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Psychological Resilience as a Predictor of Symptom Severity in Adolescents With Poor Recovery Following Concussion

Published online by Cambridge University Press:  03 May 2019

Christianne Laliberté Durish ,
Keith Owen Yeates  and
Brian L. Brooks
Christianne Laliberté Durish*
Affiliation:
Department of Psychology, University of Calgary, Calgary, Alberta
Keith Owen Yeates
Affiliation:
Department of Psychology, University of Calgary, Calgary, Alberta
Brian L. Brooks
Affiliation:
Department of Psychology, University of Calgary, Calgary, Alberta
*
Correspondence and reprint requests to: Christianne Laliberté Durish, Department of Psychology, University of Calgary, 2500 University Drive N.W., Calgary, AB, T2N 1N4. E-mail: christianne.lalibert@ucalgary.ca
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Abstract

Objectives: Examine the mediating effects of anxiety and depressive symptoms on the relationship between psychological resilience and post-concussive symptoms (PCS) in children with poor recovery following concussion. Participants and Methods: Adolescents (N=93), ages 13 to 18 years, were assessed at a neuropsychology screening clinic at a children’s hospital. They sustained concussions more than 1 month before the clinic visit (median time since injury=5.1 months; range=42–473 days) and were seen on the basis of poor recovery (i.e., presence of persistent PCS and complaints of cognitive problems). Self-reported psychological resilience was measured using the 10-item version of the Connor-Davidson Resilience Scale; self- and parent-reported anxiety and depressive symptoms were measured using the Behaviour Assessment System for Children – Second Edition; and self- and parent-reported PCS were measured using the Post-Concussion Symptom Inventory. All variables were measured concurrently. Regression-based mediation analyses were conducted to examine anxiety and depressive symptoms as mediators of the relationship between psychological resilience and PCS. Results: Psychological resilience significantly predicted self-reported PCS. Self-reported anxiety and depressive symptoms significantly mediated the relationship between resilience and self-reported PCS, and parent-reported child depressive symptoms significantly mediated the relationship between resilience and self- and parent-reported PCS. Conclusions: Psychological resilience plays an important role in recovery from concussion, and this relationship may be mediated by anxiety and depressive symptoms. These results help shed light on the mechanisms of the role of psychological resilience in predicting PCS in children with prolonged symptom recovery. (JINS, 2019, 25, 346–354)

Keywords

ConcussionPediatricMild traumatic brain injuryHardinessPost-concussive symptomsChild
Type
Regular Research
Information
Journal of the International Neuropsychological Society , Volume 25 , Issue 4 , April 2019 , pp. 346 - 354
Copyright
Copyright © The International Neuropsychological Society, 2019. 

INTRODUCTION

Concussion is very common among children and adolescents. Over half a million children younger than 14 years of age present to the emergency department with a concussion each year (Bazarian et al., Reference Bazarian, Mcclung, Shah, Cheng, Flesher and Kraus2005). An array of physical, cognitive, and emotional/behavioral sequelae, known as post-concussive symptoms (PCS), are often present following a concussion. These symptoms are expected to resolve within approximately 1–3 months post-injury in most cases (Barlow et al., Reference Barlow, Crawford, Stevenson, Sandhu, Belanger and Dewey2010); however, 15–30% of children with concussion experience persistent PCS that can last far beyond this expected recovery period (Babcock et al., Reference Babcock, Byczkowski, Wade, Ho, Mookerjee and Bazarian2013; Barlow et al., Reference Barlow, Crawford, Stevenson, Sandhu, Belanger and Dewey2010; Grool et al., Reference Grool, Aglipay, Momoli, Meehan, Freedman and Yeates2016; Zemek et al., Reference Zemek, Barrowman, Freedman, Gravel, Gagnon and McGahern2016). Prolonged symptom recovery contributes to lower health related quality of life in this population (Fineblit, Selci, Loewen, Ellis, & Russell, Reference Fineblit, Selci, Loewen, Ellis and Russell2016). Furthermore, concussion in children and youth accounts for over $1 billion in annual healthcare costs in the United States (Graves, Rivara, & Vavilala, Reference Graves, Rivara and Vavilala2015). These costs can be further amplified by additional treatment-seeking for persistent PCS. Thus, understanding factors that help account for persistent symptoms in children and adolescents with concussion has become a critical research focus.

Both injury and non-injury factors are implicated in the persistence of PCS. Injury factors, including mechanism of injury, duration of loss of consciousness, duration of post-traumatic amnesia, and positive neuroimaging findings are important to study in their relation to PCS; however, their contribution to predicting symptoms tends to be significant primarily during the acute phase of recovery (Babcock et al., Reference Babcock, Byczkowski, Wade, Ho, Mookerjee and Bazarian2013; McNally et al., Reference McNally, Bangert, Dietrich, Nuss, Rusin, Wright and Yeates2013, Olsson et al., Reference Olsson, Lloyd, Lebrocque, McKinlay, Anderson and Kenardy2013; Taylor et al., Reference Taylor, Dietrich, Nuss, Wright, Rusin, Bangert and Yeates2010; Yeates et al., Reference Yeates, Kaizar, Rusin, Bangert, Dietrich, Nuss and Taylor2012). Therefore, non-injury factors (i.e., psychosocial and/or environmental correlates that pre-date or co-occur with the injury) have received increased attention due to their importance in predicting persistent PCS. Such factors include being of female sex or adolescent age at the time of injury, pre-injury learning problems, pre-injury behavioral adjustment and psychiatric problems, and poor coping skills (Ponsford et al., Reference Ponsford, Willmont, Rothwell, Cameron, Ayton, Nelms and Ng1999; Taylor et al., Reference Taylor, Dietrich, Nuss, Wright, Rusin, Bangert and Yeates2010; Woodrome et al., Reference Woodrome, Yeates, Taylor, Rusin, Bangert, Dietrich and Wright2011; Yeates et al., Reference Yeates, Kaizar, Rusin, Bangert, Dietrich, Nuss and Taylor2012). An additional non-injury factor gaining increased attention is psychological resilience.

