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Is self-guided internet-based cognitive behavioural therapy (iCBT) harmful? An individual participant data meta-analysis

Published online by Cambridge University Press:  15 March 2018

Eirini Karyotaki*
Affiliation:
Department of Clinical Psychology, VU Amsterdam and Institute for Public Health Research, Amsterdam, the Netherlands
Lise Kemmeren
Affiliation:
Department of Psychiatry, GGZ inGeest and VU University Medical Centre, Amsterdam Public Health research institute, Amsterdam, the Netherlands
Heleen Riper
Affiliation:
Department of Clinical Psychology, VU Amsterdam and Institute for Public Health Research, Amsterdam, the Netherlands
Jos Twisk
Affiliation:
Department of Epidemiology and Biostatistics and Amsterdam Institute for Public Health Research, VU University Amsterdam, Amsterdam, the Netherlands
Adriaan Hoogendoorn
Affiliation:
Department of Psychiatry, GGZ inGeest and VU University Medical Centre, Amsterdam Public Health research institute, Amsterdam, the Netherlands
Annet Kleiboer
Affiliation:
Department of Clinical Psychology, VU Amsterdam and Institute for Public Health Research, Amsterdam, the Netherlands
Adriana Mira
Affiliation:
Department of Psychology and Technology, Jaume University, Castellon, Spain CIBER Fisiopatología Obesidad y Nutrición (CIBERobn), Instituto Salud Carlos III, Spain
Andrew Mackinnon
Affiliation:
Black Dog Institute and University of New South Wales, Prince of Wales Hospital, Sydney, Australia Center for Mental Health, University of Melbourne, Melbourne, Australia
Björn Meyer
Affiliation:
Research Department, Germany and Department of Psychology, City University, Gaia AG, Hamburg, London, UK
Cristina Botella
Affiliation:
Department of Psychology and Technology, Jaume University, Castellon, Spain CIBER Fisiopatología Obesidad y Nutrición (CIBERobn), Instituto Salud Carlos III, Spain
Elizabeth Littlewood
Affiliation:
Department of Health Sciences, University of York, York, UK
Gerhard Andersson
Affiliation:
Department of Behavioural Sciences and Learning, Sweden Institute for Disability Research, Linköping University, Linköping, Sweden Department of Clinical Neuroscience, Psychiatry Section, Karolinska Institute for Disability Research, Stockholm, Sweden
Helen Christensen
Affiliation:
Black Dog Institute and University of New South Wales, Prince of Wales Hospital, Sydney, Australia
Jan P. Klein
Affiliation:
Department of Psychiatry and Psychotherapy, Lübeck University, Lübeck, Germany
Johanna Schröder
Affiliation:
Department of Psychiatry and Psychotherapy, University Medical Center Hamburg-Eppendorf, Hamburg, Germany
Juana Bretón-López
Affiliation:
Department of Psychology and Technology, Jaume University, Castellon, Spain CIBER Fisiopatología Obesidad y Nutrición (CIBERobn), Instituto Salud Carlos III, Spain
Justine Scheider
Affiliation:
Institute of Mental Health, University of Nottingham, Nottingham, UK
Kathy Griffiths
Affiliation:
Research School of Psychology, College of Biology, Medicine & Environment, Australian National University, Canberra, Australia
Louise Farrer
Affiliation:
Centre for Mental Health Research, The Australian National University, Canberra, Australia
Marcus J. H. Huibers
Affiliation:
Department of Clinical Psychology, VU Amsterdam and Institute for Public Health Research, Amsterdam, the Netherlands
Rachel Phillips
Affiliation:
Department of Primary Care and Public Health Sciences, King's College London, London, UK
Simon Gilbody
Affiliation:
Department of Health Sciences, University of York, York, UK
Steffen Moritz
Affiliation:
Department of Psychiatry and Psychotherapy, University Medical Center Hamburg-Eppendorf, Hamburg, Germany
Thomas Berger
Affiliation:
Department of Clinical Psychology and Psychotherapy, University of Bern, Bern, Switzerland
Victor Pop
Affiliation:
CoRPS – Center of Research on Psychology in Somatic diseases, Tilburg University, Tilburg, the Netherlands
Viola Spek
Affiliation:
CoRPS – Center of Research on Psychology in Somatic diseases, Tilburg University, Tilburg, the Netherlands
Pim Cuijpers
Affiliation:
Department of Clinical Psychology, VU Amsterdam and Institute for Public Health Research, Amsterdam, the Netherlands
*
Author for correspondence: Eirini Karyotaki, E-mail: [email protected]
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Abstract

Background

Little is known about potential harmful effects as a consequence of self-guided internet-based cognitive behaviour therapy (iCBT), such as symptom deterioration rates. Thus, safety concerns remain and hamper the implementation of self-guided iCBT into clinical practice. We aimed to conduct an individual participant data (IPD) meta-analysis to determine the prevalence of clinically significant deterioration (symptom worsening) in adults with depressive symptoms who received self-guided iCBT compared with control conditions. Several socio-demographic, clinical and study-level variables were tested as potential moderators of deterioration.

Methods

Randomised controlled trials that reported results of self-guided iCBT compared with control conditions in adults with symptoms of depression were selected. Mixed effects models with participants nested within studies were used to examine possible clinically significant deterioration rates.

Results

Thirteen out of 16 eligible trials were included in the present IPD meta-analysis. Of the 3805 participants analysed, 7.2% showed clinically significant deterioration (5.8% and 9.1% of participants in the intervention and control groups, respectively). Participants in self-guided iCBT were less likely to deteriorate (OR 0.62, p < 0.001) compared with control conditions. None of the examined participant- and study-level moderators were significantly associated with deterioration rates.

Conclusions

Self-guided iCBT has a lower rate of negative outcomes on symptoms than control conditions and could be a first step treatment approach for adult depression as well as an alternative to watchful waiting in general practice.

