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Executive Function in Children and Adolescents with Critical Cyanotic Congenital Heart Disease

Published online by Cambridge University Press:  09 December 2014

Adam R. Cassidy*
Affiliation:
Department of Psychiatry, Boston Children’s Hospital, Harvard Medical School, Boston, Massachusetts
Matthew T. White
Affiliation:
Department of Psychiatry, Boston Children’s Hospital, Harvard Medical School, Boston, Massachusetts
David R. DeMaso
Affiliation:
Department of Psychiatry, Boston Children’s Hospital, Harvard Medical School, Boston, Massachusetts
Jane W. Newburger
Affiliation:
Department of Cardiology, Boston Children’s Hospital, Harvard Medical School, Boston, Massachusetts
David C. Bellinger
Affiliation:
Department of Psychiatry, Boston Children’s Hospital, Harvard Medical School, Boston, Massachusetts Department of Neurology, Boston Children’s Hospital, Harvard Medical School, Boston, Massachusetts
*
Correspondence and reprint requests to: Adam R. Cassidy, Center for Neuropsychology, Department of Psychiatry, Boston Children’s Hospital, Boston, MA 02115. E-mail: adam.cassidy@childrens.harvard.edu
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Abstract

Children and adolescents with critical cyanotic congenital heart disease (CHD) are at risk for deficits in aspects of executive function (EF). The primary aim of this investigation was to compare EF outcomes in three groups of children/adolescents with severe CHD and controls (ages 10–19 years). Participants included 463 children/adolescents with CHD [dextro-transposition of the great arteries (TGA), n=139; tetralogy of Fallot (TOF), n=68; and, single-ventricle anatomy requiring Fontan procedure (SVF), n=145] and 111 controls, who underwent laboratory and informant-based evaluation of EF skills. Rates of EF impairment on D-KEFS measures were nearly twice as high for CHD groups (75–81%) than controls (43%). Distinct EF profiles were documented between CHD groups on D-KEFS tasks. Deficits in flexibility/problem-solving and verbally mediated EF skills were documented in all three CHD groups; visuo-spatially mediated EF abilities were impaired in TOF and SVF groups, but preserved in TGA. Parent, teacher, and self-report ratings on the BRIEF highlighted unique patterns of metacognitive and self-regulatory concerns across informants. CHD poses a serious threat to EF development. Greater severity of CHD is associated with worse EF outcomes. With increased understanding of the cognitive and self-regulatory vulnerabilities experienced by children and adolescents with CHD, it may be possible to identify risks early and provide individualized supports to promote optimal neurodevelopment. (JINS, 2014, 20, 34–49)

Type
Research Articles
Copyright
Copyright © The International Neuropsychological Society 2014 

Introduction

Congenital heart disease (CHD) includes a diverse array of conditions affecting the structural and/or functional integrity of the heart. Dextro-transposition of the great arteries (TGA), tetralogy of Fallot (TOF), and single-ventricle conditions such as hypoplastic left heart syndrome (HLHS) are among the most serious forms of critical cyanotic CHD (Marino et al., Reference Marino, Lipkin, Newburger, Peacock, Gerdes, Gaynor and Mahle2012), each requiring early and intensive medical and surgical intervention(s) to sustain life. In TGA, the major blood vessels connecting the systemic and pulmonary blood supplies are transposed. In TOF, four cardiac abnormalities (ventricular septal defect, pulmonary stenosis, right ventricular hypertrophy, and an overriding aorta) undermine heart function and blood flow. In single-ventricle conditions such as HLHS, one ventricle of the heart fails to develop and thus is unable to circulate oxygenated blood to the body; staged palliative surgeries, typically culminating in the Fontan procedure, are often indicated. The incidence of critical cyanotic CHD is approximately 3/1000 live births (Hoffman & Kaplan, Reference Hoffman and Kaplan2002).

Severe CHD poses a serious threat to brain development. The pathophysiological mechanisms underlying neurologic injury in CHD are diverse and not yet fully understood, including not only potential hypoxic/ischemic cascades triggered by hypoperfusion during cardiac surgery but also a wide range of genetic, prenatal, and other pre- and post-operative factors. In at least some forms of severe CHD, atypical brain development is evident prenatally, as early as 25- to 30-weeks gestation (Clouchoux et al., Reference Clouchoux, du Plessis, Bouyssi-Kobar, Tworetzky, McElhinney, Brown and Limperopoulos2013; Limperopoulos et al., Reference Limperopoulos, Tworetzky, McElhinney, Newburger, Brown, Robertson and du Plessis2010). Infants with CHD exhibit high rates of microcephaly, hypotonia, and atypical state regulation on clinical examination, and neuroimaging abnormalities such as ischemic infarcts and white matter injury (periventricular leukomalacia) are present in up to 59% before surgery (Owen, Shevell, Majnemer, & Limperopoulos, Reference Owen, Shevell, Majnemer and Limperopoulos2011). Relative to controls, the brains of full-term infants with TGA or HLHS are smaller and less mature structurally than those of typically developing infants (Licht et al., Reference Licht, Shera, Clancy, Wernovsky, Montenegro, Nicolson and Vossough2009), with reduced grey matter volumes particularly in the frontal lobe (Watanabe et al., Reference Watanabe, Matsui, Matsuzawa, Tanaka, Noguchi, Yoshimura and Gur2009). Adolescents with corrected TGA (Bellinger et al., Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011) and those with TOF (Bellinger et al., Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a) exhibit much higher rates of structural MRI abnormalities than controls. Fractional anisotropy on diffusion tensor imaging is significantly reduced in adolescents with TGA, particularly within deep cerebral, cerebellar, and midbrain white matter (Rivkin et al., Reference Rivkin, Watson, Scoppettuolo, Wypij, Vajapeyam, Bellinger and Newburger2013).

