funding
This work was supported by the official funding agency for biomedical research of the Spanish Government, Instituto de Salud Carlos III (ISCIII), through a grant co-financed by the Fondo de Investigación Sanitaria (FIS) and the European Regional Development Fund (FEDER): EC07/90244.
Declaration of interest
V.P. has received grants and served as consultant, advisor or continuing medical education (CME) speaker for AB-Biotics, Almirall, AstraZeneca, Bristol-Myers Squibb, Compass, Johnson & Johnson, Lundbeck, Medtronic, Merk, Otsuka, Pfizer, Solvay, the Spanish Ministry of Science and Innovation (CIBERSAM), the Ministry of Science (Carlos III Institute) and the Servei Català de Salud (Generalitat de Catalunya). J.D.D.A has received grants from the Spanish Ministry of Health Instituto de Salud Carlos III (PI23/00469) and the Health Research and Innovation Strategic Plan (PERIS; SLT008/18/00207) of the Generalitat de Catalunya and served as an advisor or CME speaker for Johnson & Johnson, Lundbeck, Pfizer, Neuraxpharm, Esteve, Viatris and Amgen. J.B has received consulting fees from Idorsia, honoraria for speaking and teaching from GILEAD and Menarini, grants for conference registration and travel and hosting costs from Johnson & Johnson, MSD and ViiV Healthcare, with no financial or other relationship relevant to the subject of this article. A.G.P has received grants and served as a consultant, advisor or CME speaker for the following entities: Johnson & Johnson, Lundbeck, Otsuka, Angelini, Exeltis, Novartis, Rovi, Takeda, the Spanish Ministry of Science and Innovation (CIBERSAM), the Ministry of Science (Carlos III Institute), the Basque Government and the European Framework Programme of Research. J.M.M. has received research funding from Johnson & Johnson, the Carlos III Health Institute and Otsuka-Lundbeck; in the last 5 years, he has had agreements or received fees as a speaker from Exeltis, Lundbeck, Angelini, Johnson & Johnson, Neuraxpharm, Pfizer, Servier, Rovi and Recordati. R.R.J has been a consultant for, spoken on activities of or received grants from Instituto de Salud Carlos III, Fondo de Investigación Sanitaria (FIS), Centro de Investigación Biomédica en Red de Salud Mental (CIBERSAM), Madrid Regional Government (S2010/ BMD-2422 AGES; S2017/BMD-3740), Johnson & Johnson, Lundbeck, Otsuka, Pfizer, Ferrer, Juste, Takeda, Exeltis, Casen-Recordati, Angelini and Rovi. All other authors have no interests to declare.
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