Mem Cogn
DOI 10.3758/s13421-015-0548-9
Working memory training in children: Effectiveness
depends on temperament
Barbara Studer-Luethi 1,2 & Catherine Bauer 3 & Walter J. Perrig 1,2
# Psychonomic Society, Inc. 2015
Abstract Studies revealing transfer effects of working memory (WM) training on non-trained cognitive performance of
children hold promising implications for scholastic learning.
However, the results of existing training studies are not consistent and provoke debates about the potential and limitations
of cognitive enhancement. To examine the influence of individual differences on training outcomes is a promising approach for finding causes for such inconsistencies. In this
study, we implemented WM training in an elementary school
setting. The aim was to investigate near and far transfer effects
on cognitive abilities and academic achievement and to examine the moderating effects of a dispositional and a regulative
temperament factor, neuroticism and effortful control. Ninetynine second-graders were randomly assigned to 20 sessions of
computer-based adaptive WM training, computer-based reading training, or a no-contact control group. For the WM training group, our analyses reveal near transfer on a visual WM
task, far transfer on a vocabulary task as a proxy for crystallized intelligence, and increased academic achievement in
reading and math by trend. Considering individual differences
in temperament, we found that effortful control predicts larger
training mean and gain scores and that there is a moderation
effect of both temperament factors on post-training improvement: WM training condition predicted higher post-training
gains compared to both control conditions only in children
* Barbara Studer-Luethi
barbara.studer@psy.unibe.ch
1
Department of Psychology, University of Bern, Fabrikstrasse 8, CH 3012 Bern, Switzerland
2
Center for Cognition, Learning, and Memory, University of Bern,
Bern, Switzerland
3
School for Teacher Education, Bern, Switzerland
with high effortful control or low neuroticism. Our results
suggest that a short but intensive WM training program can
enhance cognitive abilities in children, but that sufficient selfregulative abilities and emotional stability are necessary for
WM training to be effective.
Keywords Working memory training . Individual
differences . Intelligence
Introduction
There is increasing evidence that individual differences in
cognitive and academic performance share high variance with
basic capacity-limited processes, first and foremost by working memory (WM), defined as the capacity to retain and manipulate information (e.g., Engle, Tuholski, Laughlin, &
Conway, 1999; Pickering, 2006; Shah & Miyake, 1999).
Explanations of shared variance between WM, higher cognitive performances, and scholastic abilities are based on evidence of common capacity constraint (Halford, Cowen, &
Andrews, 2007), attentional control processes (Kane et al.,
2004), and overlapping neuronal networks in the lateral prefrontal and parietal cortices (Gray, Chabris, & Braver, 2003).
These findings have motivated attempts to improve WM capacity and with it the academic abilities of children by training
regimens targeting WM; such efforts challenge the long-held
view that WM capacity is primarily inherited and fixed (e.g.,
Engel, Heloisa Dos Santos, & Gathercole, 2008). Many of
these attempts have demonstrated that an intense period of
short-term WM training with children leads to improvement
in training-related tasks such as visual-spatial WM and executive functions (near transfer; see Diamond & Lee, 2011, for a
review). Even though most of these training studies do not
demonstrate far transfer or IQ improvements (e.g., Bergman-
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Nutley et al., 2011; Mackey, Hill, Stone, & Bunge, 2011; see
Diamond & Lee, 2011, for a review), some promisingly do,
for instance, by demonstrating improvements in measures of
fluid intelligence (Jaeggi, Buschkuehl, Jonides, & Shah, 2011)
or crystallized intelligence (Alloway, Bibile, & Lau, 2013).