Behavioral studies further evidence the adverse impact of CHD on the developing brain. Within the context of Low Average to Average overall cognitive abilities (Karsdorp, Everaerd, Kindt, & Mulder, Reference Karsdorp, Everaerd, Kindt and Mulder2007), children/adolescents with CHD, as a group, face increased risk for deficits in speech/language, sensory/motor, attention, memory, and visual-spatial skills (Bellinger et al., Reference Bellinger, Wypij, duPlessis, Rappaport, Jonas, Wernovsky and Newburger2003, Reference Bellinger, Newburger, Wypij, Kuban, duPlesssis and Rappaport2009, Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011; Brosig, Mussatto, Kuhn, & Tweddell, Reference Brosig, Mussatto, Kuhn and Tweddell2007; Calderon et al., Reference Calderon, Bonnet, Courtin, Concordet, Plumet and Angeard2010; Gaynor et al., Reference Gaynor, Gerdes, Nord, Bernbaum, Zackai, Wernovsky and Jarvik2010; Hovels-Gurich et al., Reference Hovels-Gurich, Konrad, Wiesner, Minkenberg, Herpertz-Dahlmann, Messmer and von Bernuth2002; Miatton et al., Reference Miatton, De Wolf, François, Thiery and Vingerhoets2007a, Reference Miatton, De Wolf, François, Thiery and Vingerhoets2007b; Schaefer et al., Reference Schaefer, von Rhein, Knirsch, Huber, Natalucci, Caflisch and Latal2013). Educational/academic achievement difficulties (Bellinger et al., Reference Bellinger, Wypij, duPlessis, Rappaport, Jonas, Wernovsky and Newburger2003, Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011), social cognitive deficits (Bellinger, Reference Bellinger2008; Bellinger et al., Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011; Calderon et al., Reference Calderon, Bonnet, Courtin, Concordet, Plumet and Angeard2010), and emotional/behavioral problems (Bellinger et al., Reference Bellinger, Newburger, Wypij, Kuban, duPlesssis and Rappaport2009; Brosig et al., Reference Brosig, Mussatto, Kuhn and Tweddell2007) are also elevated.

Children and adolescents with CHD are also at risk for deficits in executive function. “Executive function” (EF) refers to a constellation of skills, mediated by densely interconnected neuroanatomical networks involving frontal/prefrontal (Robbins, Reference Robbins1996), parietal (Champod & Petrides, Reference Champod and Petrides2010), cerebellar (Stoodley & Schmahmann, Reference Stoodley and Schmahmann2010), and subcortical structures (Little et al., Reference Little, Kraus, Joseph, Geary, Susmaras, Zhou and Gorelick2010; Provost, Petrides, & Monchi, Reference Provost, Petrides and Monchi2010), that are necessary for effective regulation of behavior, emotion, cognition, and social adaptation (Diamond, Reference Diamond2013). Children with severe CHD exhibit problems with inhibitory control (Calderon et al., Reference Calderon, Bonnet, Courtin, Concordet, Plumet and Angeard2010, Reference Calderon, Angeard, Moutier, Plumet, Jambaqué and Bonnet2012; Gaynor et al., Reference Gaynor, Gerdes, Nord, Bernbaum, Zackai, Wernovsky and Jarvik2010, Reference Gaynor, Ittenbach, Gerdes, Bernbaum, Clancy, McDonald-McGinn and Spray2014; Miatton et al., Reference Miatton, De Wolf, François, Thiery and Vingerhoets2007a), planning (Bellinger et al., Reference Bellinger, Wypij, duPlessis, Rappaport, Jonas, Wernovsky and Newburger2003, Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011; Calderon et al., Reference Calderon, Bonnet, Courtin, Concordet, Plumet and Angeard2010, Reference Calderon, Angeard, Moutier, Plumet, Jambaqué and Bonnet2012; Miatton et al., Reference Miatton, De Wolf, François, Thiery and Vingerhoets2007a, Reference Miatton, De Wolf, François, Thiery and Vingerhoets2007b), cognitive flexibility (i.e., switching/shifting; Bellinger et al., Reference Bellinger, Wypij, duPlessis, Rappaport, Jonas, Wernovsky and Newburger2003, Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011; Calderon et al., Reference Calderon, Bonnet, Courtin, Concordet, Plumet and Angeard2010, Reference Calderon, Angeard, Moutier, Plumet, Jambaqué and Bonnet2012), working memory (Calderon et al., Reference Calderon, Bonnet, Courtin, Concordet, Plumet and Angeard2010, Reference Calderon, Angeard, Moutier, Plumet, Jambaqué and Bonnet2012), and executive attention (Hovels-Gurich et al., Reference Hövels-Gürich, Konrad, Skorzenski, Herpertz-Dahlmann, Messmer and Seghaye2007). Some also struggle with abstract problem-solving and inferential reasoning, and can have a hard time with efficient retrieval and generation of verbal output (Bellinger et al., Reference Bellinger, Wypij, duPlessis, Rappaport, Jonas, Wernovsky and Newburger2003). Composite parent and teacher ratings of EF skills confirm self-regulatory and metacognitive difficulties at home and school (Bellinger et al., Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011, Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a). In contrast, self-report ratings of global EF abilities have generally failed to document significant concerns (Bellinger et al., Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011, Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a), leading investigators to suggest that “…relying solely on self-reports of patients with congenital heart disease might underestimate the severity of their challenges, at least in the domain of executive functions” (Bellinger et al., Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a, p. 9).

