Participants

Adolescents and their parent(s) participated in RE-PAIR (‘Relations and Emotions in Parent-Adolescent Interaction Research’). This Dutch multi-method two-generation study investigates the bidirectional interplay between parent-adolescent interactions and adolescent wellbeing by comparing adolescents with major depressive disorder (MDD) or dysthymia (DEP) to healthy controls (HC). Families with a DEP adolescent were primarily recruited via mental health clinics. Families were also recruited via (social) media. Inclusion criteria for all adolescents were as follows: aged between 11 and 17 years when screened for psychopathology, having started secondary school, living with one or both parents, and good command of the Dutch language. Inclusion criteria specifically for DEP adolescents were: a current MDD or dysthymia diagnosis as determined by the Kiddie-Schedule for Affective Disorders and Schizophrenia–Present and Lifetime Version (K-SADS-PL) (Kaufman, Birmaher, Brent, Rao, & Ryan, Reference Kaufman, Birmaher, Brent, Rao and Ryan1996), and psychotherapy for their depression did not start yet, or had just started. Exclusion criteria for DEP adolescents were: a primary mental disorder other than MDD/dysthymia, or having a comorbid psychosis, substance use disorder, autism spectrum disorder, and/or mental retardation. For HCs, a lifetime MDD/dysthymia diagnosis or any other psychiatric diagnosis in the 2 years preceding study participation was an exclusion criterion. Families participated in a lab session, completed ecological momentary assessment (EMA; Stone & Shiffman, Reference Stone and Shiffman1994) for 14 consecutive days, and were invited for an MRI-scanning session (for detailed procedures, see Supplement 1). For the scanning session, MRI contraindications were exclusion criteria.

In total, 22 DEP and 63 HC adolescents took part in the scanning session. The current paper focuses on the impact of depression on responses to parental feedback, whereas data of HCs have previously been published elsewhere (van Houtum et al., Reference van Houtum, Will, Wever, Janssen, van Schie, Tollenaar and Elzinga2022). Two HCs were excluded due to scanner artifacts, one due to excessive head motion, and one because of a depression severity score in the clinical range, see also (van Houtum et al., Reference van Houtum, Will, Wever, Janssen, van Schie, Tollenaar and Elzinga2022). Furthermore, one DEP adolescent was excluded due to excessive head motion and one due to claustrophobia. This resulted in a final sample of 20 DEP (primary diagnosis MDD: n = 16; dysthymia: n = 4) and 59 HC adolescents (Table 1 and Supplement 2).

Table 1. Participants' demographics and descriptive statistics

EHI, Edinburgh handedness inventory (Oldfield, Reference Oldfield1971); PBI, parental bonding instrument (Parker, Tupling, & Brown, Reference Parker, Tupling and Brown1979); PDS, pubertal development scale (Petersen, Crockett, Richards, & Boxer, Reference Petersen, Crockett, Richards and Boxer1988); PHQ-9, patient health questionnaire-9 (Kroenke & Spitzer, Reference Kroenke and Spitzer2002).

^a As assumptions of normality and/or equal variances were not met, a nonparametric Mann–Whitney U test was conducted.

^b n = 58 healthy control adolescents, as PBI data of one adolescent was missing.

RE-PAIR was approved by the Medical Ethics Review Committee of Leiden University Medical Centre, Leiden, the Netherlands (reference: P17.241; protocol: NL62502.058.17) and carried out in accordance with the Declaration of Helsinki and Dutch Medical Research Involving Human Subjects Act (WMO). Written informed assent and consent were obtained from all adolescents and their parents prior to study procedures.

Clinical assessment

To determine current and lifetime psychopathology adolescents were interviewed based on DSM-IV criteria using the K-SADS-PL (Kaufman et al., Reference Kaufman, Birmaher, Brent, Rao and Ryan1996). For DEP adolescents, interviews were conducted by a trained psychologist from the mental healthcare institution where the adolescent was (on the waiting list for) being treated. Otherwise, adolescents were interviewed by trained graduate clinical psychology students of Leiden University prior (DEP) or during (HC) the lab session. Final diagnoses were discussed with a registered healthcare psychologist. Additionally, depressive symptoms were assessed using the Patient Health Questionnaire-9 (Kroenke & Spitzer, Reference Kroenke and Spitzer2002) as part of the scanning session questionnaire battery.