Psychological resilience is conceptualized as interpersonal qualities that enable one to successfully adapt to adverse events, such as illness or injury. It is comprised of factors such as tolerance of negative affect, positive acceptance of change, perceived control, and personal competence (Conner & Davidson, Reference Connor and Davidson2003). Recently, the construct of resilience has piqued the interest of researchers wishing to study predictors of the outcomes of medical trauma, including concussion. Several studies in adults have demonstrated high psychological resilience to be related to fewer PCS, fewer depressive symptoms, and less fatigue following concussion in adults (Losoi et al., Reference Losoi, Silverberg, Waljas, Turunen, Rosti-Otajarvi, Helminen and Iverson2015; Merritt, Lange, & French, Reference Merritt, Lange and French2015; Sullivan, Edmed, Allan, Smith, & Karlsson, Reference Sullivan, Edmed, Allan, Smith and Karlsson2015), although some research has not supported this relationship (e.g., McCauley et al., Reference McCauley, Wilde, Miller, Frisby, Garaza, Varghese and McCarthy2013).

Recently, resilience has been shown to be related to fewer PCS in children and adolescents long after injury (i.e., 2.5 years; Laliberté Durish, Brooks, & Yeates, Reference Laliberté Durish, Yeates and Brooks2018). Importantly, psychological resilience has been identified as a dynamic, modifiable construct that is amenable to change through intervention (Johnston et al., Reference Johnston, Porteous, Crilly, Burton, Elliot, Iversen and Black2015; Steinhardt & Doblier, Reference Steinhardt and Dolbier2008); thus, it seems an important construct to examine to better understand the outcomes of concussion. Given the modifiability of resilience and its relation to outcome in concussion, further study of its role in children with poor recovery following concussion is warranted. However, our understanding of the mechanisms of the relationship of resilience to concussion outcomes remains unclear.

Anxiety and depression are other factors that have been found to predict persistent symptoms in children and adolescents who are slow to recover from concussion (Grubenhoff et al., Reference Grubenhoff, Currie, Comstock, Juarez-Colnga, Bajaj and Kirkwood2016; Laliberté Durish, Persevereff, & Yeates, Reference Laliberté Durish, Persevereff and Yeates2018; Stazyk et al., Reference Stazyk, DeMatteo, Moll and Missiuna2017; Wood, O’Hagan, Williams, McCabe, & Chadwick, Reference Wood, O’Hagan, Williams, McCabe and Chadwick2014;). For example, the risk for persistent PCS has been found to be associated with increased anxiety before or shortly after injury in children with concussion who were followed longitudinally (Grubenhoff et al., Reference Grubenhoff, Currie, Comstock, Juarez-Colnga, Bajaj and Kirkwood2016). Furthermore, the role of high resilience in mitigating the development of psychological symptoms, such as anxiety and depression, following adversity is well documented (e.g., Campbell-Sills, Cohan, & Stein, Reference Campbell-Sills, Cohan and Stein2006; Pietrzak, Johnson, Goldstein, Malley, & Southwick, Reference Pietrzak, Johnson, Goldstein, Malley and Southwick2009; Poole, Dobson, & Pusch, Reference Poole, Dobson and Pusch2017; Rainey, Petrey, Reynolds, Agtarap, & Warren, Reference Rainey, Petrey, Reynolds, Agtarap and Warren2014; Schulz et al., Reference Schulz, Becker, Van der Auwera, Barnow, Appel, Mahler and Grabe2014). Given support for the relationship between psychological resilience and both anxiety/depressive symptoms and persistent PCS, as well as the relationship between anxiety/depressive symptoms and persistent PCS, we hypothesized that anxiety/depressive symptoms might act as a mediator of the relationship between resilience and PCS in children with prolonged symptom recovery.

The aim of the current study was to thus elucidate the relationship between psychological resilience and persistent PCS by examining the role of anxiety/depressive symptoms as a potential mediator. We predicted that psychological resilience would be negatively associated with PCS, such that lower self-reported psychological resilience would predict greater self- and parent-reported PCS. We also predicted that both anxiety and depressive symptoms would act as mediators of this relationship, such that lower psychological resilience would predict higher self- and parent-reported anxiety and depressive symptoms, which would correspond with greater self- and parent-reported PCS.

METHODS

Participants

Adolescents (N=93), ages 13–18 years, were consecutively referred to the Alberta Children’s Hospital Neuropsychology Service for a neuropsychological screening of their neurocognitive and psychological functioning following a concussion. All participants sustained injuries more than 1 month before assessment and were referred by a nurse practitioner, neurologist, or physiatrist on the basis of poor recovery (i.e., persistent PCS) and complaints of cognitive problems. The diagnosis of concussion (or mild traumatic brain injury [TBI]) was based on the World Health Organization (WHO) definition (Carroll, Cassidy, Holm, Kraus, & Coronado, Reference Carroll, Cassidy, Holm, Kraus and Coronado2004), and was confirmed by a nurse practitioner at the initial intake clinical assessment via review of medical records and/or family report.

Persistent PCS was defined as the presence of one or more symptoms reported to be associated with the concussion that persist for longer than 1 month post-injury, consistent with the International Classification of Diseases for post-concussion syndrome (WHO, 1992). Symptom severity was initially evaluated as part of the intake clinical assessment by a nurse practitioner using the Post-Concussion Symptom Inventory (PCSI), to assess ongoing symptoms for clinical purposes, but that data were not available for research purposes and are not included in analyses. Complaints of cognitive problems were based on child or parent report of problems with attention, thinking speed, memory, or executive functioning post-concussion to the nurse practitioner.

Inclusion criteria for the current study were sustainment of a concussion, diagnosed by a health professional, no less than 1 month before testing. Children with a record of positive neuroimaging findings (i.e., complicated mild TBI) were excluded from analyses. To conform with age restrictions of the measures used, children less than 13 years of age were also excluded from analyses. Children with a history of premorbid learning, attention, or psychological concerns were not excluded from participation due to the high degree of co-occurrence of these problems in this population (Horris, Elmer, & Valovich McLeod, Reference Horris, Elmer and Valovich McLeod2017) and to increase generalizability of the findings.

Measures

Post-concussive symptoms

PCS were measured using the PCSI (Gioia, Janusz, Isquith, & Vincent, Reference Gioia, Janusz, Isquith and Vincent2008; Gioia, Schneider, Vaughan, & Isquith, Reference Gioia, Schneider, Vaughan and Isquith2009). The PCSI is a 26-item measure of severity of PCS. Participants are asked rate the severity of current symptoms (i.e., yesterday and today) on a 7-point scale (0=Not a problem, 3=Moderate problem, 6=Severe problem), with total possible scores ranging from 0 to 156 (higher scores are indicative of greater severity of PCS). Children completed the self-report form and their parents completed the parent-report form. The PCSI has been shown to have moderately high test–retest reliability, strong internal consistency, and good convergent validity (Sady et al., Reference Sady, Vaughan and Gioia2014). PCS are multidimensional, and include physical, cognitive, emotional, and fatigue related symptoms (Sady et al., Reference Sady, Vaughan and Gioia2014).