Type
Review Article
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
Copyright © Cambridge University Press 2018

Introduction

Depression is a common and major health issue that is associated with a considerable personal and societal burden (Reddy, Reference Reddy2010; Lepine & Briley, Reference Lepine and Briley2011). Self-guided forms of internet-based cognitive behaviour therapy (iCBT) can increase accessibility and reduce the costs of depression treatment (Hedman et al. Reference Hedman, Ljótsson and Lindefors2012; Muñoz et al. Reference Muñoz, Bunge, Chen, Schueller, Bravin and Shaughnessy2015). Over the past decade, free or commercially provided self-guided iCBT programmes have been made available to individuals with depression (Kaltenthaler et al. Reference Kaltenthaler, Brazier, De Nigris, Tumur, Ferriter and Beverley2006). However, there is an ongoing discussion about the advantages and disadvantages of such programmes (Andersson & Titov, Reference Andersson and Titov2014). Many healthcare systems remain hesitant to implement self-guided iCBT. Among the barriers to implementation are concerns regarding safety and effectiveness (Waller & Gilbody, Reference Waller and Gilbody2009). Offered as first stage treatment, self-guided iCBT has been criticised as potentially delaying individuals suffering from depression receiving effective clinical services (Robinson et al. Reference Robinson, Patrick, Eng and Gustafson1998; Ybarra & Eaton, Reference Ybarra and Eaton2005).

Our recent individual participant data (IPD) meta-analysis demonstrated that self-guided iCBT produces encouraging effects although average effects are small in magnitude (Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017). Small effects can be clinically useful and relevant, for instance in countries where mental healthcare services are scarce or inaccessible for other reasons (Muñoz et al. Reference Muñoz, Bunge, Chen, Schueller, Bravin and Shaughnessy2015; Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017). Despite the ample evidence regarding the overall benefits of iCBT, possible effects harmful to individuals have been infrequently monitored. As with any other potentially effective treatment, iCBT could also result in undesirable outcomes or fail to arrest substantial ongoing deterioration (Dimidjian & Hollon, Reference Dimidjian and Hollon2010). The issue of negative effects is crucial for clinical decision-making, yet limited systematic examination of this issue exists for iCBT.

In contrast to the vast majority of pharmacological trials, which rigorously measure and report adverse outcomes, only half of psychotherapeutic trials report undesirable outcomes, in particular substantial symptom deterioration (Jonsson et al. Reference Jonsson, Alaie, Parling and Arnberg2014; Vaughan et al. Reference Vaughan, Goldstein, Alikakos, Cohen and Serby2014). Previous research has shown that some forms of psychotherapy can be hazardous for some patients e.g. prolonged imaginal exposure may result in worsening of symptoms in some patients with posttraumatic stress disorder (Foa et al. Reference Foa, Hembree, Cahill, Rauch, Riggs and Feeny2005). With regard to self-guided psychological treatment, it has been argued that it may not be appropriate for all individuals (Newman, Reference Newman2000). For instance, self-guided interventions may not be intensive enough for individuals with severe symptoms (Mohr et al. Reference Mohr, Beutler, Engle, Shoham-Salomon, Bergan and Kaszniak1990). Moreover, lack of therapeutic support may jeopardise therapy outcomes as the progress of patients is not monitored (Newman et al. Reference Newman, Erickson, Przeworski and Dzus2003). Most self-guided interventions are not tailored to the current depressive status of the individual and, accordingly, do not respond to symptom deterioration (Andersson & Titov, Reference Andersson and Titov2014).

To our knowledge symptom deterioration has not been examined in self-guided iCBT to date. It is therefore clearly important to determine the prevalence and extent of symptom deterioration in self-guided iCBT. Furthermore, given that not everyone receiving self-guided iCBT experiences worsening of symptoms, research examining for whom this particular form of therapy may be harmful is sorely needed: individuals likely to deteriorate could be diverted to other more appropriate treatment options. However, study-level meta-analyses and randomised controlled trials (RCTs) cannot thoroughly examine moderators of deterioration due to inadequate power (Bower et al. Reference Bower, Kontopantelis, Sutton, Kendrick, Richards and Gilbody2013). Novel methodological approaches, such as IPD meta-analysis, are needed to identify who may experience adverse effects from self-guided iCBT. IPD meta-analysis allows us to move beyond the ‘grand mean’ to explore change at the individual level as well as to examine study variability (e.g. level of adherence, settings, etc.)

The present IPD meta-analysis examined rates of clinically significant symptom deterioration under self-guided iCBT compared with control conditions in adults with depression. In addition, we examined several socio-demographic and clinical variables as potential moderators of symptom deterioration. In the context of the present paper, the term ‘self-guided iCBT’ is defined as CBT treatment delivered via the Internet without any professional support related to the therapeutic content. The present analysis focuses on the prevalence of deterioration (numbers of persons affected) in contrast to our previous IPD meta-analysis of the present dataset in which we focused on population average outcomes due to self-guided iCBT on depression severity (Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017)

Methods

Studies selection process

We included IPD from randomised controlled trials comparing self-guided iCBT to a control condition (waiting list, treatment as usual, attention placebo or other non-active controls) for adults (⩾18 years old) with symptoms of depression based either on a diagnostic interview or validated self-report scales. We excluded studies that did not primarily target depression. No limits were applied for language and publication status.

To identify eligible studies, we used an existing database of trials focusing on psychological therapies for adults with depression (Cuijpers et al. Reference Cuijpers, van Straten, Warmerdam and Andersson2008). This database was developed in 2006 and is updated annually by a systematic literature search in four major bibliographic databases (PubMed, Embase, PsycINFO and Cochrane Library). The database was updated up to 1 January 2016 for the current search. In this search, various index and free terms of psychotherapy were used in combination with index and free terms of depression. Appendix A. presents the full electronic search string for PubMed. Two reviewers (PC and EK) examined 13 384 titles and abstracts independently. All full texts of papers that possibly met inclusion criteria according to one of the two reviewers were retrieved and checked for eligibility. Disagreement on the inclusion was solved through discussion. Additionally, references of recently published meta-analyses on this field were examined to ensure the inclusion of all eligible published trials. Finally, key researchers who are actively involved in this field were contacted to ask whether they were aware of unpublished trials on this topic or trials missed through the searches.