The primary aim of the current investigation was to compare EF outcomes in four groups of children and adolescents: three with CHD (TGA, TOF, or single-ventricle cardiac conditions culminating in the Fontan procedure) and a group of typically developing controls. Although prior studies have shown that children with severe CHD are at risk for EF deficits, none to date have been designed and/or adequately powered to determine whether distinct forms of CHD are associated with distinct patterns of EF vulnerabilities. In the present study, we operationalized the EF construct broadly, using a combination of well-validated laboratory tasks and parent, teacher, and self-report rating scales, within a large mixed-CHD sample of children and adolescents who participated in one of three cardiac neurodevelopmental studies at Boston Children’s Hospital.

We hypothesized that children/adolescents with CHD would perform worse on all laboratory EF tasks and would be rated by parents and teachers as having more real-world EF problems than controls. Self-report ratings were not expected to reflect the same degree of problem severity as parent and teacher reports; nonetheless, by examining perceived concerns across a wide range of specific EF domains, this study provides a more comprehensive test than previous investigations of whether children/adolescents with CHD self-identify EF problems in everyday life. Finally, because data contrasting neurodevelopmental outcomes on the basis of cardiac diagnosis are limited, we conducted exploratory comparisons across CHD groups.

Method

Recruitment and Procedure

Data were compiled from three large-scale, single-center studies: (1) the Boston Circulatory Arrest Study of children/adolescents with TGA (Bellinger et al., Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011); (2) a study of children/adolescents with TOF (Bellinger et al., Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a); and (3) a study of children/adolescents with single-ventricle cardiac anatomy who underwent the Fontan operation (SVF; Bellinger et al., Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson, Wypij and Newburger2014b). All three studies included extensive neuropsychological evaluation (lasting approximately 4 hr). Psychological measures were administered in a fixed order by a licensed psychologist or supervised research assistant.

Studies were approved by the Institutional Review Board and conducted in accordance with the Helsinki Declaration. Informed consent was obtained from parents of participants; adolescents provided assent.

TGA group

The Boston Circulatory Arrest Study has been well-described previously (e.g., Bellinger et al., Reference Bellinger, Jonas, Rappaport, Wypij, Wernovsky, Kuban and Strand1995, Reference Bellinger, Wypij, duPlessis, Rappaport, Jonas, Wernovsky and Newburger2003, Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011; Newburger et al., Reference Newburger, Jonas, Wernovsky, Wypij, Hickey, Kuban and Ware1993). Eligible participants included children/adolescents 14–16 years old with TGA who underwent the arterial switch operation by 3 months of age. Exclusion criteria included birth weight <2.5 kg, recognized genetic syndrome, prior heart surgery, or cardiovasculature requiring reconstruction of the aortic arch. Enrolled infants were randomly assigned to receive the arterial switch operation using a strategy of vital organ support of cardiopulmonary bypass with predominant deep hypothermic circulatory arrest or predominant low-flow bypass. Children were followed serially after surgery. Data from the most recent assessment were analyzed in the current study.

TOF group

Eligible participants included children/adolescents 13–16 years old with TOF (with or without pulmonary atresia) who underwent surgical repair at least 6 months before assessment. Exclusion criteria included diagnosis of trisomy 21 and/or presence of a disorder/device contraindicated for MRI.

SVF group

Eligible participants included children/adolescents 10–19 years old with single-ventricle cardiac anatomy and who underwent the Fontan procedure, Fontan re-do, or other open-heart surgical procedure at least 6 months before evaluation. Exclusion criteria included history of cardiac transplantation and/or presence of a disorder/device contraindicated for MRI.

Control group

A total of 111 typically developing children/adolescents 10–19 years old were recruited (61 during the TOF study and 50 during the SVF study) in accordance with admission criteria for the NIH MRI Study of Normal Brain Development (Waber et al., Reference Waber, De Moor, Forbes, Almli, Botteron and Leonard2007).

Participants

Among the 497 children/adolescents included in our cohort, 34 (23 TOF and 11 SVF) had identified genetic/syndromic conditions (e.g., 22q11) and were excluded from analyses. The final pooled sample for the current study included 463 children/adolescents (63.3% male; 139 TGA, 68 TOF, 145 SVF, and 111 controls) ranging in age from 10 to 19 years (M=15.17; SD=2.04). Table 1 presents sample demographic and medical/surgical characteristics.

Table 1 Sample demographic characteristics by cardiac diagnosis

Note. CHD=congenital heart disease; TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure; SES=family socioeconomic status according to Hollingshead Four Factor Index of Social Status (1975). The CHD category includes all participants in the TGA, TOF, and SVF groups. Some demographic data were missing; therefore, sample sizes, which are provided above as min-max, depict valid ns by group. Unless otherwise specified, results are presented as mean (standard deviation).

a Hollingshead, A. A. (Reference Hollingshead1975). Four-factor index of social status. Unpublished manuscript, Yale University, New Haven, CT.

b ns: CHD=256; Control=30; TGA=127; TOF=25; SVF=104.

c ns: CHD=252; Control=29; TGA=126; TOF=23; SVF=103.