Given the high correlation between emotional symptom reporting on the PCSI and symptom reporting on the Behaviour Assessment System for Children – Second Edition (BASC-2) Anxiety (self: r=.71; p<.001; parent: r=.55; p<.001) and Depression (self: r=.71; p<.001; parent: r=.61; p < .001) subscales, emotional symptom scores on the PCSI (i.e., items 13, 14, 15, 16 on the self-report and items 12, 13, 14, 15 on the parent-report) were subtracted from the PCSI total score to minimize overlap between items on the PCSI and on the BASC-2 Anxiety and Depression subscales. Thus, all analyses used total scores minus emotional symptoms from both the self- and parent-report versions of the PCSI.

Resilience

Resilience was measured using the 10-item version of the Connor-Davidson Resilience Scale (CD-RISC; Connor & Davidson, Reference Connor and Davidson2003; Campbell-Sills & Stein, Reference Campbell-Sills and Stein2007). The CD-RISC is a self-report rating scale that measures factors related to resilience, such as personal competence, tenacity, tolerance of negative affect, and positive acceptance of change. Each item is measured on a 5-point scale (0=Not true at all, 2=Sometimes true, 4=True nearly all the time), with total possible scores ranging from 0 to 40 (higher scores indicative of greater resilience). The CD-RISC demonstrates satisfactory reliability and validity in the general population, as well as clinical samples (Connor & Davidson, Reference Connor and Davidson2003), and satisfactory validity in a pediatric medical sample (Laliberté Durish, Yeates, & Brooks, Reference Laliberté Durish, Yeates and Brooks2017). Total raw scores for the CD-RISC were included in the analyses.

Anxiety and depressive symptoms

Anxiety and depressive symptoms were measured using the self- and parent-report versions of the BASC-2 (Reynolds & Kamphaus, Reference Reynolds and Kamphaus2004). The BASC-2 is a measure of behavioral and psychological symptoms in children and adolescents. Both versions of the BASC-2 contain items measured on a 4-point scale (i.e., Never, Sometimes, Often, Almost Always). The self-report version also contains items rated as true/false. Standardized scores (i.e., age and sex-adjusted T scores with a mean of 50 and SD of 10) for the Anxiety and Depression subscales were included in the analyses, with higher scores indicative of greater problems (cutoff for clinical significance=70). The BASC-2 has demonstrated satisfactory reliability and validity in pediatric populations (Reynolds & Kamphaus, Reference Reynolds and Kamphaus2004).

Procedure

The measures included in the current study were administered as part of a clinical neuropsychological assessment battery. Participants underwent approximately 90 minutes of neuropsychological testing, completed in a designated testing space in the clinic with a trained psychometrist (under the supervision of a neuropsychologist), and parents completed questionnaires, as well as a demographic and injury information form (e.g., parental education, pre-injury attention/learning concerns, mechanism of injury), in a separate space. All participants provided signed parental consent and child assent for use of their data for research purposes upon consenting to the clinical assessment, as approved by the Research Ethics Board.

Statistical Analyses

Statistical analyses were conducted using IBM SPSS Statistics Software, Version 24 (IBM Corp., 2016). Initial hierarchical regression analyses were conducted to examine the prediction of self- and parent-reported PCS by psychological resilience, over and above the effects of age and sex, to control for the effects of age and sex on PCS (e.g., see Taylor et al., Reference Taylor, Dietrich, Nuss, Wright, Rusin, Bangert and Yeates2010). Thereafter, mediation analyses were conducted using the PROCESS macro (Hayes, Reference Hayes2013) with the CD-RISC entered as the predictor variable, self- and parent-report BASC-2 Anxiety and Depression subscales examined separately as mediator variables, and self- and parent-report PCS examined separately as dependent variables.

Age and sex were also included in each of the mediation models as covariates. Proposed effect size measures for mediation (Preacher & Kelley, Reference Preacher and Kelley2011) have not been validated for models that contain covariates. Therefore, standardized betas are reported as measures of effect size (i.e., representing change in outcome variable for every 1 SD change in the mediator variable), gauging the indirect effect relative to variation in the predictor and outcome variables not accounted for by the covariates.

RESULTS

Descriptive statistics for demographic and injury variables (i.e., age, sex, ethnicity, maternal and paternal education, pre-morbid problems, and injury factors) are presented in Table 1. The sample was composed of 52 females and 41 males who were of primarily Caucasian ethnicity and were, on average, from families of higher socioeconomic status (i.e., college-educated mothers). Time since injury ranged from 42 to 473 days, with an average time since injury of approximately 6 months. Descriptive statistics for predictor (i.e., CD-RISC, self- and parent-report BASC-2 Anxiety and Depression subscales), outcome variables (i.e., self- and parent-report PCSI scores), and PCSI domain scores encompassed by the total score (i.e., physical, cognitive, fatigue), as well as analyses of sex differences on each of the variables, are presented in Table 2.

Table 1 Demographic characteristics of study sample

Table 2 Descriptive statistics of study measures

BASC-2=Behaviour Assessment System for Children – Second Edition (standardized scores for Anxiety and Depression sub-scales; SR=Self-Report, PR = Parent Report), CD-RSIC=Connor-Davidson Resilience Scale (10 item version; total raw score); PCSI=Post-Concussion Symptom Inventory (total raw score minus ratings on emotional symptom items).

*Significant group differences (p<.05).

Significant sex differences were present on self-reported depressive symptoms (t(91)=−2.16; p=.034), self-reported total PCS (t(91)=−2.78; p=.007), and self-reported physical PCS (t(90)=−2.41; p=.018) and cognitive PCS (t(90)=−3.04; p=.003), as well as parent-reported physical PCS (t(90)=−3.20; p=.002), with females reporting greater depressive symptoms and PCS. Correlations among study measures are presented in Table 3.