Data collection process and data items

We contacted the first or the senior author of the RCTs to request access to their datasets. In the case of no response, a reminder email was sent after 2 weeks and after 1 month. If no response was received 1 month after the first email, the study was excluded as unavailable. Authors provided IPD including socio-demographic variables (age, gender, educational level, employment status and relationship status), pre- and post-treatment depression scores, anxiety scores at baseline and the number of iCBT modules completed by each participant. All IPD were merged into one dataset. We also extracted study level variables available from the published reports of the included RCTs (type of control condition, recruitment method and level of support provided).

Risk of bias assessment

Two independent reviewers (EK and PC) assessed the risk of bias in the included studies according to the Cochrane risk of bias assessment tool (Higgins & Altman, Reference Higgins, Altman, Higgins and Green2008; Higgins & Green, Reference Higgins and Green2011). We examined whether the included studies were at low or high risk of selection, performance, detection, attrition, reporting and other sources of bias. In cases of uncertainty, clarification was sought from the authors of the RCT.

Measures

The included studies used either the Beck Depression Inventory [BDI-I (Beck et al. Reference Beck, Ward and Mendelson1961) or BDI-II (Beck et al. Reference Beck, Steer and Brown1996)], the Centre for Epidemiological Studies Depression Scale [CES-D (Radloff, Reference Radloff1977)] or the Patient Health Questionnaire [PHQ-9 (Kroenke et al. Reference Kroenke, Spitzer and Williams2001)] as outcome measures of depression severity.

We classified ‘clinically significant deterioration’ according to each participant's reliable change index (RCI) (Jacobson & Truax, Reference Jacobson and Truax1991), which is the most commonly used method for calculating clinically significant negative effects. This method aims to ensure that each individual's deterioration could not attributable to measurement error (Lambert et al. Reference Lambert, Bergin, Bergin and Garfield1993) and thus might warrant clinical intervention in the context of an unsupervised intervention such as iCBT. An RCI of ±1.96 indicates that the difference in scores is likely to be due to a real change in symptoms of an individual (95% confidence level). Participants showing a clinically significant change with an increase in their score (clinically significant negative change of more than −1.96) were classified as clinically significant deteriorated (Jacobson & Truax, Reference Jacobson and Truax1991). A RCI was calculated separately for each of the studies, using their pre-treatment standard deviation, and the test–retest reliability coefficient of the outcome measure (BDI = 0.93, CES-D = 0.87, PHQ-9 = 0.84).

Finally, in a sensitivity analysis we calculated ‘any deterioration’ as any increase of equal or more than one point on depressive symptom scales (increase ⩾1 BDI or CES-D or PHQ-9 point) from pre- to post-treatments. Any deterioration includes all deterioration rates (clinically significant or not).

Missing data

Missing outcome data at the post-treatment were multiply imputed. We generated one hundred imputed datasets based on the missing-at-random assumption (‘mi impute mvn’ in Stata version 13.1; StataCorp LP). These datasets, which consisted of the observed and the imputed deterioration rates, were analysed separately using the selected model and the results were combined using Rubin's rules (Rubin, Reference Rubin2004). We ran sensitivity analyses including only observed values to ensure the robustness of the results (‘the complete case analysis’).

Analysis

One-stage IPD

We performed a one-stage IPD meta-analysis in which the IPD from all included studies were merged, with participants nested within studies. A one-stage IPD approach is preferred over a two-stage approach because it allows for a more exact likelihood specification (Stewart & Parmar, Reference Stewart and Parmar1993; Debray et al. Reference Debray, Moons, Abo-Zaid, Koffijberg and Riley2013; Burke et al. Reference Burke, Ensor and Riley2016). We used the statistical software Stata (version 14.2) for conducting all analyses. A multilevel-mixed effects logistic regression was used to analyse the effect of the iCBT intervention on clinically significant deterioration and any deterioration. We used a random intercepts model with a random effect for each trial and fixed effect for condition (intervention v. control) using the ‘melogit’ command in Stata. The binary variables ‘clinically significant deterioration’ and ‘any deterioration’ were used as fixed effect.

To explore the variation in outcomes between participants, we examined dichotomous and continuous baseline characteristics of the participants as potential moderators of clinically significant deterioration and of any deterioration. Moderation was tested by adding the interaction between each moderator and deterioration rates to the multilevel mixed-effects logistic regression model. Similarly, we examined whether adherence (defined as number of modules completed divided by the total number of treatment modules) predicted lower deterioration rates within the intervention group.

Two-stage IPD

In addition to the one-stage IPD, we performed a two-stage IPD to examine the effects of study-level variables. We calculated the odds ratio (OR) of deterioration for each study and we pooled the outcomes using a random effects model, chosen because considerable heterogeneity across studies was expected. The OR shows the probability that an event (deterioration) will occur in the intervention group (self-guided iCBT) compared with the probability that the same event occurring in the control group. An OR of more than 1 indicates increased probability that an event will occur in the intervention group while and an OR <1 shows increased probability that an event will occur in the control group (Deeks et al. Reference Deeks, Higgins, Altman, Higgins and Green2008).