Measures

The present investigation used a common subset of laboratory data from the Delis-Kaplan Executive Function System (D-KEFS; Delis, Kaplan, & Kramer, Reference Delis, Kaplan and Kramer2001) and questionnaire data from the Behavior Rating Inventory of Executive Function (BRIEF; Gioia, Isquith, Buy, & Kenworthy, Reference Gioia, Isquith, Guy and Kenworthy2000; Guy, Isquith, & Geoia, Reference Guy, Isquith and Gioia2004) to examine EF outcomes. Of note, broad neurobehavioral outcomes from the three larger studies, including a D-KEFS composite score and BRIEF General Executive Composite scores, have been described in previous reports (Bellinger et al., Reference Bellinger, Wypij, Rivkin, DeMaso, Robertson, Dunbar-Masterson and Newburger2011, Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a, Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson, Wypij and Newburger2014b). The present study provides a detailed analysis of EF outcomes, using individual D-KEFS subtest scores and BRIEF subscale/index scores that have not been published elsewhere.

D-KEFS

The D-KEFS is a widely used battery of laboratory EF tasks. Five subtests were included in the current study. The Verbal Fluency Test is a measure of verbal generativity and switching consisting of 3 conditions (Letter Fluency, Category Fluency, Category Switching). The Design Fluency Test is a measure of visual-spatial generativity and switching consisting of 3 conditions (Filled Dots, Empty Dots, Dot Switching). The Sorting Test is a measure of cognitive flexibility and problem-solving in which participants are asked to sort cards into as many 3-card groups as possible. The Word Context Test is a measure of verbal concept formation and hypothesis-testing requiring participants to determine the definitions of 10 nonsense “mystery” words using a series of context clues. The Tower Test is a measure of visual-spatial planning that requires participants to build a series of towers by arranging flat disks on a board with 3 vertical pegs. Age-referenced scaled scores (M=10; SD=3) were included in analyses.

BRIEF

The BRIEF is a questionnaire designed to solicit information about an individual’s use of EF skills in real-world settings. Parent, teacher, and self-report ratings were administered. Age-referenced T-scores (M=50; SD=10) were included in analyses. Scores ≥65 are considered “clinically significant;” self-report scores ≥60 may “warrant clinical interpretation” (Guy et al., Reference Guy, Isquith and Gioia2004, p. 16; Gioia et al., Reference Gioia, Isquith, Guy and Kenworthy2000).

Data Analysis

Data analyses were conducted using IBM SPSS Statistics Version 21 and SAS Version 9.3. Variables were examined for normality and outliers; no concerning outliers were present. D-KEFS variables were normally distributed. BRIEF data were significantly positively skewed and could not be normalized adequately with transformation, thereby precluding them from analyses assuming normality. To establish comparability of groups on EF outcomes, six factors potentially related to EF development [socioeconomic status (SES), birth weight, gestational age, age at assessment, sex, and race (white/Caucasian/non-Hispanic vs. nonwhite)] were subjected to separate multivariate analysis of covariance (MANCOVA) models and examined for between-group differences.

Profile analysis was used initially to assess D-KEFS score patterns across CHD (combined) and control groups, and subsequently to compare profiles across CHD subgroups (TGA, TOF, and SVF). This analysis was conducted using a general linear model (PROC GLM in SAS) with the D-KEFS subtests as the outcome variables and with group and other significant covariates included as predictors. Performance on D-KEFS subtests was compared across groups using contrasts from the profile analysis with a Bonferroni correction for pairwise comparisons. D-KEFS subtest scores were then dichotomized using a cutoff of 1.5 SD below population mean (scaled scores≤6) to denote impairment. BRIEF data were also dichotomized using accepted cutoff scores. Logistic regression, controlling for significant covariates, was used to compare the odds of scoring within the impaired/elevated range between CHD groups and controls on D-KEFS/BRIEF measures. Paired t-tests (calculated separately for CHD and control groups) were performed to compare self-report versus parent/teacher BRIEF ratings. We used Benjamini and Hochberg’s (Reference Benjamini and Hochberg1995) false discovery rate procedure to limit the chance of reporting a falsely significant result to be no more than 5%. We first determined significance of the overall group effect for each model and then, if significant, conducted pairwise comparisons between groups to identify significant group differences. Using this procedure, a p-value≤.031 was considered statistically significant. In an exploratory analysis, Spearman partial correlation coefficients were calculated to evaluate associations between D-KEFS and BRIEF variables.

Results

Comparability of Groups

SES, birth weight, gestational age, age at assessment, sex, and race were examined as potential covariates in four separate MANCOVA models: (1) all D-KEFS variables, (2) BRIEF Parent, (3) BRIEF Teacher, and (4) BRIEF Self-Report. Groups did not differ in gestational age or birth weight for any EF outcome. Significant findings were as follows: for D-KEFS: SES [F(11,413)=4.91; p<.001], age at assessment [F(11,415)=1.81; p=.05], sex [F(11,415)=2.84; p=.001], and race [F(11,415)=2.70; p=.002]; for BRIEF-Parent: SES [F(8,439)=5.91; p<.001] and sex [F(8,441)=2.66; p=.007]; for BRIEF-Teacher: sex [F(8,235)=2.86; p=.005] and race [F(8,235)=2.46; p=.01]; for BRIEF-Self: SES [F(8,416)=2.81; p=.005]. Significant factors for each respective EF outcome source were included as covariates in primary analyses. Consistent with the rationale proposed by Dennis et al. (Reference Dennis, Francis, Cirino, Schachar, Barnes and Fletcher2009), IQ was not included as a covariate in any analysis (see also Miller, Loya, & Hinshaw, Reference Miller, Loya and Hinshaw2013).