Table 3 Correlations among study measures

BASC-2=Behaviour Assessment System for Children – Second Edition (standardized scores for Depression and Anxiety sub-scales; SR=Self-Report, PR=Parent-Report); CD-RISC=Connor-Davidson Resilience Scale (10-item version, total raw score); PCSI=Post-Concussion Symptom Inventory (total raw score minus ratings on emotional symptoms).

* Significant (p<.05) after controlling for multiple comparisons (false discovery rate).

Hierarchical regression analyses demonstrated a significant effect of the contribution of age and sex on self-reported PCS (R 2=.08; p=.024), with a significant independent contribution of sex (t(90)=3.04; p=.003; females reported greater PCS). They also showed a significant effect of psychological resilience on self-reported PCS, over and above the effects of age and sex (β=−0.23; Δ R 2=.05; p=.022). Similar effects were not found for parent-reported PCS.

Significant mediation analyses are outlined in Figures 14. Of the eight models tested, the mediation effect was significant in four, with three of the four involving the same rater for PCS and for anxiety or depressive symptoms. Self-reported anxiety symptoms significantly mediated the relationship between psychological resilience and self-reported PCS (β=−0.20; 95% CI=−0.33 to −0.10). Self- and parent-reported depressive symptoms significantly mediated the relationship between psychological resilience and self-reported PCS (β=−0.18; 95% CI=−0.35 to −0.09 and β=−0.11; CI=−0.23 to −0.03, respectively). Parent-reported depressive symptoms also mediated the relationship between psychological resilience and parent-reported PCS (β=−0.12; 95% CI=−0.24 to −0.06). The prediction of self-reported PCS by psychological resilience was no longer significant when anxiety or depressive symptoms were entered into the model. In all models, psychological resilience significantly predicted anxiety/depressive symptoms (p ≤ .001), and in four of eight models, anxiety or depressive symptoms significantly predicted PCS (i.e., self-reported anxiety symptoms to self-reported PCS; self-reported depressive symptoms to self-reported PCS, parent-reported depressive symptoms to self-reported PCS, parent-reported depressive symptoms to parent-reported PCS; p ≤ .005).

Fig. 1 Mediation model depicting the relationship between psychological resilience and self-reported PCS mediated by self-reported anxiety symptoms, with age (Anxiety Symptoms: t(89)=0.44; p=.663; PCS: t(88)=−0.74; p=.458) and sex (Anxiety Symptoms: t(89)=−0.05; p=.963; PCS: t(88)=2.82*; p=.006) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on self-reported PCS through self-reported anxiety symptoms. *Significant effect (p<.05).

Fig. 2 Mediation model depicting the relationship between psychological resilience and self-reported PCS mediated by self-reported depressive symptoms, with age (Depressive Symptoms: t(89)=1.74; p=.086; PCS: t(88)=−1.26; p=.211) and sex (Depressive Symptoms: t(89)=1.85; p=.067; PCS: t(88)=1.96; p=.053) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on self-reported PCS through self-reported depressive symptoms. *Significant effect (p<.05).

Fig. 3 Mediation model depicting the relationship between psychological resilience and self-reported PCS mediated by parent-reported depressive symptoms, with age (Depressive Symptoms: t(88)=−0.22; p=.823; PCS: t(87)=−0.57; p=.571) and sex (Depressive Symptoms: t(88)=0.92; p=.362; PCS: t(87)=2.18*; p=.032) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on self-reported PCS through parent-reported depressive symptoms. *Significant effect (p<.05).

Fig. 4 Mediation model depicting the relationship between psychological resilience and parent-reported PCS mediated by parent-reported depressive symptoms, with age (Depressive Symptoms: t(88)=−0.23; p=.823; PCS: t(87)=0.31; p=.758) and sex (Depressive Symptoms: t(88)=0.92; p=.362; PCS: t(87)=1.62; p=.110) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on parent-reported PCS through parent-reported depressive symptoms. *Significant effect (p<.05).

DISCUSSION

Psychological resilience has been found to be an important predictor of persistent PCS in adults following concussion (Losoi et al., Reference Losoi, Silverberg, Waljas, Turunen, Rosti-Otajarvi, Helminen and Iverson2015; Merritt et al., Reference Merritt, Lange and French2015; Sullivan et al., Reference Sullivan, Edmed, Allan, Smith and Karlsson2015), but only one other study has examined this relationship in children (Laliberté Durish, Yeates, & Brooks, Reference Laliberté Durish, Yeates and Brooks2018). This study sought to contribute to the growing body of research regarding the role of psychological resilience in predicting poor outcome of pediatric concussion by elucidating the relationships among psychological resilience, anxiety/depressive symptoms, and PCS, to better understand potential mediators of poor outcome after concussion in adolescents.

Our results indicate that anxiety and depressive symptoms may indeed act as mediators of the relationship between psychological resilience and PCS, such that lower resilience predicted greater anxiety/depressive symptoms, which, in turn, predicted increased PCS in this population. Self-reported depressive symptoms may act as a more important mediator of the relationship between resilience and PCS given their significance in mediating parent-reported PCS, as opposed to self-reported anxiety symptoms, which only mediated child-reported PCS.

Although inclusion criteria for the study required a minimum time since injury of 1 month, the average time since injury was 6 months; thus, the current results are best interpreted as shedding light on the relationship between psychological resilience and persistent PCS in children with poor recovery following concussion. Moreover, the exclusion of emotional symptom items from the PCSI total scores minimized the extent to which item overlap may have accounted for significant mediation by anxiety and depressive symptoms. That is, anxiety and depressive symptoms mediated the relationship of psychological resilience to physical, cognitive, and fatigue-related PCS. These findings are in keeping with previous literature indicating that anxiety and depressive symptoms are predictive of physical, cognitive, and sleep symptoms following concussion (e.g., de Koning et al., Reference de Koning, Gareb, El Moumni, Scheenen, van der Horn, Timmerman and van der Naalt2016; Herrmann et al., Reference Herrmann, Rapoport, Rajaram, Chan, Kiss, Ma and Lanctot2009).

An interesting finding was the substantial change in the prediction of PCS by psychological resilience when anxiety and depressive symptoms were added to the model. Although psychological resilience significantly predicted self-reported PCS when anxiety and depressive symptoms were not included in the model, this predictive relationship was no longer significant when they were added as mediators. This finding suggests that, while resilience may be an important predictor of PCS, this may be because of the relationship of resilience to psychological distress more generally.