To examine heterogeneity, the I 2-statistic was calculated. This is an indicator of heterogeneity expressed as a percentage: an I 2 value of 0% is interpreted as no heterogeneity, 25% as low, 50% as moderate and 75% as high heterogeneity (Cohen, Reference Cohen1988). We calculated the 95% confidence intervals (CI) around I 2 using the non-central chi-squared-based approach within the heterogeneity module for Stata (Orsini et al. Reference Orsini, Bottai, Higgins and Buchan2006; Evangelou et al. Reference Evangelou, Ioannidis and Patsopoulos2007). Publication bias was examined by visually inspecting funnel plots and by using the Duval and Tweedie's trim and fill method, which yields an estimate of the effect size after adjusting for publication bias (Egger et al. Reference Egger, Smith, Schneider and Minder1997; Duval & Tweedie, Reference Duval and Tweedie2000). We also conducted the Egger's test of the intercept to quantify the bias captured by the funnel plot and test whether it was significant30.

Finally, we examined study-level moderators by conducting subgroup analyses using the mixed effects models in which studies were treated as random effects and subgroups were tested as fixed effects.

Sample representativeness

In our previous analysis (Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017), we tested differences between 13 studies that provided IPD and three eligible studies that did not. Results indicated that there are no statistically significant differences in depression severity outcomes between the included and the unavailable trials (Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017). This suggests that the present sample of studies is representative. However, we could not test differences between included and unavailable trials in the current analysis since deterioration rates are not reported by the published reports of the unavailable trials.

Results

Study selection

The systematic literature search resulted in 16 eligible studies for inclusion. The flowchart of the study selection process is presented in Fig. 1. Data were available from thirteen trials including 3876 participants (Christensen et al. Reference Christensen, Griffiths and Jorm2004; de Graaf et al. Reference de Graaf, Gerhards, Arntz, Riper, Metsemakers and Evers2009; Berger et al. Reference Berger, Hammerli, Gubser, Andersson and Caspar2011; Farrer et al. Reference Farrer, Christensen, Griffiths and Mackinnon2011; Gilbody et al. Reference Gilbody, Littlewood, Hewitt, Brierley, Tharmanathan and Araya2015; Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017 accepted, Spek et al. Reference Spek, Nyklíček, Smits, Cuijpers, Riper and Keyzer2007; Meyer et al. Reference Meyer, Berger, Caspar, Beevers, Andersson and Weiss2009; Moritz et al. Reference Moritz, Schilling, Hauschildt, Schroder and Treszl2012; Phillips et al. Reference Phillips, Schneider, Molosankwe, Leese, Foroushani and Grime2014; Kleiboer et al. Reference Kleiboer, Donker, Seekles, van Straten, Riper and Cuijpers2015; Meyer et al. Reference Meyer, Bierbrodt, Schröder, Berger, Beevers and Weiss2015; Klein et al. Reference Klein, Berger, Schröder, Späth, Meyer, Caspar and Lutz2016; Mira et al. Reference Mira, Bretón-López, García-Palacios, Quero, Baños and Botella2017). Three eligible datasets were excluded from the present IPD meta-analysis as data were unavailable (Clarke et al. Reference Clarke, Reid, Eubanks, O'connor, DeBar and Kelleher2002; Clarke et al. Reference Clarke, Eubanks, Reid, O'Connor, DeBar and Lynch2005; Clarke et al. Reference Clarke, Kelleher, Hornbrook, DeBar, Dickerson and Gullion2009).

Fig. 1. PRISMA IPD diagram of studies selection process.

Studies and participants characteristics

Studies characteristics are presented in Table 1. Across the 13 included RCTs participants were recruited mainly within communities. The studies were conducted in six countries (Australia, Germany, Spain, Switzerland, the Netherlands and the UK). The included RCTs examined the effects of self-guided iCBT over control conditions (attention placebo, no treatment, treatment as usual or waiting list). The interventions consisted of five to 11 online self-guided modules. The majority of the trials provided fully self-guided iCBT while four studies provided technical support related to technical aspects of the web-platform.

Table 1. Characteristics of included studies

AP, Attention Placebo; BDI, Beck Depression Inventory; CBT, Cognitive Behavioural Therapy; CES-D, Centre of Epidemiological Studies for Depression Scale; EDS, Edinburgh Depression Scale; HADS, Hospital Anxiety and Depression Scale; IPT, Interpersonal Psychotherapy; K10, Kessler 10 Psychological Distress Scale; Mini DIPS, Mini Diagnostic Interview for Psychiatric Disorders; n, number; NT, no treatment; PHQ-9, Patient Health Questionnaire; PST, Problem Solving Therapy; TAU, treatment as usual; WL: waiting list; WHO CIDI, World Health Organization Composite International Diagnostic Interview.

a Klein et al. Reference Klein, Berger, Schröder, Späth, Meyer, Caspar and Lutz2016 trial provided therapeutic support to participants with moderate depression (PHQ-9 > 9). Participants with mild depressive symptoms received no support throughout the trial. Klein et al. Reference Klein, Berger, Schröder, Späth, Meyer, Caspar and Lutz2016 stratified participants based on depression severity during randomisation. Therefore, we decided to exclude all participants who received therapeutic support (PHQ-9 > 9; n = 634) from the present IPD meta-analysis.

Patient characteristics of the intervention and control groups are presented in Table 2. There were no significant between-group differences in gender, age, relationship status, employment, education level, comorbid anxiety or pre-treatment scores on depression measures. Two-thirds of the participants were female (n = 2531/3832, 66%), and the mean age was 42 years (s.d. = 11.7). Most of the participants were employed (n = 2233/3146, 71%) and had a high school degree or further education (n = 2314/2574, 90%). Participants had mean baseline scores of BDI-II = 28.3 (s.d. = 14.4), CES-D = 25.7 (s.d. = 10.8) and PHQ-9 = 14.2 (s.d. = 5.4). A small number of individual cases (n = 71) did not start the treatment or did not have baseline data, leaving a total of n = 3805. Finally, 997 participants dropped out from the included RCTs and did not provide post-treatment scores of depressive symptoms (26% of the total sample). More specifically, 630/2220 (28.4%) and 347/1585 (22%) participants dropped out of the intervention and controls, respectively. The intervention had significantly higher study dropout rates compared with controls (OR 1.51, 95% CI 1.11–2.08; p = 0.01).