Gains in measures of general intelligence after WM training are still rare, and evidence of improved scholastic abilities
after WM training with healthy school-aged children is even
more sparse. On the one hand, some studies found positive
evidence, giving rise to optimism (Titz & Karbach, 2014), for
example a laboratory study which showed increased reading
abilities after WM training (Looslie, Buschkuehl, Perrig, &
Jaeggi, 2011), and an investigation in a school setting which
demonstrated that WM-trained academically low-achieving
children made significantly greater progress across the academic year in mathematics and English than matched untrained pupils (Holmes & Gathercole, 2014). On the other
hand, there are also WM training studies which did not find
any significant progress in childrens’ academic or higherorder cognitive performance, thus casting doubt on the general
scope of WM-training-related improvements (e.g., Dunning,
Holmes, Gathercole, 2013; Thorell, Lindqvist, Nutley, Bohlin,
& Klingberg, 2009).
In recent years, this heterogeneity of training research results has given rise to a series of critical reviews or metaanalyses (e.g., Melby-Lervåg & Hulme, 2012; Shipstead,
Redick, & Engle, 2010, 2012). They primarily identify methodological reasons for the inconsistency of results, such as
inadequate control of study groups (Shipstead et al., 2012),
and suggest interpreting results with caution. However, methodological weaknesses should not belie the fact that WM
training shows a clear potential: The general trainability of
WM can be considered reliable, since near transfer on nontrained WM tasks is a consistent result in most of the training
studies with participants at every age (Melby-Lervåg &
Hulme, 2012), and several findings of far transfer to intelligence measures indicate the impact of WM training on important intellectual abilities (cf. Au et al., 2014; Buschkuehl &
Jaeggi, 2010; Bryck & Fisher, 2012; Klingberg, 2010).
These inconsistent training results have led to a recent shift
in research attention to the influence of individual differences
on training outcomes (e.g., Jaeggi, Buschkuehl, Shah, &
Jonides, 2014; Studer-Luethi, Jaeggi, Buschkuehl, & Perrig,
2012). However, such investigations are still in their infancy.
Whereas active compliance with training, stress, need for cognition, or beliefs about the malleability of intelligence have
been found to influence training outcomes in adults (Bagwell
& West, 2008; Jaeggi et al., 2014; Valentijn et al., 2005), perceived training task difficulty has been found to interfere with
training benefits in children (Jaeggi et al., 2011). Only very few
studies investigated the influence of personality characteristics
on cognitive training outcomes. Yesavage (1989) has suggested
that subjects with high scores of neuroticism show the least
profit from memory training, and Bäckman, Hill, and Rosell
(1996) state that subjects with depressive symptoms have difficulty in activating the necessary cognitive resources to
achieve improvement after training. Contrarily, training studies
in different fields found conscientiousness to be the strongest
predictor of training success (e.g., Barrick, Stewart, &
Piotrowski, 2002; Tziner, Fisher, Senior, & Weisberg, 2007).
Therefore, in a previous study, we investigated the moderating
effect of the personality traits neuroticism and conscientiousness on WM training outcomes in young adults (Studer-Luethi
et al., 2012). Results revealed a significant interaction of neuroticism and intervention in terms of training efficacy, in that
the demanding WM training task was more effective for participants low in neuroticism. Furthermore, conscientiousness
was associated with higher WM training scores and improvement in near-transfer measures.
To our knowledge, no study has yet investigated the moderating effect of these two prominent personality traits on cognitive training outcomes in samples of children. In children,
these individual differences can be found at the level of temperament: Whereas neuroticism, representing negative affectivity and increased emotional reactivity, is a temperament
factor that can be observed already in childhood (Eysenck,
1967), conscientiousness is a personality factor which only
fully develops after adolescence. Rothbart and her collegues
(2001) identified a temperament factor in childhood
representing the developmental process underlying conscientiousness, naming it effortful control (cf. Ahadi & Rothbart,
1994; Blair & Razza, 2007). Together, neuroticism and effortful control represent the two temperament categories reactivity
and self-regulation (Rothbart, Derryberry, & Posner, 1994).
Even though results regarding the interplay between these
temperament factors and general performance in cognitive
tests are very heterogeneous (see, e.g., Owens, Stevenson,
Norgate, & Hadwin, 2008; Seipp, 1991, for meta-analyses),
the theoretical assumptions and findings can serve as a framework for hypotheses about the influence of temperament on
cognitive training outcomes.