Our results have important implications for intervention research, suggesting that interventions that target anxiety and depressive symptoms may help to alleviate persistent PCS. Psychological resilience, however, may also play an important role in terms of intervention, given its relationship to psychological symptoms. Studies on the effectiveness of psychotherapy have provided empirical support for the importance of resilience factors, such as flexibility and optimism, in achieving positive outcomes (Duncan, Miller, Wampold, & Hubble, Reference Duncan, Miller, Wampold and Hubble2010). Thus, the current findings provide a more comprehensive understanding of psychological factors implicated in poor recovery following concussion and may help serve as a guide to the best treatment modalities.

Justification for the therapeutic application the current findings is provided by research showing that high resilience is predictive of fewer anxiety and depressive symptoms following exposure to trauma (Campbell-Sills et al., Reference Campbell-Sills, Cohan and Stein2006; Pietrzak et al., Reference Pietrzak, Johnson, Goldstein, Malley and Southwick2009; Poole et al., Reference Poole, Dobson and Pusch2017; Rainey et al., Reference Rainey, Petrey, Reynolds, Agtarap and Warren2014; Schulz et al., Reference Schulz, Becker, Van der Auwera, Barnow, Appel, Mahler and Grabe2014), that anxiety/depressive symptoms are predictive of outcome of concussion (Grubenhoff et al., Reference Grubenhoff, Currie, Comstock, Juarez-Colnga, Bajaj and Kirkwood2016; Stazyk et al., Reference Stazyk, DeMatteo, Moll and Missiuna2017, Laliberté Durish, Persevereff, & Yeates, Reference Laliberté Durish, Persevereff and Yeates2018; Wood et al., Reference Wood, O’Hagan, Williams, McCabe and Chadwick2014), and that psychological resilience is a predictor of PCS (Laliberté Durish, Yeates, & Brooks, Reference Laliberté Durish, Yeates and Brooks2018; Losoi et al., Reference Losoi, Silverberg, Waljas, Turunen, Rosti-Otajarvi, Helminen and Iverson2015; Merritt et al., Reference Merritt, Lange and French2015; Sullivan et al., Reference Sullivan, Edmed, Allan, Smith and Karlsson2015). However, given that our study did not use a longitudinal design, causal relationships cannot be proven; thus, the possibility of alternative causal relationships among anxiety, depressive symptoms, and PCS (i.e., greater PCS leads to increased anxiety or depressive symptoms) cannot be discounted.

Studies have shown an increased risk of anxiety and depressive symptoms following concussion (Hawley, Ward, Magnay, & Long, Reference Hawley, Ward, Magnay and Long2004; Luis & Mittenberg, Reference Luis and Mittenberg2002), suggesting that increased PCS may lead to greater anxiety/depressive symptomatology rather than the converse. Given the overlap that exists between depression and anxiety, and many PCS (e.g., fatigue), changes in one may affect changes in the other in a bidirectional manner (see Stein et al., Reference Stein, Howard, Rowhani-Rahbar, Rivara, Zatzick and McCarty2017). More research is needed to examine the causal relationships among these variables.

The results should be interpreted in light of several study limitations. First, and perhaps most importantly, the study was cross-sectional; thus, causal relationships between the three key variables (i.e., resilience, anxiety/depressive symptoms, and PCS) cannot be determined from the data. Second, only limited retrospective data were available regarding pre-morbid psychological symptoms or PCS, although a high proportion of children were reported to have pre-morbid learning and attention concerns, as well as a history of physical symptoms (i.e., headaches). While inclusion of children with these pre-morbid concerns increases generalizability of the findings, we cannot conclude that all symptoms reported by the participants were linked to their concussions. The limited sample size precluded examining the contribution of these variables in the analyses; however, premorbid factors may account for significant variance in the mediator and outcome variables. Relatedly, pre-injury resilience was not assessed; thus, we cannot assume that the concurrent ratings reflected a stable trait and were unchanged by the injury. Previous research suggests that resilience, while potentially modifiable (Steinhardt & Dolbier, Reference Steinhardt and Dolbier2008), is unlikely to change as a result of a single injury (Rainey et al., Reference Rainey, Petrey, Reynolds, Agtarap and Warren2014). However, no research to date has examined these relationships prospectively among children with concussion, limiting definitive conclusions in this regard.

Third, information on previous injuries was not collected. Given the potential impact of a history of multiple concussions on severity of PCS (Brooks et al., Reference Brooks, McKay, Mrazik, Barlow, Meeuwisse and Emery2013; Iverson et al., Reference Iverson, Gardner, Terry, Ponsford, Sills, Broshek and Solomon2017; Laliberté Durish, Yeates, & Brooks, Reference Laliberté Durish, Yeates and Brooks2018; Rieger et al., Reference Rieger, Lewandowski, Callahan, Spenceley, Truckenmiller, Gathke and Miller2013), the possibility of previous injuries accounting for variance in anxiety/depressive symptoms and PCS cannot be discounted. Fourth, the mediation effects were not significant when models were based on multi-informant ratings (e.g., self-report depressive symptoms mediating the relationship between psychological resilience and parent-reported PCS), except for the model involving parent-reported depressive symptoms and self-reported PCS; thus, shared rater variance may be driving some of the observed mediation effects. Fifth, given the lack of a comparison group (e.g., orthopedic injury), we are limited in interpreting the findings as specific to concussion rather than as potentially reflecting psychological factors related to sustaining an injury in general (e.g., post-traumatic stress disorder following a motor vehicle collision). Finally, the results must be interpreted in the context of a highly selective sample, (i.e., children who were seen in a clinical setting on the basis of poor recovery). Thus, the results cannot be generalized to all youth who sustain concussion, but instead are restricted to those with poor recovery.

In conclusion, the results of this study suggest a potential mechanism underlying the relationship between psychological resilience and PCS. That is, low psychological resilience is associated with greater anxiety and depressive symptoms, which, in turn, predicts a combination of physical, cognitive, and fatigue-related PCS. Future studies should use a longitudinal design to further explore causal relationships among these variables. Additionally, future studies should examine these relationships within specific domains of PCS (i.e., physical, cognitive, sleep, mood) to better parse out the specific symptoms that may be impacted by resilience and anxiety/depressive symptoms. Nonetheless, the current findings have important potential implications for intervention for children suffering from persistent symptoms after concussion.