Primary Analyses

D-KEFS task performance

Most D-KEFS subtest scores were within the average range, except for the Sorting Recognition score, which was below average in some CHD groups (Table 2). Performance profiles are depicted graphically in Figure 1. Profile analysis indicated that D-KEFS score patterns between combined CHD and control participants were not parallel [F(11,410)=2.65; p<.001]. Looking specifically at score patterns across the TGA, TOF, and SVF groups, likewise revealed a lack of parallelism, F(22,820)=3.16; p<.001; the TGA profile differed significantly from the SVF [F(11,410)=4.53; p<.001] and TOF [F(11,410)=2.65; p=.003] profiles, and the TOF and SVF profiles were also significantly different [F(11,410)=2.01; p=.026].

Fig. 1 Estimated marginal means of D-KEFS tasks in cardiac and control groups, controlling for SES, age, sex, and race (error bars represent 95% confidence intervals). TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure; VFL=Verbal Fluency; TCC=Total Consecutively Correct; CCS=Confirmed Correct Sorts; DFL=Design Fluency; TAS=Total Achievement Score; TPMR=Time per Move Ratio; MAR=Move-Accuracy Ratio.

Table 2 D-KEFS subtest performance and impaired subtest score percentages by cardiac diagnosis

Note. CHD=congenital heart disease; TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure; C=control; Total Ach. Score=Tower Total Achievement score; TPMR=Tower Time-per-Move Ratio; MAR=Tower Move-Accuracy Ratio; Conf. Correct Sorts=Sorting Test Confirmed Correct Sorts. Unless otherwise specified, results are presented as mean (standard deviation). All p-values are derived using linear contrasts from the profile analysis described in the data analysis section; significant differences between CHD groups are bolded. Cohen’s d effect size estimates were calculated using estimated marginal means and adjusted SDs. Some D-KEFS data were missing; therefore, sample sizes, which are provided above as min-max, depict valid ns by group.

*p≤.031.

**p≤.01.

***p≤.001.

Linear contrasts comparing TGA, TOF, SVF, and controls identified significant group differences. At least one CHD group performed significantly worse than controls for all D-KEFS measures except the Tower MAR, which was not statistically different among the groups. See Table 2 for a summary of significant pairwise differences between groups. No significant differences between CHD groups were noted on verbally mediated EF tasks (Verbal Fluency and Word Context Tests) or on tasks with combined verbal/visuo-spatial demands (Sorting Test). In contrast, TGA- (and, in some instances, TOF-) group performance was relatively secure on most visuo-spatial EF tasks. On the Design Fluency Test, TGA-group performance was not statistically different than controls—and better than the SVF group—across all three trials; the TGA group also outperformed the TOF group on Filled Dots trial. On the Tower Test, TGA- and TOF-group Total Achievement Scores were not statistically different than controls; however, all three CHD groups scored lower than controls on Time-per-Move Ratio, indicating greater efficiency in task-completion among healthy children/adolescents than those with CHD. Pairwise CHD group differences were moderate in effect size.

Table 3 presents results from the logistic regression models used to compare the odds of impaired D-KEFS task performance among the control and CHD groups. Looking first at verbal EF tasks, the odds of impairment on the Category Fluency task were no worse among CHD groups than controls. In contrast, TGA and TOF groups had greater odds of impaired Letter Fluency than controls; odds of impaired Letter Fluency in the SVF group were lower than in the TGA group. All three CHD groups had greater odds of impaired Category Switching compared to controls, arguably the most demanding of the verbal fluency tasks. The highest odds of impairment were on the Word Context Test, with the SVF group significantly higher than both control and TGA participants.

Table 3 Odds of impairment on D-KEFS subtest by CHD group as compared to controls

Note. CHD=congenital heart disease; TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure; OR=odds ratio; CI=confidence interval for the OR; TCC=Total Consecutively Correct; TPMR=Time-per-Move Ratio; MAR=Move-Accuracy Ratio; CCS=Confirmed Correct Sorts. Reference group=controls. Variables were dichotomized using 1.5 SD below population mean as cutoff score. Boldface denotes significant odds ratios. Only significant CHD-group pairwise comparisons are presented.

*p≤.031.

**p≤.01.

***p≤.001.

On visuo-spatial EF tasks, the odds of impairment on all three Design Fluency trials and two out of three Tower measures were statistically greater among TOF and SVF groups than controls; the TGA group was more likely than controls to score within the impaired range on Empty Dots, but was otherwise at no greater risk for impaired Design Fluency or Tower Test performance than controls. Moreover, the TGA group was at lower risk than TOF for impairment on the Dot Switching trial, and at lower risk than both TOF and SVF groups for impairment on Filled Dots trial.

Finally, the odds of impairment on the Sorting Test were higher in all three CHD groups than controls.

BRIEF reports

Group-level means were within normal limits (Table 4). Percentages of children/adolescents obtaining at least one elevated subscale differed markedly across CHD and control groups for parent and teacher ratings. Self-report ratings with at least one elevated score also differed from controls using a clinical cutoff score of ≥65, but more closely approximated parent/teacher percentages using a relaxed cutoff score of ≥60.