Dispositional temperament factors and their relationship
to working memory (WM)
Temperament refers to individual differences in emotional reactivity and the regulation of this reactivity (e.g., Ahadi &
Rothbart, 1994; Posner & Rothbart, 2000). At a neural system
level, emotional reactivity is mainly associated with the limbic
systems in the ventromedial prefrontal cortex, whereas selfregulation, the innate ability to maintain optimal levels of
emotional, motivational, and cognitive arousal (Eisenberg,
Hofer, & Vaughan, 2007; Liew, 2011), is mainly rooted in
the lateral prefrontal cortex and the anterior cingulate cortex
(ACC) (Botvinick et al., 2001). Temperament factors have
received increased attention during recent years, as they have
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been shown to play key roles in children’s academic success.
In a study by Blair and Razza (2007), self-regulation
accounted for unique variance in the scholastic achievements
independent of general intelligence (see also ChamorroPremuzic & Furnham, 2006; De Fruyt & Mervielde, 1996;
Duckworth & Seligman, 2005; Tangney, Baumeister, &
Boone, 2004). This relationship seems to be mediated by
WM capacity (e.g., Owens, Stevenson, Hadwin, & Norgate,
2014), or more specifically by attentional efficiency (see
Rueda, Posner, & Rothbart, 2005).
One dispositional component of emotional reactivity is the
hyperarousability of the limbic systems, labeled neuroticism
in Eysenck’s model of personality (1967). Neuroticism is related to higher excitability and emotional responsiveness,
resulting in a higher variability of emotional and motivational
states and the tendency to experience more negative emotions,
such as anxiety or distress. On the one hand, neuroticism and
related traits (e.g., anxiety) seem to generally diminish processing efficiency through disadvantageous arousal level as
well as emotional and cognitive resource-demanding interferences, such as worrisome thoughts or negative emotions. On
the other hand, in accordance with many studies showing the
effect of distress on aggravated operations in the prefrontal
cortex (for a review, see Arnsten, 2009), neuroticism-related
characteristics seem to mainly reduce resources available to
control attention by impairing processes in the central executive of WM (e.g., Bishop, 2009; Derakshan & Eysenck, 2009;
Eysenck & Calvo, 1992; Eysenck, Derakshan, Santos, &
Calvo, 2007; Gray et al., 2005; Schmeichel, Volokhov, &
Demaree, 2008; Shackman et al., 2006). These assumptions
were confirmed in neuroimaging studies revealing that neuroticism is associated with reduced neuronal efficiency and
impoverished recruitment of prefrontal attention control
mechanisms during a WM task (Bishop, 2009; Gray et al.,
2005). However, lower efficiency does not necessarily mean
lower efficacy, meaning quality of performance.
Investigations regarding WM task performance in relation to
neuroticism-related characteristics are very sparse, and the
published findings are inconsistent. To date, to our knowledge, there is no study demonstrating a significant association
between neuroticism and general WM performance in children. There is one study demonstrating a negative association
between the trait anxiety and verbal WM, but not spatial WM
(Visu-Petra et al., 2010), whereas another investigation found
a positive association between neuroticism and verbal WM in
adults (Arbune et al., 2015). These examples demonstrate that
more research is needed to disentangle the interaction of neuroticism and WM task performance (see also Hadwin, Brogan,
& Stevenson, 2005; DeYoung et al., 2009). As Eysenck and
Calvo (1992) put it, individuals with high anxiety often apply
compensatory strategies such as enhanced effort, which can
explain why they often reach task performance comparable to
individuals with low anxiety (cf. Eysenck & Calvo, 1992).
One predisposition for self-regulation skills is the temperament factor called effortful control (Rothbart & Bates, 2006).