ACKNOWLEDGMENTS

Special thanks to the families who participated in this research. The authors thank Helen Carlson PhD and Shane Virani MSc for their time and expertise with data management, as well as (alphabetically) Kalina Askin, Christina Bigras, Dominique Bonneville, Shauna Bulman, Claire David, Hussain Daya, Lisa Goodman, Andrea Jubinville, Courtney Habina, Michelle Huie, Shelby MacPhail, Lonna Mitchell, Carlie Montpetit, Victoria Purcell, Alysha Rajaram, Jasmine Santos, Kalina Slepicka, Emily Tam, Julie Wershler, and Nikola Zivanovic for help with data entry into the BrainChild database program. Funding: Christianne Laliberté Durish received funding from Alberta Innovates Health Solutions (AIHS) and Alberta Children’s Hospital Research Institute (ACHRI) in the form of graduate studentships. Brian Brooks acknowledges support from the Neurosciences Program at the Alberta Children’s Hospital for database management and salary support from the CIHR Embedded Clinical Research Award. Keith Yeates is supported by the Robert and Irene Ward Chair in Pediatric Brain Injury from the Alberta Children’s Hospital Foundation. Conflict of Interest: Brian Brooks receives royalties for the sales of the Pediatric Forensic Neuropsychology textbook (2012, Oxford University Press) and three pediatric neuropsychological tests [Child and Adolescent Memory Profile (ChAMP, Sherman and Brooks, 2015, PAR Inc.), Memory Validity Profile (MVP, Sherman and Brooks, 2015, PAR Inc.), and Multidimensional Everyday Memory Ratings for Youth (MEMRY, Sherman and Brooks, 2017, PAR Inc.)]. He previously received in-kind support (free test credits) from the publisher of a computerized cognitive test (CNS Vital Signs, Chapel Hill, North Carolina) for prior studies. Keith Yeates receives royalties for book sales from Guilford Press and Cambridge University Press, and occasionally serves as a paid expert in forensic cases. None of the authors have a financial interest in any measures used in the present study.