Parental social feedback task

During the parental social feedback task, adolescents received social feedback (i.e. words describing their personality) supposedly given by their parent (van Houtum et al., Reference van Houtum, Will, Wever, Janssen, van Schie, Tollenaar and Elzinga2022). During the lab session, adolescents and their parents had rated 49 feedback words in terms of valence (‘What do you think of this personality characteristic?’) from −4 (‘very negative’) to 0 (‘neutral’) to 4 (‘very positive’) and applicability to the adolescent (‘To what extent does this personality characteristic apply to you/your child?’) from 1 (‘not at all’) to 5 (‘very much’). Questions could be answered with a question mark if a feedback word was unclear. Unclear feedback words were discarded from analyses on a person-based level [excluded words: 16 (0.6%) across 12 HCs; 12 (1.3%) across 7 DEP].

Right before the task, adolescents were informed that their mother/father (HC: n = 32/27; DEP: n = 13/7) was asked to select both positive and negative personality characteristics from a list that they deemed most descriptive of their child, and that they would see these chosen personality characteristics. In reality, each adolescent received the same preprogrammed feedback, split in three predetermined valence categories: 15 positive (e.g. ‘Kind’), 15 intermediate (e.g. ‘Chaotic’), and 15 negative words (e.g. ‘Untrustworthy’; see (van Houtum et al., Reference van Houtum, Wever, Janssen, van Schie, Will, Tollenaar and Elzinga2021)). Each trial (online Supplementary Fig. S1) started with a jittered fixation cross and the sentence ‘Your mother/father thinks you are:’ [duration: 2000–6000 ms (M = 4000 ms)]. Next, a feedback word appeared (2500 ms), followed by a jittered inter-trial-interval [duration: 1000–3000 ms (M = 2000 ms)]. After each feedback word, adolescents rated their current mood (‘How do you feel right now?’) from 1 (‘very negative’) to 7 (‘very positive’) with MR-compatible button boxes. Participants used their left index- and middle fingers to move from left to right on the scale and their right index-finger to confirm responses. If adolescents did not respond within 8000 ms, the message ‘Too late’ appeared (1000 ms), and the trial was excluded from analyses [excluded trials: 4 (0.15%) across 4 HCs; 0 DEP]. Feedback words were pseudo-randomly presented, with the condition that consecutive words were never of similar valence. The task started and ended with two fixed positive feedback fillers, being excluded from analyses. Before and after the task, adolescents filled out visual analog scales to assess their current level of self-esteem, sadness, relaxation, and irritation (Supplement 3).

Outside the scanner, we asked adolescents to freely recall as much feedback words as possible within 2 min, using an online questionnaire with a timer. Obvious typos (e.g. ‘life’ instead of the Dutch word ‘lief’) were corrected manually. Next, adolescents were interviewed to check the extent to which they believed that their parent provided the feedback. No adolescent disbelieved our cover story (Supplement 4). Hereafter, a thorough debriefing took place about study purposes and to ensure adolescents understood that feedback was preprogrammed and not based on their parent's appraisals. We also informed parents that their child received preprogrammed feedback, ostensibly given by them. Families received a letter explaining the experimental set-up and – if preferred – were contacted later to evaluate experiences (contacted families: n = 15). The task was well-received by families, and they were positive about study participation.

The task was programmed using E-Prime 2.0 (Psychological Software Tools, Pittsburgh, PA) and presented on a 32-inch BOLD-screen (Cambridge Research Systems, Cambridge, UK) placed at the end of the scanner bore, which participants could see via a mirror attached to the head coil.

Parents' general view of their child

Parents' general tendency to view their child positively was calculated by multiplying parents' applicability ratings of the feedback words (assessed during the lab session) with within-subject z-scored valence ratings of these words. Parents can have different baseline values in valence ratings of words. To account for these differences between parents, we used within-subject z-scored valence ratings to ascertain that parents' evaluation of the valence of feedback words are incorporated in the measure, i.e. all feedback words with z-scored values >0 were evaluated as more positive than the other words, while feedback words with z-scored values <0 were evaluated as more negative by the parent. We averaged these within-subject applicability*z-scored valence values across all feedback words per parent to create a general view score (van Houtum et al., Reference van Houtum, Wever, Janssen, van Schie, Will, Tollenaar and Elzinga2021) (Table 1). A higher score indicated a more positive parental view of the child.