It is believed to be associated with early-appearing individual
differences in self-regulation, and with it the developmental
process underlying conscientiousness (Ahadi & Rothbart,
1994). It allows individuals to voluntarily regulate their behavior in relation to current and future needs, as for instance to
inhibit a dominant response in favor of a subdominant response (Blair & Diamond, 2008; Derryberry, Reed, &
Pilkenton-Taylor, 2003). In temperament questionnaires, effortful control emerges from factors including shifting and
focusing attention, inhibitory control, perceptual sensitivity,
and low-intensity pleasure. As Rothbart and Rueda (2005)
postulate, the systems of this temperament factor provide the
flexibility required to master negative affect and consider potential actions in the light of principles. Effortful control overlaps substantially with inhibitory control (see Diamond,
2013), but while executive functions emerge from a neural
system approach with a historical focus on volitional control
of cognitive self-regulation, effortful control historically focused more tightly on automatic or nonconscious emotional
regulation (cf. Blair & Razza, 2007; see also Eisenberg,
Spinrad, & Eggum, 2010; Mischel & Ayduk, 2002).
Effortful control was found to facilitate performance efficiency by helping suppress distracting stimuli and monitor optimal
arousal maintenance for a given task (e.g., Blair & Diamond,
2008; Eisenberg et al., 2004; Rothbart, Ellis, Rueda, & Posner,
2003), as well as by improving internalized control
(Kochanska, Murray, & Harlan, 2000; Kochanska, Murray,
Jacques, Koenig, & Vandegeest, 1996) and the ability to deal
with conflict (see Rueda, Posner, & Rothbart, 2005).
Regarding the interplay of effortful control and task effectiveness (quality of performance), results show positive associations with scholastic abilities (e.g., Deater-Deckard,
Mullineaux, Petrill, & Thompson, 2009), but mixed findings
regarding performance in executive functions (e.g., Bridgett
et al., 2013). Some authors postulate the association of effortful control with heightened levels of evaluation apprehension
or the tendency to be self-deceptive as an explanation for these
inconsistent findings (e.g., Martocchio & Judge, 1997).
The current study
The current study investigates the effects of school-based WM
training in a sample of non-selected primary-school children.
We chose this setting because there is still a lack of findings
from natural learning settings as opposed to optimized laboratory settings, and we chose this sample because this provides a strong basis for the assessment of individual influences
on training results. The aim of this investigation was twofold.
Firstly, we aimed to investigate the near and far transfer
effects of WM training. On the basis of the empirical findings
discussed above, we hypothesized that WM training improves
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performances in WM, and that there might be far-transfer
effects on fluid or crystallized intelligence and on scholastic
performance of children who participate in WM training in
comparison to children who participate in an alternative training or in no training.
However, moderator variables are critical for understanding the generalizability of training results to subgroups. For
intervention research, moderator variables may reflect subgroups of persons for whom the training is more or less effective than for other groups (see MacKinnon, 2011). Therefore,
secondly, we sought to build upon previous findings in adults
showing the influence of neuroticism and conscientiousness
on WM training outcomes (Studer-Luethi et al., 2012).
Focusing on the corresponding temperament factors in children, we predicted that neuroticism and effortful control
would moderate training and transfer measures by affecting
the ability to deal with frustration and negative affect during a
WM training period:
1) WM training tasks largely rely on attentional control.
Based on the assumption that subjects with high neuroticism experience cognitive and emotional interferences
which decreases attentional control, processing, and storage resources of the WM system, we assume that neuroticism will negatively predict WM training efficiency and
with it training effectiveness regarding transfer. However,
since the WM training tasks are not too complex, compensatory effects could facilitate individuals with high
neuroticism to improve their training performance.
Consequentially, for the subgroup analyses, we hypothesized that children with low neuroticism scores will show
higher WM training average performance than but comparable training gain to children with high scores and that
WM training will show superior effects on untrained measures in comparison to the two control groups only in this
subgroup of children.