References

REFERENCES

Babcock, L., Byczkowski, T., Wade, S.L., Ho, M., Mookerjee, S., & Bazarian, J.J. (2013). Predicting postconcussion syndrome after mild traumatic brain injury in children and adolescents who present to the emergency department. Journal of the American Medical Association Pediatrics, 167(2), 156161.Google ScholarPubMed
Barlow, K.M., Crawford, S., Stevenson, A., Sandhu, S.S., Belanger, F., & Dewey, D. (2010). Epidemiology of postconcussion syndrome in pediatric mild traumatic brain injury. Pediatrics, 126(2), e374e381.CrossRefGoogle ScholarPubMed
Bazarian, J.J., Mcclung, J., Shah, M.N., Cheng, Y.T., Flesher, W., & Kraus, J. (2005). Mild traumatic brain injury in the United States, 1998-2000. Brain Injury, 19(2), 8591.CrossRefGoogle ScholarPubMed
Brooks, B.L., McKay, C.D., Mrazik, M., Barlow, K.M., Meeuwisse, W.H., & Emery, C.A. (2013). Subjective, but not objective, lingering effects of multiple past concussions in adolescents. Journal of Neurotrauma, 30, 14691475.CrossRefGoogle Scholar
Campbell-Sills, L., Cohan, S.L., & Stein, M.B. (2006). Relationship of resilience to personality, coping and psychiatric symptoms in young adults. Behaviour Research & Therapy, 44, 585599.CrossRefGoogle ScholarPubMed
Campbell-Sills, L., & Stein, M.B. (2007). Psychometric analysis and refinement of the Connor-Davidson Resilience Scale (CD-RISC): Validation of a 10-item measure of resilience. Journal of Traumatic Stress, 20(6), 10191028.CrossRefGoogle ScholarPubMed
Carroll, L.J., Cassidy, J.D., Holm, L., Kraus, J., & Coronado, V.G. (2004). Methodological issues and research recommendations for mild traumatic brain injury: The WHO Collaborating Center Task Force on Mild Traumatic Brain Injury. Journal of Rehabilitation Medicine, 43, 113125. doi:10.1080/16501960410023877CrossRefGoogle Scholar
Connor, K.M., & Davidson, J.R. (2003). Development of a new resilience scale: The Connor-Davidson Resilience Scale (CD-RISC). Depression and Anxiety, 18, 7682.CrossRefGoogle Scholar
de Koning, M.E., Gareb, B., El Moumni, M., Scheenen, M.E., van der Horn, H.J., Timmerman, M.E., . . . van der Naalt, J. (2016). Subacute posttraumatic complaints and psychological distress in trauma patients with or without mild traumatic brain injury. Injury, 47, 20412047.CrossRefGoogle ScholarPubMed
Duncan, B.L., Miller, S.D., Wampold, B.E., & Hubble, M.A. (2010). The heart and soul of change: Delivering what works in therapy, Second Edition. Washington, DC: American Psychological Association.CrossRefGoogle Scholar
Fineblit, S., Selci, E., Loewen, H., Ellis, M., & Russell, K. (2016). Health-related quality of life after pediatric mild traumatic brain injury/concussion. A systematic review. Journal of Neurotrauma, 33(17), 15611568.CrossRefGoogle ScholarPubMed
Gioia, G.A., Janusz, J., Isquith, P., & Vincent, D. (2008). Psychometric properties of the parent and teacher Post-Concussion Symptom inventory (PCSI) for children and adolescents. Journal of the International Neuropsychological Society, 14(Suppl. 1), 204.Google Scholar
Gioia, G.A., Schneider, J.C., Vaughan, C.G., & Isquith, P.K. (2009). Which symptom assessments and approaches are uniquely appropriate for paediatric concussion? British Journal of Sports Medicine, 43(Suppl. 1), i13i22.CrossRefGoogle ScholarPubMed
Grool, A.M., Aglipay, M., Momoli, F., Meehan, W.P., Freedman, S.B., Yeates, K.O., . . . Pediatric Emergency Research Canada (PERC) Concussion Team. (2016). Association between early participation in physical activity following acute concussion and persistent postconcussive symptoms in children and adolescents. Journal of the American Medical Association, 316(23), 25042514.CrossRefGoogle ScholarPubMed
Graves, J.M., Rivara, F.P., & Vavilala, M.S. (2015). Health care costs 1 year after pediatric traumatic brain injury. American Journal of Public Health, 105(10), e35e41.CrossRefGoogle ScholarPubMed
Grubenhoff, J.A. Currie, D., Comstock, R.D., Juarez-Colnga, E., Bajaj, L., & Kirkwood, M.W. (2016). Psychological factors associated with delayed symptom resolution in children with concussion. Journal of Pediatrics, 174, 2732.CrossRefGoogle ScholarPubMed
Hawley, C.A., Ward, A.B., Magnay, A.R., & Long, J. (2004). Outcomes following childhood head injury: A population study. Journal of Neurology, Neurosurgery, and Psychiatry, 75(5), 737742.CrossRefGoogle ScholarPubMed
Hayes, A.F. (2013). Methodology in the social sciences. Introduction to mediation, moderation, and conditional process analysis: A regression-based approach. New York: Guilford Press.Google Scholar
Herrmann, N., Rapoport, M.J., Rajaram, R.D., Chan, F., Kiss, A., Ma, A.K., . . . Lanctot, K.L. (2009). Factor analysis of the Rivermead Post-Concussion Symptoms Questionnaire in mild-to-moderate traumatic brain injury patients. Journal of Neuropsychiatry and Clinical Neurosciences, 21(2), 181188.CrossRefGoogle ScholarPubMed
Horris, H.B., Elmer, C., & Valovich McLeod, T.C. (2017). Premorbid diagnosis of attention deficit disorder and the association of concussion risk and prolonged recovery: An evidence-based report. Athletic Training and Sports Health Care, 9(1), 3944.CrossRefGoogle Scholar
IBM Corp. (2016). IBM SPSS Statistics for Windows, Version 24.0. Armonk, NY: IBM Corp.Google Scholar
Iverson, G.L., Gardner, A.J., Terry, D.P., Ponsford, J.L., Sills, A.K., Broshek, D.K., & Solomon, G.S. (2017). Predictors of clinical recovery from concussion: A systematic review. British Journal of Sports Medicine, 51, 941948.CrossRefGoogle ScholarPubMed
Johnston, M.C., Porteous, T., Crilly, M.A., Burton, C.D., Elliot, A., Iversen, L., . . . Black, C. (2015). Physical disease and resilient outcomes: A systematic review of resilience definitions and study methods. Psychosomatics, 56, 168180.CrossRefGoogle ScholarPubMed
Laliberté Durish, C., Persevereff, R.S., & Yeates, K.O. (2018). Depression and depressive symptoms in pediatric traumatic brain injury: A scoping review. Journal of Head Trauma Rehabilitation, 33(3), E18E30.CrossRefGoogle ScholarPubMed
Laliberté Durish, C., Yeates, K.O., & Brooks, B.L. (2017). Convergent and divergent validity for a measure of psychological resilience in children with mild traumatic brain injury [abstract]. In: Final Program Forty Fifth Annual Meeting International Neuropsychological Society. Journal of the International Neuropsychological Society, 23(S1), 294.Google Scholar
Laliberté Durish, C., Yeates, K.O., & Brooks, B.L. (2018). Psychological resilience as a predictor of persistent post-concussive symptoms in children with single and multiple concussion. Journal of the International Neuropsychological Society, 24, 759768.CrossRefGoogle ScholarPubMed
Losoi, H., Silverberg, N.D., Waljas, M., Turunen, S., Rosti-Otajarvi, E., Helminen, M., . . . Iverson, G.L. (2015). Reslience is associated with outcome from mild traumatic brain injury. Journal of Neurotrauma. 32, 942949. doi:10.1089/neu.2014.43799CrossRefGoogle Scholar
Luis, C.A., & Mittenberg, W. (2002). Mood and anxiety disorders following pediatric traumatic brain injury: A prospective study. Journal of Clinical and Experimental Neuropsychology, 24(3), 270279.CrossRefGoogle ScholarPubMed
McCauley, S.R., Wilde, E.A., Miller, E.R., Frisby, M.L., Garaza, H.M., Varghese, R., . . . McCarthy, J.J. (2013). Preinjury resilience and mood as predictors of early outcome following mild traumatic brain injury. Journal of Neurotrauma, 30, 642652.CrossRefGoogle ScholarPubMed
McNally, K.A., Bangert, B., Dietrich, A., Nuss, K., Rusin, J., Wright, M., . . . Yeates, K.O. (2013). Injury versus non-injury factors as predictors of post-concussive symptoms following mild traumatic brain injury in children. Neuropsychology, 27(1), 112.CrossRefGoogle Scholar
Merritt, V.C., Lange, R.T., & French, L.M. (2015). Resilience and symptom reporting following mild traumatic brain injury in military service members. Brain Injury, 29(11), 13251336.CrossRefGoogle ScholarPubMed
Olsson, K.A., Lloyd, O.T., Lebrocque, R.M., McKinlay, L., Anderson, V.A., & Kenardy, J.A. (2013). Predictors of child post-concussion symptoms at 6 and 18 months following mild traumatic brain injury. Brain Injury, 27, 145157.CrossRefGoogle ScholarPubMed
Pietrzak, R.J., Johnson, D.C., Goldstein, M.B., Malley, J.C., & Southwick, S.M. (2009). Psychological resilience and postdeployment social support protect against traumatic stress and depressive symptoms in soldiers returning from Operations Enduring Freedom and Iraqi Freedom. Depression and Anxiety, 26, 745751.CrossRefGoogle ScholarPubMed
Ponsford, J., Willmont, C., Rothwell, A., Cameron, P., Ayton, G., Nelms, R., . . . Ng, K.T. (1999). Cognitive and behavioral outcome following mild traumatic head injury in children. Journal of Head Trauma and Rehabilitation, 14, 360372.CrossRefGoogle ScholarPubMed
Poole, J.C., Dobson, K.S., & Pusch, D. (2017). Anxiety among adults with a history of childhood adversity: Psychological resilience moderates the indirect effect of emotion dysregulation. Journal of Affective Disorders, 217, 144152.CrossRefGoogle ScholarPubMed
Preacher, K.J., & Kelley, K. (2011). Effect size measures for mediation models: Quantitative strategies for communicating indirect effects. Psychological Methods, 16(2), 93115.CrossRefGoogle ScholarPubMed
Rainey, E.E., Petrey, L.B., Reynolds, M., Agtarap, S., & Warren, A.M. (2014). Psychological factors predicting outcome after traumatic injury: The role of resilience. The American Journal of Surgery, 208, 517523.CrossRefGoogle ScholarPubMed
Reynolds, C.R., & Kamphaus, R.W. (2004). BASC-2: Behavior assessment system for children, second edition manual. Circle Pines, MN: American Guidance Service.Google Scholar
Rieger, B.P., Lewandowski, L.J., Callahan, J.M., Spenceley, L., Truckenmiller, A., Gathke, R., & Miller, L.A. (2013). A prospective study of symptoms and neurocognitive outcomes in youth with concussion vs orthopaedic injuries. Brain Injury, 27(2), 169178.CrossRefGoogle ScholarPubMed
Sady, M.D., Vaughan, C.G., & Gioia, G.A. (2014). Psychometric characteristics of the postconcussion symptom inventory in children and adolescents. Archives of Clinical Neuropsychology, 29, 348363.CrossRefGoogle ScholarPubMed
Schulz, A., Becker, M., Van der Auwera, S., Barnow, S., Appel, K., Mahler, J., . . . Grabe, H.J. (2014). The impact of childhood trauma on depression: Does resilience matter? Population-based results from the Study of Health in Pomerania. Journal of Psychosomatic Research, 77(2), 97103.CrossRefGoogle ScholarPubMed
Stazyk, K., DeMatteo, C., Moll, S., & Missiuna, C. (2017). Depression in youth recovering from concussion: Correlates and predictors. Brain Injury, 31(5), 631638.CrossRefGoogle ScholarPubMed
Stein, E., Howard, W., Rowhani-Rahbar, A., Rivara, F.P., Zatzick, D., & McCarty, C.A. (2017). Longitudinal trajectories of post-concussive and depressive symptoms in adolescents with prolonged recovery from concussion. Brain Injury, 31(13-14), 17361744.CrossRefGoogle ScholarPubMed
Steinhardt, M.A., & Dolbier, C. (2008). Evaluation of a resilience intervention to enhance coping strategies and protective factors and decrease symptomatology. Journal of American College Health, 56, 445453.CrossRefGoogle ScholarPubMed
Sullivan, K.A., Edmed, S.L., Allan, A.C., Smith, S.S., & Karlsson, L. J. E. (2015). The role of psychological resilience and mTBI as predictors of postconcussional syndrome symptomatology. Rehabilitation Psychology, 60(2), 147154.CrossRefGoogle ScholarPubMed
Taylor, H.G., Dietrich, A., Nuss, K., Wright, M., Rusin, J., Bangert, B., . . . Yeates, K.O. (2010). Post-concussive symptoms in children with mild traumatic brain injury. Neuropsychology, 24, 148159.CrossRefGoogle ScholarPubMed
Wood, R.L., O’Hagan, C., Williams, C., McCabe, M., & Chadwick, N. (2014). Anxiety sensitivity and alexithymia as mediators of postconcussion syndrome following mild traumatic brain injury. Journal of Head Trauma Rehabilitation, 29(1), E9E17.CrossRefGoogle ScholarPubMed
Woodrome, S.E., Yeates, K.O., Taylor, H.G., Rusin, J., Bangert, B., Dietrich, A., . . . Wright, M. (2011). Coping strategies as a predictor of post-concussive symptoms in children with mild traumatic brain injury versus mild orthopedic injury. Journal of the International Neuropsychological Society, 17(2), 317326.CrossRefGoogle ScholarPubMed
World Health Organization. (1992). The ICD-10 classification of mental and behavioural disorders: Clinical descriptions and diagnostic guidelines. Geneva: World Health Organization.Google Scholar
Yeates, K.O., Kaizar, E., Rusin, J., Bangert, B., Dietrich, A., Nuss, K., . . . Taylor, H.G. (2012). Reliable change in post-concussive symptoms and its functional consequences among children with mild traumatic brain injury. Archives of Pediatrics & Adolescent Medicine, 166(7), 615622.CrossRefGoogle Scholar
Zemek, R., Barrowman, N., Freedman, S.B., Gravel, J., Gagnon, I., McGahern, , . . . Pediatric Emergency Research Canada (PERC) Concussion Team. (2016). Clinical risk score for persistent postconcussion symptoms among children with acute concussion in the ED. Journal of the American Medical Association, 315(10), 10141025.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Demographic characteristics of study sample