Table 4 BRIEF descriptive results and elevated subscale score percentages by CHD diagnosis

Note. CHD=congenital heart disease; TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure. Unless otherwise specified, results are presented as mean (standard deviation). Some BRIEF Teacher-report data were missing; therefore, sample sizes, which are provided above as min-max, depict valid ns by group.

Results of logistic regression analyses and pairwise comparisons are presented in Table 5. On parent report, the odds of being rated as having clinically significant metacognitive and self-regulatory problems were statistically higher among CHD groups than controls for most domains. Inhibition was the only exception; odds of parent-rated inhibitory control problems were greater than controls for the SVF group, but no different for TGA and TOF groups. Children/adolescents in the SVF group were also statistically more likely than those in the TGA group to have parent-reported problems with initiation and working memory.

Table 5 Odds of clinically significant problems on BRIEF subscale by CHD group as compared to controls

Note. CHD=congenital heart disease; TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure; OR=odds ratio; CI=confidence interval for OR. Variables were dichotomized using 1.5 SD above population mean for parents/teachers, 1.0 SD for self-report. Boldface denotes significant odds ratios. Only significant CHD-group pairwise comparisons are presented.

a The overall group effect was not significant (p>0.031). Pairwise differences were not assessed for statistical significance.

**p≤.01.

On teacher report, the odds of being rated as having clinically significant metacognitive problems were statistically higher among CHD groups than controls for most domains. The TOF group had significantly greater odds of having problems with inhibition than both control and TGA groups. Otherwise, the odds of clinically significant self-regulatory problems were not statistically greater among children/adolescents with CHD than controls, according to teachers.

Logistic regression analyses of self-report ratings revealed no significant differences in odds of obtaining ratings ≥65 across groups. Using a cutoff score of ≥60, however, the odds of self-identifying problems with shifting and emotion regulation were statistically greater among all three CHD groups than controls. TGA participants were more likely than controls to endorse problems with inhibition and self-monitoring. On self-report, the odds of rating oneself as having clinically significant problems with metacognitive skills were statistically no greater among CHD than control participants.

Paired t-tests examining differences between BRIEF self-report and parent/teacher ratings showed that, for CHD participants, self-report ratings were lower than parent/teacher scores for all subscales; effect sizes ranged from small to medium (Table 6). Control self-report ratings were significantly lower than teacher ratings for inhibit, shift, emotion control, monitor, and plan/organize subscales, with small to medium effects. Control self- and parent-report ratings were not statistically different.

Table 6 Paired t-test results comparing BRIEF self-report vs. parent/teacher ratings

BRIEF-D-KEFS correlations

Spearman partial correlation coefficients, controlling for SES, age, sex, and race, were calculated between BRIEF and D-KEFS variables for CHD and control groups separately. Given the large number of variables included, a p-value<.001 was considered statistically significant. Results are presented in Table 7. For CHD groups, correlations between parent and teacher ratings and several D-KEFS measures (most notably Sorting, Verbal Fluency, and Design Fluency) were statistically significant yet small in magnitude. For controls, BRIEF ratings did not correlate significantly with any D-KEFS variable.

Table 7 Correlations between D-KEFS and BRIEF variables for CHD and control groups

Note. Results are Spearman partial correlation coefficients controlling for SES, age, sex, and race. TCC=Total Consecutively Correct; CCS=Confirmed Correct Sorts; TPMR=Time-per-Move Ratio; MAR=Move-Accuracy Ratio. Correlations significant at p<.001 are bolded.

Discussion

We found that, on average, CHD group means were within the expected age-range on most laboratory EF tasks and informant ratings. However, looking more specifically at areas of clinical impairment, the percentages of children and adolescents performing at least 1.5 SD below the population mean on at least one D-KEFS subtest were nearly twice as high for CHD groups (75–81%) than controls (43%). Percentages of children/adolescents with CHD obtaining clinically elevated scores on the BRIEF were four times higher than controls for parent ratings, and twice as high for teacher and self-report ratings.

Our prediction that controls would outperform CHD groups on all EF measures was partially confirmed: Tower Move-Accuracy Ratio demonstrated very poor sensitivity to differentiate between children with CHD and controls. Controls scored higher than CHD participants on all other D-KEFS measures.

Distinct EF profiles were documented between CHD groups on D-KEFS tasks. Comparing across groups, an interesting pattern emerged in relation to the predominant modality-specific demands of a given task. Controlling for SES, age, sex, and race, CHD was associated with relative deficits in cognitive flexibility/problem-solving and most verbally mediated EF skills for TGA, TOF, and SVF groups. Many visuo-spatially mediated EF skills were also impaired relative to controls in TOF and SVF groups but were relatively preserved in the TGA group.

The etiology of this diagnosis-specific pattern of deficits is unclear but may stem from one or a combination of prenatal, postnatal, and surgical differences. One possibility is that brain regions critical for verbally versus visually mediated EF abilities may be differentially vulnerable to duration/extent of sub-optimal cerebral perfusion and/or oxygenation in prenatal development. Whereas fetuses with TGA experience reduced oxygenation but relatively normal cerebral perfusion prenatally and immediately after birth, single-ventricle conditions such as HLHS are associated with significant reductions in both oxygenation and perfusion (Licht et al., Reference Licht, Wang, Silvestre, Nicolson, Montenegro, Wernovsky and Detre2004). Absent in utero antegrade cerebral blood flow, which reduces cerebral perfusion and is common in HLHS (but not TGA), has been linked to reduced volumes of white matter, subcortical gray matter, and regional surface area in fetuses with HLHS (Sethi et al., Reference Sethi, Tabbutt, Dimitropoulos, Harris, Chau, Poskitt and McQuillen2013; Clouchoux et al., Reference Clouchoux, du Plessis, Bouyssi-Kobar, Tworetzky, McElhinney, Brown and Limperopoulos2013) and, as such, may account for relatively greater risk for neural injury and associated functional impairment among single-ventricle participants.