Table 2. Sociodemographic and clinical characteristics of study participants

Assessment of risk of bias

The overall risk of bias was low across the included RCTs. Random sequence was adequately generated and allocation was concealed in all included studies. Blinding of participants and personnel is not possible in psychotherapy research due to the nature of the treatment. The included RCTs used self-report outcome measure, thus blinding of outcome assessment is not applicable. As an attempt to minimise attrition bias, we multiply imputed the missing data in the present IPD. Finally, there was no indication of selective reporting and other sources of bias. For a justification of risk of bias assessment for each study, the reader is referred to our previous publication (Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017).

Prevalence of clinically significant deterioration

Overall, 7.2% (276/3805) of participants met criteria for clinically significant deterioration, while 30.1% (1143/3805) showed deterioration of any size. Divided by treatment group, 5.8% of participants who followed self-guided iCBT and 9.1% of participants in control groups showed clinically significant deterioration. Similarly, 26.2% of participants in self-guided iCBT and 35.3% of participants in control groups experienced any deterioration. Complete case analysis showed that 6.1 and 9.1% of participants showed clinically significant deterioration in self-guided iCBT and control groups, respectively. Any deterioration rates were 26.5% for self-guided iCBT and 36.6% for the control groups.

One-stage IPD: deterioration rates

The outcomes of one-stage IPD meta-analysis on deterioration rates are summarised in Table 3. Self-guided iCBT resulted in significantly lower clinically significant deterioration (OR 0.62; 95% CI 0.46–0.83, p < 0.001) compared with controls at post-treatment assessment (6–16 weeks post-randomisation). Sensitivity analysis on any deterioration rates and complete case analyses yielded similar outcomes, suggesting that these findings are robust. No significant associations were found between participant characteristics (age, gender, educational level, relationship status, employment status, comorbid anxiety and baseline severity of depression) or for deterioration rates in both full sample and complete case analyses. Finally, treatment adherence was not significantly associated with clinically significant (β = −0.01; s.e. = 0.37, p = 0.97) or any deterioration (β = −0.10; s.e. = 0.19, p = 0.59) within the intervention group.

Table 3. Relative odds of deterioration under self-guided iCBT v. controls in one-stage IPD analysis

N obs, Number of observations; N st, number of studies; OR, odds ratio; s.e., standard error

a This is a sensitivity analysis that was conducted including only participants who completed post-treatment depression questionnaires

Two-stage IPD deterioration rates

Results of the two-stage IPD meta-analysis replicated the findings of one-stage IPD on clinically significant deterioration (OR 0.62; 95% CI 0.48–0.81, p < 0.001). Heterogeneity was zero. These results were replicated in sensitivity analysis on any deterioration rates showed similar outcomes and complete case analyses. There was no indication for publication bias across all the analyses. Finally, the examined study-level variables were not significantly associated with clinically significant and any deterioration. Results of the two-stage IPD are presented in Table 4 in the online supplement.

Table 4. Relative odds of deterioration of self-guided iCBT v. controls in adults with depressive symptoms, two-stage IPD

I 2, heterogeneity index; N, number of studies; N/A, not applicable; OR, odds ratio.

a 95% CI 95% confidence intervals; p, p-value.

b p value between groups.

Discussion

The present IPD meta-analysis aimed to examine the clinically significant symptom deterioration rates of self-guided iCBT compared with controls and to evaluate the moderating effects of deterioration. Of the 3805 participants included in the analysis, 7.2% showed clinically significant deterioration. Self-guided iCBT had low clinically significant deterioration rates (5.8%) and resulted in lower risk of clinically significant deterioration compared with controls at the post-treatment assessment. Similar results were observed in sensitivity analyses. None of the examined participant- and study-level variables moderated clinically significant deterioration.

This is the first meta-analysis to have systematically examined deterioration rates in self-guided iCBT for adults with depressive symptoms. The finding that self-guided iCBT shows lower deterioration rates compared with controls is consistent with previous IPD meta-analysis of 2079 participants on guided internet based interventions (Ebert et al. Reference Ebert, Donkin, Andersson, Andrews, Berger and Carlbring2016). According to this work, guided web-based interventions resulted in lower risk of clinically significant deterioration compared with controls. Furthermore, guided internet-based interventions showed 3.6% clinically significant deterioration, which is slightly lower but comparable with the present clinically significant deterioration rates of self-guided iCBT (5.8%) (Ebert et al. Reference Ebert, Donkin, Andersson, Andrews, Berger and Carlbring2016). The deterioration rates found in the present IPD meta-analysis are in line with the deterioration rates observed in face-to-face treatment (5–10%) (Rozental et al. Reference Rozental, Andersson, Boettcher, Ebert, Cuijpers and Knaevelsrud2014) and considerably lower compared with the 12% rate of deterioration reported by a recent meta-analysis examining change under treatment as usual (Kolovos et al. Reference Kolovos, van Tulder, Cuijpers, Prigent, Chevreul and Riper2017).

The present study has several notable strengths; we were able to obtain IPD from 3876 participants from the majority (81%) of the eligible trials. This large number of participants offered us adequate power to detect statistically significant differences between self-guided iCBT and controls on symptom deterioration rates and to examine moderators of clinically significant deterioration. In addition, the current sample of studies appears to be free from critical bias, since the included trials had high methodological quality. Other strengths of the current work are that heterogeneity between studies was small to moderate and there was no indication of publication bias.