Figure 1

Table 2 Descriptive statistics of study measures

Figure 2

Table 3 Correlations among study measures

Figure 3

Fig. 1 Mediation model depicting the relationship between psychological resilience and self-reported PCS mediated by self-reported anxiety symptoms, with age (Anxiety Symptoms: t(89)=0.44; p=.663; PCS: t(88)=−0.74; p=.458) and sex (Anxiety Symptoms: t(89)=−0.05; p=.963; PCS: t(88)=2.82*; p=.006) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on self-reported PCS through self-reported anxiety symptoms. *Significant effect (p<.05).

Figure 4

Fig. 2 Mediation model depicting the relationship between psychological resilience and self-reported PCS mediated by self-reported depressive symptoms, with age (Depressive Symptoms: t(89)=1.74; p=.086; PCS: t(88)=−1.26; p=.211) and sex (Depressive Symptoms: t(89)=1.85; p=.067; PCS: t(88)=1.96; p=.053) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on self-reported PCS through self-reported depressive symptoms. *Significant effect (p<.05).

Figure 5

Fig. 3 Mediation model depicting the relationship between psychological resilience and self-reported PCS mediated by parent-reported depressive symptoms, with age (Depressive Symptoms: t(88)=−0.22; p=.823; PCS: t(87)=−0.57; p=.571) and sex (Depressive Symptoms: t(88)=0.92; p=.362; PCS: t(87)=2.18*; p=.032) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on self-reported PCS through parent-reported depressive symptoms. *Significant effect (p<.05).

Figure 6

Fig. 4 Mediation model depicting the relationship between psychological resilience and parent-reported PCS mediated by parent-reported depressive symptoms, with age (Depressive Symptoms: t(88)=−0.23; p=.823; PCS: t(87)=0.31; p=.758) and sex (Depressive Symptoms: t(88)=0.92; p=.362; PCS: t(87)=1.62; p=.110) entered as covariates. The standardized beta and confidence interval displayed in the center of the model indicate the indirect effect of psychological resilience on parent-reported PCS through parent-reported depressive symptoms. *Significant effect (p<.05).