Postnatal cerebral perfusion and oxygenation also differ dramatically across CHD groups. Infants with TGA typically undergo surgical correction within the first weeks of life, essentially normalizing the oxygen content and cerebral perfusion pressure. In contrast, there is much greater variability in age-at-first-surgery for infants with TOF and single-ventricle anatomy, with the majority experiencing ongoing alterations in perfusion and oxygenation for months or even years after birth. While children with TOF may undergo repair at a few months old, children with HLHS typically live for 2–3 years with chronic reductions in oxygenation and/or perfusion and continue to experience chronic circulatory changes even after palliation. Surgical management also differs greatly. Most children with TGA require a single postnatal corrective surgery with no additional cardiac operations. Those with TOF may undergo a single correction but typically not until a few months of age. On the other hand, children with single-ventricle conditions nearly always require more than one surgery, which not only exposes them to higher levels of general anesthetics (Jevtovic-Todorovic et al., Reference Jevtovic-Todorovic, Absalom, Blomgren, Bambrink, Crosby, Culley and Hemmings2013) and additional opportunities for surgical complications, but also necessitates that they endure a period of chronic hypoxemia while awaiting completion of staged palliation (Fenton, Lessman, Glogowski, Fogg, & Duncan, Reference Fenton, Lessman, Glogowski, Fogg and Duncan2007).

Finally, although patients were screened for syndromic findings, not all had genetic testing. Indeed, genetic/epigenetic factors influencing patterning of both heart and brain are more common in TOF and single-ventricle conditions than in TGA (Mahle et al., Reference Mahle, Lu, Ohye, Gaynor, Goldberg, Sleeper and NewBurger2013; Newburger et al., Reference Newburger, Sleeper, Bellinger, Goldberg, Tabbutt and Mussatto2012; Yi et al., Reference Yi, Tang, McDonald-McGinn, Calkins, Whinna, Souders and Gur2014) and as-yet undescribed genetic factors could have contributed to some of the cognitive differences detected. Thus, more severe functional impairment may have been more common in participants with TOF or single-ventricle conditions than in those with TGA for several reasons, ranging from genetic and fetal cerebral hemodynamics to postnatal brain injury.

Regarding informant ratings, parents expressed the widest range of EF concerns, endorsing problems related to both regulatory and metacognitive functions. Teachers also recognized problems with metacognitive skills but in general did not rate children/adolescents with CHD as having more behavior or emotion regulation difficulties than controls. Understanding the nature of this discrepancy likely requires an appreciation of context. Teachers interact with students within the school environment, which is equipped with a range of external regulators (e.g., teachers, non-familial peers, strict scheduling) generally not available within the home that may help to mitigate self-control vulnerabilities. Schools may also present greater demands than home for organization, planning, and independent problem-solving, especially as students transition into middle and high school, which may increase the salience of a child’s metacognitive difficulties to his/her teachers. Managing metacognitive challenges at school may also be more effortful for children with CHD, taxing already vulnerable regulatory resources and making it harder for them to effectively modulate their behavior and emotions after school.

It has been suggested that “…relying solely on self-reports of patients with congenital heart disease might underestimate the severity of their challenges, at least in the domain of executive functions” (Bellinger et al., Reference Bellinger, Rivkin, DeMaso, Robertson, Stopp, Dunbar-Masterson and Newburger2014a, p. 9). Consistent with this view, logistic regression analyses were indeed unable to distinguish CHD groups from controls using a cutoff score ≥65. However, application of a more relaxed cutoff score (≥60) revealed that children/adolescents with CHD do, in fact, rate themselves as having more problems than controls in select domains of EF. Self-identified concerns regarding cognitive flexibility/shifting, in particular, emerged among members of all three CHD groups, and were consistent with parent ratings and performance on select laboratory flexibility/switching tasks. The development of cognitive flexibility is protracted relative to other core EF abilities (Davidson, Amso, Anderson, & Diamond, Reference Davidson, Amso, Anderson and Diamond2006) and is accompanied by increased capacity for switching fluidly between rules, accommodating unexpected changes in routine, and generating/entertaining less obvious perspectives than one’s own (Diamond, Reference Diamond2013). As such, cognitive flexibility facilitates not only cognitive and academic success but also social competence. Being able to accurately infer the mental states of others (i.e., theory of mind), for example, relies on the ability to toggle flexibly between self- and other-generated representations of the world (Müller, Zelazo, & Imrisek, Reference Müller, Zelazo and Imrisek2005) and has been identified as an area of vulnerability among young children with TGA (Calderon et al., Reference Calderon, Angeard, Moutier, Plumet, Jambaqué and Bonnet2012). Of interest, individual differences in EF have also recently been shown to predict benefit from theory-of-mind training in healthy preschool children (Benson, Sabbagh, Carlson, & Zelazo, Reference Benson, Sabbagh, Carlson and Zelazo2013), suggesting that an understanding of the specific cognitive processes facilitating the development of social cognition in children with CHD may ultimately guide the development of effective prevention/intervention programs for this vulnerable population as well.