Affective data analysis

We analyzed how mood varied as a function of feedback valence and group (depression yes/no) using multilevel modeling in R-4.0.4 (R Foundation, Vienna, Austria). Intermediate feedback was set as reference category to which the effects of criticism and praise were compared. We specified adolescents' mood after each feedback word as outcome, feedback valence categories on the first level (including random effects), and group on the second level:

$$\!\! \eqalign{{\rm Moo}{\rm d}_{ij} = & \gamma _{00} + \gamma _{01}( \hbox{Depression}) _j + \gamma _{10}( \hbox{Criticism}) _{ij} + \gamma _{20}( \hbox{Praise}) _{ij} \cr & + \! \! \gamma _{11}( \hbox{Depression}) _j( \hbox{Criticism}) _{ij} \! + \!\! \gamma _{21}( \hbox{Depression}) _j( \hbox{Praise}) _{ij} \cr & + \! \upsilon _{0j} + \upsilon _{1j}( \hbox{Criticism}) _{ij} + \upsilon _{2j}( \hbox{Praise}) _{ij} + \varepsilon _{ij}} $$

To ascertain whether DEP adolescents have more negative self-views, we included applicability (instead of mood) ratings as outcome.

To explore whether consistency of feedback words with adolescents' self-views differentially impacts mood across groups, applicability ratings were added on the first level (including random effects) to the mood model:

$$\eqalign{& {\hbox{Mood}}_{ij} = \gamma _{00} + \gamma _{01}( \hbox{Depression}) _j + \gamma _{10}( \hbox{Criticism}) _{ij} + \gamma _{20}( \hbox{Praise}) _{ij} \cr & \qquad\qquad\quad \ + \gamma _{11}( \hbox{Depression}) _j( \hbox{Criticism}) _{ij} + \gamma _{21}( \hbox{Depression}) _j( \hbox{Praise}) _{ij} \cr & \qquad\qquad\quad \ + \gamma _{30}( \hbox{Applicability}) _{ij} + \gamma _{31}( \hbox{Depression}) _j( \hbox{Applicability}) _{ij} \cr & \qquad\qquad\quad \ + \gamma _{40}( \hbox{Criticism} \, {\ast} \, \hbox{Applicability}) ij + \gamma _{50}( Praise \, {\ast} \, \hbox{Applicability}) _{ij} \cr & \qquad\qquad\quad \ + \gamma _{41}( \hbox{Depression}) _j( \hbox{Criticism} \, {\ast} \, \hbox{Applicability}) _{ij} \cr & \qquad\qquad\quad \ + \gamma _{51}( \hbox{Depression}) _j( \hbox{Praise} \, {\ast} \, \hbox{Applicability}) _{ij} \cr & \qquad\qquad\quad \ + \upsilon _{0j} + \upsilon _{1j}( \hbox{Criticism}) _{ij} + \upsilon _{2j}( \hbox{Praise}) _{ij} + \upsilon _{3j}( \hbox{Applicability}) _{ij} + \varepsilon _{ij}} $$

To explore whether the impact of parental feedback on adolescents' mood is dependent on parents' general view, general view scores were added on the second level:

$$\eqalign{{\hbox{Mood}}_{ij} = & \; \gamma _{00} + \gamma _{01}( \hbox{Depression}) _j + \gamma _{02}( \hbox{Parents}{\rm ^{\prime}}\;{ \hbox{general}}\;{\rm view}) _j\gamma _{10}( \hbox{Criticism}) _{ij} \cr & \quad + \gamma _{20}( \hbox{Praise}) _{ij}\gamma _{03}( \hbox{Depression}) \;( \hbox{Parents}{\rm ^{\prime}}\;{\hbox{general}}\;{\hbox{view}}) _j \cr & \quad + \gamma _{11}( \hbox{Depression}) _j( {\rm Criticism}) _{ij} + \gamma _{12}( \hbox{Parents}{\rm ^{\prime}}\;{\hbox{general}}\;{\hbox{view}}) _j( \hbox{Criticism}) _{ij} \cr & \quad + \gamma _{21}( \hbox{Depression}) _j( {\rm Praise}) _{ij} + \gamma _{22}( \hbox{Parents}{\rm ^{\prime}}\;{\hbox{general}}\;{\hbox{view}}) _j( {\hbox{Praise}}) _{ij} \cr & \quad + \gamma _{13}( \hbox{Depression}) _j( \hbox{Parents}{\rm ^{\prime}}\;{\hbox{general}}\;{\hbox{view}}) _j( \hbox{Criticism}) _{ij} \cr & \quad + \gamma _{23}( \hbox{Depression}) _j( \hbox{Parents}{\rm ^{\prime}}\;{\hbox{general}}\;{\hbox{view}}) _j( \hbox{Praise}) _{ij} \cr & \quad + \upsilon _{0j} + \upsilon _{1j}( \hbox{Criticism}) _{ij} + \upsilon _{2j} + ( \hbox{Praise}) _{ij} + \varepsilon _{ij}} $$