2) Successful suppression of distracting stimuli and the
monitoring of optimal arousal are necessary for an effective training process. Based on the assumption that
subjects with high effortful control have increased internalized control and a higher ability to deal with frustration and conflictual tendencies, such as wanting to stop
the task after a failure but at the same time wanting to
improve task performance and keeping up with others,
we assumed that effortful control would positively predict WM training performance and benefit regarding
transfer. Consequently, for the subgroup analyses, we
hypothesized that children with high effortful control
will show better WM training improvement than the
subgroup with low effortful control, and that WM training will show superior effects on untrained measures in
comparison to the two control groups only in this subgroup of children.
Method
Participants
A total of 99 second-grade elementary school children
(36 % female) were recruited in four public schools in
Switzerland. At the time of first data collection, the mean
age of the children was 8 years and 3 months (SD = .50).
Besides the written consent of the parents for their children
to participate in the study, no exclusion criteria were applied at recruitment. Most of the children (76.8 %) reported
German as their first language, and 23.2 % reported another language as their first language. None of them had any
problems understanding and speaking German. As a reward, all children received a medal after the completion
of the study.
After first data collection, we allocated the children of each
class to three study groups, matched for age, gender, and general intelligence. The experimental group completed
computer-based WM training (n = 34; mean age = 8.28 years;
SD = .43; 21 male), the active control group participated in
computer-based reading training (n = 31; mean age =
8.15 years; SD = .38; 19 male), and the third part was assigned
to a no-contact control group (n = 30; mean age = 8.49 years;
SD = .58; 22 male). We had to exclude the data of four children from longitudinal analyses due to their infrequent attendance at training (a minimal attendance of 17 sessions was
required).
Procedure
At the beginning of the study, teachers’ ratings (effortful
control) and parents’ ratings (effortful control, neuroticism) were collected to assess the temperamental factors
of the children. To assess performance in cognitive and
academic abilities, all children completed a battery of cognitive and academic ability tests during two regular school
lessons, 1–4 days before and then 1–4 days and 3 months
after the training period. A and B versions were used for
the pre- and the post-tests in counterbalanced order. With
the exception of the memory span task, which was individually administered, all the tests were carried out as a group
with the whole class. The self-reported personality questionnaire to measure neuroticism was conducted with the
children pre-testing.
The children of the WM-training and reading-training
groups completed daily training sessions of 15 min in groups
of six to 13 children in the computer laboratories of the
schools for four consecutive weeks on school days, resulting
in 17–20 training sessions. The children of the no-contact
control group stayed in the classroom with their respective
teacher.
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Material
games targeting reading comprehension, syntax, and word
recognition, among other elements.
Training tasks
WM training comprised two different tasks, the single n-back
task and the animal span task. In every training session, both
of the training tasks were applied in the same order.
WM single n-back task We chose an adaptive visual-spatial
single n-back task, similar to the task used in other WM training studies (e.g., Jaeggi, Studer-Luethi et al., 2010). A sequence of visual stimuli was shown to the children. Each
stimulus was presented for 500 ms and was followed by a 2,
500-ms interstimulus interval. During this interval, the children had to respond by pressing a pre-defined key each time
when the location of the current stimulus was identical to one
presented n positions back in the sequence; no response was
required for non-targets. The stimulus material consisted of
squares in a different color for each level of n. The level of n
was increased by one if the child made fewer than three mistakes, and it was decreased by one if the child made more than
five mistakes. One training session comprised 5–6 blocks
consisting of 6+n trials. After each block, children received
feedback concerning their performance (percent correct). The
average level of n of every training session served as the
dependent variable defining the training performance, whereas the difference between the last two training sessions and the
first two training sessions served as the dependent variable
training gain.
WM animal span task As a second training task, we chose an
adaptive WM span task as used before (see Looslie et al.,
2011). In this task, children were presented with a sequence
of pictures of animals either normally oriented or upsidedown. Firstly, they were asked to decide as quickly as possible
on the orientation of the animal by pressing the right or the left
mouse button. If children waited longer than 3,000 ms to give
their answer, they were reminded to respond more quickly.