Self- and parent-report ratings also identified concerns regarding emotion regulation. These findings highlight the need for a broader conceptualization of EF in CHD, emphasizing not only decontextualized, “cool” EFs but also the range of “hot” EF skills involved in overcoming problems bearing greater emotional/motivational significance (Prencipe et al., Reference Prencipe, Kesek, Cohen, Lamm, Lewis and Zelazo2011). Mediated by networks involving ventro-medial/orbitofrontal regions of the prefrontal cortex, as well as the amygdala and limbic structures, “hot” EF skills may be vulnerable to systemic perturbations affecting midline cardiac and neural development. Future studies should harness the power of sensitive behavioral tasks (see Crone & Van der Molen, Reference Crone and Van der Molen2004; Kerr & Zelazo, Reference Kerr and Zelazo2004) and neuroimaging techniques to elucidate the developmental course of “hot” EF skills in children with CHD.

Clinically, the self-report ratings collected in this study provide novel insight into how children and adolescents with severe CHD perceive themselves. To date, use of the BRIEF in cardiac neurodevelopmental research has generally been limited to composite variables that collapse across diverse EF skills. This study suggests that children with CHD may be more aware of their struggles than previously thought, particularly regarding problems with cognitive flexibility and emotion regulation. We recommend that clinicians working with the CHD population recognize BRIEF self-report scores ≥60 as potentially “warranting clinical attention” and provide recommendations to manage concerns. We also recommend that future research deconstruct multifaceted composite scores into component subscales to identify specific patterns of risk and protective factors among children with CHD.

This report outlines findings from the largest and most comprehensive study of EF in critical cyanotic CHD to date. There are, however, some limitations to be considered. First, in our effort to limit our sample to children without identified genetic conditions, 25% of the TOF group was excluded, rendering this group relatively underpowered to detect differences. Second, not all participants had genetic testing or evaluation by a geneticist, leaving open the possibility that some participants with undetected genetic/syndromic conditions may have been included in our sample. Third, it should be acknowledged that the controls in our study were carefully screened for conditions known or expected to adversely impact brain development and thus may be more representative of “super-normal” than “normal” population development (Waber et al., Reference Waber, De Moor, Forbes, Almli, Botteron and Leonard2007). Our sample was also drawn from studies conducted at a single center and consisted largely of Caucasian participants. Although we attempted to mitigate these issues by controlling statistically for SES and other factors related to EF development, further research is necessary to determine the generalizability of our findings to the broader CHD population. Fourth, because of “task impurity” (Denckla, Reference Denckla1994), performance on tests purported to measure EF can be affected by a range of factors that cannot be adequately accounted for except in tightly controlled experimental paradigms that, unfortunately, were not included in the current study. Fifth, the surgical and postoperative management techniques used in infancy in our mostly adolescent samples might have changed over time in such a way as to produce better outcomes in patients who underwent cardiac surgery more recently. Finally, although the current investigation aimed to operationalize the EF construct broadly, it will be important for future studies to take this approach further, drawing from developmentally informed models of EF (e.g., Lee, Bull, & Ho, Reference Lee, Bull and Ho2013) to better understand how core EF abilities such as working memory, inhibitory control, and shifting are organized in children with CHD and how these putative core skills may be related to functional outcomes.

In conclusion, the current study demonstrates that children and adolescents developing within the context of critical cyanotic congenital heart disease are at increased risk for EF deficits. With greater understanding of the specific patterns of cognitive and self-regulatory vulnerabilities experienced by children with CHD, it may be possible to identify risks early and provide individualized supports necessary to promote optimal neurodevelopmental outcomes.

Acknowledgments

This research was supported in part by grants from the National Heart, Lung, and Blood Institute (HL77681, HL74734, and HL096825), the Farb Family Fund, and the National Center for Research Resources (RR02172). The authors have no conflicts of interest to declare. The authors thank the children and adolescents, parents, and teachers who participated in this study. The authors also thank Jane Holmes Bernstein, PhD, Caitlin Rollins, MD, and Debbie Waber, PhD, for their thoughtful comments on earlier versions of this manuscript, and Christian Stopp, MS, for his assistance with data management.

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Figure 0

Table 1 Sample demographic characteristics by cardiac diagnosis

Figure 1

Fig. 1 Estimated marginal means of D-KEFS tasks in cardiac and control groups, controlling for SES, age, sex, and race (error bars represent 95% confidence intervals). TGA=dextro-transposition of the great arteries; TOF=tetralogy of Fallot; SVF=single-ventricle children/adolescents who underwent the Fontan procedure; VFL=Verbal Fluency; TCC=Total Consecutively Correct; CCS=Confirmed Correct Sorts; DFL=Design Fluency; TAS=Total Achievement Score; TPMR=Time per Move Ratio; MAR=Move-Accuracy Ratio.

Figure 2

Table 2 D-KEFS subtest performance and impaired subtest score percentages by cardiac diagnosis

Figure 3

Table 3 Odds of impairment on D-KEFS subtest by CHD group as compared to controls

Figure 4

Table 4 BRIEF descriptive results and elevated subscale score percentages by CHD diagnosis

Figure 5

Table 5 Odds of clinically significant problems on BRIEF subscale by CHD group as compared to controls

Figure 6

Table 6 Paired t-test results comparing BRIEF self-report vs. parent/teacher ratings

Figure 7

Table 7 Correlations between D-KEFS and BRIEF variables for CHD and control groups