All continuous variables were z-scored at the sample level. χ² tests were used to test for significance of effects.

fMRI data acquisition and analysis

We acquired MRI images using a Philips Achieva 3.0-Tesla scanner (Philips Medical Systems, Best, NL) equipped with a SENSE-32 whole-head coil. We collected functional scans with T2*-weighted echo-planar imaging sequence [TR/TE: 2200/30 ms; flip angle: 80°; 38 transverse slices (anterior-to-posterior); FOV: 220 × 220 × 114.68 mm; voxel size: 2.75 mm³], see Supplement 5 for further details.

fMRI data were preprocessed and analyzed using SPM12 (Wellcome Trust Centre for Neuroimaging, London, UK), following standard procedures including spatial normalization using the DARTEL-toolbox (Ashburner, Reference Ashburner2007) (Supplement 5). Next, we defined a general linear model (GLM) including three separate regressors for onsets of criticism, praise, and intermediate feedback (modeled for 2500 ms), and one onset regressor of no interest for the mood question [modeled for the duration questions were displayed (self-paced)]. DEP adolescents answered mood questions significantly faster [M(s.d.) = 1720(984) ms, range: 460–7961) than HCs [M(s.d.) = 1906(969) ms, range: 395–7903] [t(1741) = 5.43, p < 0.001]. The GLM further included six motion regressors accounting for head motion (realignment parameters). For each subject, t-contrasts were generated to compare criticism and praise to each other and to intermediate feedback.

We compared activation patterns across groups in a priori preregistered regions of interests (ROIs). For the criticism v. praise/intermediate feedback contrasts, we looked at activity in bilateral dACC, sgACC, amygdala, AI, and right TPJ. For the praise v. criticism/intermediate contrasts, we looked at activity in bilateral VS and right TPJ. We created an anatomical ROI of bilateral dACC previously used by Dedovic, Slavich, Muscatell, Irwin, and Eisenberger (Reference Dedovic, Slavich, Muscatell, Irwin and Eisenberger2016). We obtained anatomical ROIs of bilateral sgACC, amygdala, AI, and VS from Silk et al. (Reference Silk, Sequeira, Jones, Lee, Dahl, Forbes and Ladouceur2022). Furthermore, we created an independent functional ROI of right TPJ [i.e. 8-mm sphere MNI-space surrounding peak voxel coordinates (x = 56, y = −42, z = 16) previously found by van Schie, Chiu, Rombouts, Heiser, and Elzinga (Reference van Schie, Chiu, Rombouts, Heiser and Elzinga2020) in response to criticism, using this paradigm in borderline personality disorder patients]. Parameter estimates for each ROI were extracted and averaged across all voxels per feedback valence using MarsBar toolbox implemented in SPM12. We used independent t-tests (two-tailed) to test for significance of each contrast of interest in these ROIs. We corrected for multiple comparisons by applying Bonferroni correction for the number of ROIs per analysis (i.e. criticism contrasts: p < 0.05/5; praise contrasts: p < 0.05/2).

We explored whether additional brain regions were differentially involved in the processing of parental feedback across groups using exploratory whole-brain analyses. Subject-specific contrast images were submitted to group-level random effects analyses using independent t-tests, which were corrected for multiple comparisons as preregistered using Family-wise Error cluster-correction at p < 0.05 (cluster-forming threshold of p < 0.001).

To explore how neural responses to parental feedback varied as a function of self-rated applicability, we defined a similar GLM, in which feedback regressors were parametrically modulated by applicability ratings. We generated first-level t-contrasts which were entered in a flexible factorial ANOVA design with applicability per valence as within-subject factor (three levels: negative, intermediate, and positive) and depression as group factor (two levels: yes/no) to examine differences in BOLD-responses between groups with respect to the main effect of applicability, and the feedback valence*applicability interaction (Gläscher & Gitelman, Reference Gläscher and Gitelman2008).

To explore group differences associated with parents' general view of the adolescent, we ran independent t-tests on all feedback contrasts, with a general view score regressor added as interaction term.