Nevertheless, the current findings should be interpreted with caution due to a number of limitations. The present sample of studies is at (relatively low) risk of availability bias since three eligible studies were not available for inclusion. The published reports of these unavailable trials did not include deterioration rates. Thus, traditional meta-analysis of direct comparison between available and unavailable studies was not possible. However, results of a previous analysis showed no difference between the effectiveness of the available and unavailable studies, indicating that the present sample is representative (Karyotaki et al. Reference Karyotaki, Riper, Twisk, Hoogendoorn, Kleiboer and Mira2017). Moreover, the intervention had significantly higher study dropout rates compared with control conditions. It has been suggested that study dropout could be either related to symptom deterioration or improvement (Rozental et al. Reference Rozental, Andersson, Boettcher, Ebert, Cuijpers and Knaevelsrud2014). On the other hand, higher study adherence rates in controls, such as waiting list, may be associated to the expectation that participants will eventually receive treatment. Unfortunately, it was not possible to examine reasons for study dropout as this information is largely missing from the included studies. In light of this limitation, it should be noted that in the present analysis missing outcome data were multiply imputed based on missing at random assumption. The missing at random assumption underlying multiple imputation is critical as it assumes that those participants for whom post-treatment data were imputed behaved similarly to those with post-treatment data with comparable profiles. Therefore, if individuals dropped out due to deterioration (missing not at random), this would not be captured and a conservative estimate of deterioration is likely. Nevertheless, we performed a complete case analysis to test the robustness of our main full sample analysis and we found no differences between the full sample and complete cases in deterioration rates. Another limitation is that we could not examine several variables that might influence deterioration, such as previous episodes of depression and symptom duration. Individuals who have experienced several episodes of depression in the past and those who have chronic symptoms might be at greater risk of deterioration. Moreover, the majority of the trials included recruited their participants through the community. Thus, the current findings cannot be generalised to patients treated in clinical settings since active care seekers may differ from individuals responding to advertisements.

From a clinical point of view, the present study has important implications. Although many patients prefer psychotherapy to antidepressants (van Schaik et al. Reference van Schaik, Klijn, van Hout, van Marwijk, Beekman and de Haan2004), pharmacotherapy dominates primary and secondary mental healthcare while psychotherapy is offered to a lesser degree. Self-guided iCBT has the potential to increase the availability and accessibility of psychotherapy and minimise the costs. However, the implementation of self-guided iCBT in clinical practice is hampered by barriers, such as concerns regarding its safety and effectiveness. The present study has demonstrated that self-guided iCBT results in lower risk for symptom deterioration compared with controls (including regular care services) and our previous study showed that is effective in treating depressive symptoms. This suggests that self-guided iCBT could be an alternative to watchful waiting in general practice and it can be disseminated at a large scale in countries where resources of mental healthcare are limited or inaccessible due to other reasons.

Symptom deterioration occurs in self-guided iCBT and study dropout is higher compared with controls; thus, future studies should carefully examine and report deterioration rates and reasons for study dropout. Future research on self-guided iCBT interventions should examine deterioration rates over longer time periods. Moreover, moderators, such as duration of symptoms and previous episodes, should be addressed by future studies to indicate for whom self-guided iCBT might be harmful. More studies from primary care are needed to replicate the current findings with clinical samples.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291718000648

Acknowledgements

This work was funded by the European Commission's Seventh Framework Program (grant 603098 for the E-COMPARED project). At the time of the study, Dr K. Griffiths was supported by National Health & Medical Research Counselling Fellowship 1059620.

Declaration of interest

Dr Klein reported receiving funding for clinical trials (German Federal Ministry of Health, Servier), payments for presentations on internet interventions (Servier), and payments for workshops and books (Beltz, Elsevier and Hogrefe) on psychotherapy for chronic depression and psychiatric emergencies. No other disclosures were reported.

References

Andersson, G and Titov, N (2014) Advantages and limitations of internet-based interventions for common mental disorders. World Psychiatry 13, 411.Google Scholar
Beck, A, Steer, R and Brown, G (1996) BDI-II, Beck Depression Inventory: Manual. San Antonio, TX: Psychological Corporation.Google Scholar
Beck, AT, Ward, C and Mendelson, M (1961) Beck depression inventory (BDI). Archives of General Psychiatry 4, 561571.Google Scholar
Berger, T, Hammerli, K, Gubser, N, Andersson, G and Caspar, F (2011) Internet-based treatment of depression: a randomized controlled trial comparing guided with unguided self-help. Cognitive Behavioral Therapy 40, 251266.Google Scholar
Bower, P, Kontopantelis, E, Sutton, A, Kendrick, T, Richards, DA, Gilbody, S et al. (2013) Influence of initial severity of depression on effectiveness of low intensity interventions: meta-analysis of individual patient data. The British Medical Journal 346, f540.Google Scholar
Burke, DL, Ensor, J and Riley, RD (2016) Meta-analysis using individual participant data: one-stage and two-stage approaches, and why they may differ. Statistics in Medicine. 36(5), 855875.Google Scholar
Christensen, H, Griffiths, KM and Jorm, AF (2004) Delivering interventions for depression by using the internet: randomised controlled trial. The British Medical Journal 328, 265.Google Scholar
Clarke, G, Eubanks, D, Reid, CK, O'Connor, E, DeBar, LL, Lynch, F et al. (2005) Overcoming depression on the internet (ODIN)(2): a randomized trial of a self-help depression skills program with reminders. Journal of Medical Internet Research 7(2), e16.Google Scholar
Clarke, G, Kelleher, C, Hornbrook, M, DeBar, L, Dickerson, J and Gullion, C (2009) Randomized effectiveness trial of an internet, pure self-help, cognitive behavioral intervention for depressive symptoms in young adults. Cognitive Behavioral Therapy 38, 222234.Google Scholar
Clarke, G, Reid, E, Eubanks, D, O'connor, E, DeBar, LL, Kelleher, C et al. (2002) Overcoming depression on the internet (ODIN): a randomized controlled trial of an internet depression skills intervention program. Journal of Medical Internet Research 4, e14.Google Scholar
Cohen, J (1988) Statistical Power Analysis for the Behavioral Sciences. 2nd ed. Hillsdale, NJ: Lawrence. Erlbaum Associates.Google Scholar
Cuijpers, P, van Straten, A, Warmerdam, L and Andersson, G (2008) Psychological treatment of depression: a meta-analytic database of randomized studies. BMC Psychiatry 8, 16.Google Scholar
Debray, TP, Moons, KG, Abo-Zaid, GMA, Koffijberg, H and Riley, RD (2013) Individual participant data meta-analysis for a binary outcome: one-stage or two-stage? PLoS ONE 8, e60650.Google Scholar
Deeks, JJ, Higgins, J and Altman, DG (2008) Analysing data and undertaking meta-analyses. In Higgins, JP and Green, S (eds). Cochrane Handbook for Systematic Reviews of Interventions: Cochrane Book Series. Cochrane Book Series. Chichester, UK: John Wiley & Sons, Ltd, pp. 243296.Google Scholar
de Graaf, LE, Gerhards, S, Arntz, A, Riper, H, Metsemakers, J, Evers, S et al. (2009) Clinical effectiveness of online computerised cognitive–behavioural therapy without support for depression in primary care: randomised trial. The British Journal of Psychiatry 195, 7380.Google Scholar
Dimidjian, S and Hollon, SD (2010) How would we know if psychotherapy were harmful? American Psychologist 65, 21.Google Scholar
Duval, S and Tweedie, R (2000) Trim and fill: a simple funnel-plot-based method of testing and adjusting for publication bias in meta-analysis. Biometrics 56, 455463.Google Scholar
Ebert, DD, Donkin, L, Andersson, G, Andrews, G, Berger, T, Carlbring, P et al. (2016) Does internet-based guided-self-help for depression cause harm? An individual participant data meta-analysis on deterioration rates and its moderators in randomized controlled trials. Psychological Medicine 46, 26792693.Google Scholar
Egger, M, Smith, GD, Schneider, M and Minder, C (1997) Bias in meta-analysis detected by a simple, graphical test. British Medical Journal 315, 629634.Google Scholar
Evangelou, E, Ioannidis, JP and Patsopoulos, NA (2007) Uncertainty in heterogeneity estimates in meta-analyses. The British Medical Journal 335, 914916.Google Scholar
Farrer, L, Christensen, H, Griffiths, KM and Mackinnon, A (2011) Internet-based CBT for depression with and without telephone tracking in a national helpline: randomised controlled trial. PLoS ONE 6, e28099.Google Scholar
Foa, EB, Hembree, EA, Cahill, SP, Rauch, SA, Riggs, DS, Feeny, NC et al. (2005) Randomized trial of prolonged exposure for posttraumatic stress disorder with and without cognitive restructuring: outcome at academic and community clinics. Journal of Consulting and Clinical Psychology 73, 953.Google Scholar
Gilbody, S, Littlewood, E, Hewitt, C, Brierley, G, Tharmanathan, P, Araya, R et al. (2015) Computerised cognitive behaviour therapy (cCBT) as treatment for depression in primary care (REEACT trial): large scale pragmatic randomised controlled trial. The British Medical Journal 351, h5627.Google Scholar
Hedman, E, Ljótsson, B and Lindefors, N (2012) Cognitive behavior therapy via the internet: a systematic review of applications, clinical efficacy and cost-effectiveness. Expert Review of Pharmacoeconomics & Outcomes Research 12, 745764.Google Scholar
Higgins, J and Altman, DG (2008) Assessing risk of bias in included studies In Higgins, JP and Green, S (eds). Cochrane Handbook for Systematic Reviews of Interventions: Cochrane Book Series. Chichester, UK: John Wiley & Sons, Ltd, pp. 187241.Google Scholar
Higgins, J and Green, S (2011) Handbook for Systematic Reviews of Interventions. version 5.1. 0 [updated March 2011]. Chichester, UK: John Wiley & Sons, Ltd.Google Scholar
Jacobson, NS and Truax, P (1991) Clinical significance: a statistical approach to defining meaningful change in psychotherapy research. Journal of Consulting and Clinical Psychology 59, 12.Google Scholar
Jonsson, U, Alaie, I, Parling, T and Arnberg, FK (2014) Reporting of harms in randomized controlled trials of psychological interventions for mental and behavioral disorders: a review of current practice. Contemporary Clinical Trials 38, 18.Google Scholar
Kaltenthaler, E., Brazier, J., De Nigris, E., Tumur, I., Ferriter, M., Beverley, C. et al. (2006). Computerised cognitive behaviour therapy for depression and anxiety update: a systematic review and economic evaluation. Health Technology Assessment 10, iii, xi-xiv, 1168.Google Scholar
Karyotaki, E, Riper, H, Twisk, J, Hoogendoorn, A, Kleiboer, A, Mira, A et al. (2017) Efficacy of self-guided internet-based cognitive behavioral therapy in the treatment of depressive symptoms: a meta-analysis of individual participant data. JAMA Psychiatry 74(4), 351359.Google Scholar
Kleiboer, A, Donker, T, Seekles, W, van Straten, A, Riper, H and Cuijpers, P (2015) A randomized controlled trial on the role of support in internet-based problem solving therapy for depression and anxiety. Behavioral Research Therapy 72, 6371.Google Scholar
Klein, JP, Berger, T, Schröder, J, Späth, C, Meyer, B, Caspar, F, Lutz, W et al. (2016) Effects of a psychological internet intervention in the treatment of mild to moderate depressive symptoms: results of the EVIDENT study, a randomised controlled trial. Psychotherapy Psychosomatics 85(4), 218228.Google Scholar
Kolovos, S, van Tulder, MW, Cuijpers, P, Prigent, A, Chevreul, K, Riper, H et al. (2017) The effect of treatment as usual on major depressive disorder: a meta-analysis. Journal of Affective Disorders 210, 7281.Google Scholar
Kroenke, K, Spitzer, RL and Williams, JB (2001) The Phq-9. Journal of General Internal Medicine 16, 606613.Google Scholar
Lambert, MJ, Bergin, A, Bergin, A and Garfield, S (1993) Handbook of Psychotherapy and Behavior Change. New York: John Wiley & Sons. Kendall, P. C., & Chambless, D. L. (Eds).Google Scholar
Lepine, JP and Briley, M (2011) The increasing burden of depression. Neuropsychiatric Disease and Treatment 7, 37.Google Scholar
Meyer, B, Berger, T, Caspar, F, Beevers, CG, Andersson, G and Weiss, M (2009) Effectiveness of a novel integrative online treatment for depression (Deprexis): randomized controlled trial. Journal of Medical Internet Research 11, e15.Google Scholar
Meyer, B, Bierbrodt, J, Schröder, J, Berger, T, Beevers, CG, Weiss, M et al. (2015) Effects of an internet intervention (Deprexis) on severe depression symptoms: randomized controlled trial. Internet Interventions 2, 4859.Google Scholar
Mira, A, Bretón-López, J, García-Palacios, A, Quero, S, Baños, RM and Botella, C (2017) An internet-based program for depressive symptoms using human and automated support: a randomized control trial. Neuropsychiatric Disease and Treatment 13, 9871006.Google Scholar
Mohr, DC, Beutler, LE, Engle, D, Shoham-Salomon, V, Bergan, J, Kaszniak, AW et al. (1990) Identification of patients at risk for nonresponse and negative outcome in psychotherapy. Journal of Consulting and Clinical Psychology 58, 622.Google Scholar
Moritz, S, Schilling, L, Hauschildt, M, Schroder, J and Treszl, A (2012) A randomized controlled trial of internet-based therapy in depression. Behavioral Research Therapy 50, 513521.Google Scholar
Muñoz, RF, Bunge, EL, Chen, K, Schueller, SM, Bravin, JI, Shaughnessy, EA et al. (2015) Massive open online interventions a novel model for delivering behavioral-health services worldwide. Clinical Psychological Science 4(2), 194205.Google Scholar
Newman, MG (2000) Recommendations for a cost-offset model of psychotherapy allocation using generalized anxiety disorder as an example. Journal of Consulting and Clinical Psychology 68, 549.Google Scholar
Newman, MG, Erickson, T, Przeworski, A and Dzus, E (2003) Self-help and minimal-contact therapies for anxiety disorders: is human contact necessary for therapeutic efficacy? Journal of Clinical Psychology 59, 251274.Google Scholar
Orsini, N, Bottai, M, Higgins, J and Buchan, I (2006) Heterogi: Stata module to quantify heterogeneity in a meta-analysis. Statistical Software Components Available at https://econpapers.repec.org/software/bocbocode/s449201.htm.Google Scholar
Phillips, R, Schneider, J, Molosankwe, I, Leese, M, Foroushani, PS, Grime, P et al. (2014) Randomized controlled trial of computerized cognitive behavioural therapy for depressive symptoms: effectiveness and costs of a workplace intervention. Psychological Medicine 44, 741752.Google Scholar
Radloff, LS (1977) The CES-D scale a self-report depression scale for research in the general population. Applied Psychological Measurement 1, 385401.Google Scholar
Reddy, M (2010) Depression: the disorder and the burden. Indian Journal of Psychological Medicine 32, 1.Google Scholar
Robinson, TN, Patrick, K, Eng, TR and Gustafson, D (1998) An evidence-based approach to interactive health communication: a challenge to medicine in the information age. JAMA 280, 12641269.Google Scholar
Rozental, A, Andersson, G, Boettcher, J, Ebert, DD, Cuijpers, P, Knaevelsrud, C et al. (2014) Consensus statement on defining and measuring negative effects of internet interventions. Internet Interventions 1, 1219.Google Scholar
Rubin, DB (2004) Multiple Imputation for Nonresponse in Surveys. New York: John Wiley & Sons.Google Scholar
Spek, V, Nyklíček, I, Smits, N, Cuijpers, P, Riper, H, Keyzer, J et al. (2007) Internet-based cognitive behavioural therapy for subthreshold depression in people over 50 years old: a randomized controlled clinical trial. Psychological Medicine 37, 17971806.Google Scholar
Stewart, L and Parmar, M (1993) Meta-analysis of the literature or of individual patient data: is there a difference? The Lancet 341, 418422.Google Scholar
van Schaik, DJ, Klijn, AF, van Hout, HP, van Marwijk, HW, Beekman, AT, de Haan, M et al. (2004) Patients’ preferences in the treatment of depressive disorder in primary care. General Hospital Psychiatry 26, 184189.Google Scholar
Vaughan, B, Goldstein, MH, Alikakos, M, Cohen, LJ and Serby, MJ (2014) Frequency of reporting of adverse events in randomized controlled trials of psychotherapy vs. psychopharmacotherapy. Comprehensive Psychiatry 55, 849855.Google Scholar
Waller, R and Gilbody, S (2009) Barriers to the uptake of computerized cognitive behavioural therapy: a systematic review of the quantitative and qualitative evidence. Psychological Medicine 39, 705712.Google Scholar
Ybarra, ML and Eaton, WW (2005) Internet-based mental health interventions. Mental Health Services Research 7, 7587.Google Scholar
Figure 0

Fig. 1. PRISMA IPD diagram of studies selection process.

Figure 1

Table 1. Characteristics of included studies

Figure 2

Table 2. Sociodemographic and clinical characteristics of study participants

Figure 3

Table 3. Relative odds of deterioration under self-guided iCBT v. controls in one-stage IPD analysis

Figure 4

Table 4. Relative odds of deterioration of self-guided iCBT v. controls in adults with depressive symptoms, two-stage IPD

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