Secondly, at the end of each animal sequence, they were asked
to reproduce the chronological presentation order by clicking
on the animals. Children received performance feedback and
the next sequence length was increased by one if the child
made no mistakes in orientation decisions and reproduction
of the sequence. Similarly, it was reduced by one if the sequence was not correctly reproduced. The averaged sequence
length of every training session served as the dependent variable defining the training performance, whereas the difference of the last two training sessions and the first two training
sessions served as the dependent variable training gain.
Reading training We used a computer-based reading training
program (Lesewerkstatt; Isler, Bünzli, Fehr-Biscioni, &
Tresch, 2010), which included a number of different reading
Scholastic ability tests
Reading We applied a widely used German reading ability
assessment which demonstrated good external validity, the
Knuspels Lesetest (KNUSPELS-L; Marx, 1998). Of four subtests, three were selected for the current study: phonological
encoding, phonological recoding, and reading comprehension. The first subtest requires children to read pronounceable
pseudowords and to decide whether they sound like a real
German word. In the second subtest, they have to decide
whether pronounceable pseudoword pairs have the same pronunciation, although spelt differently. The third subtest requires children to carefully read sentences and exactly execute
the task described. The sum of the correct responses in all the
subtests was taken as the dependent variable indicating general reading ability.
Mathematics To measure mathematical abilities, we used the
Deutscher Mathematiktest für zweite Klassen (DEMAT 2+;
Krajweski, Liehm, & Schneider, 2004). The test contains subsets dealing with characteristics of numbers, comparison of
length, addition and subtraction, duplication and bisection,
division, and counting with money. All subtests were included
in our study. We chose the sum of all subtest scores as the
dependent variable.
Cognitive ability tasks
Proxy for crystallized intelligence (Gc) A vocabulary task
was used as a measure of Gc, the Wortschatztest taken from
the Culture Fair Intelligence Test (CFT; Grundintelligenztest
CFT 20; Weiss, 1991). The test consisted of 30 words of
colloquial vocabulary, which are not part of the basic vocabulary of the German language. Each task included a key word,
and the children were asked to choose the word with the same
or closest meaning from a sample of five words. They were
allowed to work for 6 min. The number of correct word
choices served as the dependent variable.
Proxy for fluid intelligence (Gf) Fluid intelligence was
assessed using either the even or odd items of Raven’s
Progressive Matrices in counterbalanced order (RPM, 30
items; Raven, 1998). After two practice trials, children were
allowed to work for 10 min and cross the right solution for
each task. The number of correct solutions provided in this
time limit was used as the dependent variable.
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WM and inhibition
WM To measure WM capacity, a backwards color recall task
was included (see Roethlisberger, Neuenschwander, Michel,
& Roebers, 2010). The task was carried out individually with
each child. Children were presented with a sequence of colored discs on a computer screen and were asked to recall the
sequence in the reverse order. The presentation time for each
disc was 1 s. Sequence length was two at the beginning and
increased by one item when the child correctly recalled two of
three sequences on a particular level. The dependent variable
was the number of trials of correctly reproduced sequences of
colors (Schmid, Zoelch, & Roebers, 2008).
Stroop task To measure cognitive control (inhibition component) of children, we used the fruit and vegetable Stroop task
(Roethlisberger et al., 2010), an adapted form of the fruit
Stroop task used by Archibald and Kerns (1999). The child
had four tasks, each consisting of a practice trial and an experimental trial. In the first task, colored squares were presented, and in the second task, fruit and vegetables in their correct
colors. Children were asked to name the colors they saw as
fast as possible (congruent condition). In the third and fourth
tasks, the fruit and vegetables were black and white and in
wrong colors, respectively. Children were asked to name the
correct color of the fruit and vegetables as fast as possible
(incongruent condition). The degree of interference served as
the dependent variable and was computed according to the
formula in Archibald and Kerns (1999).
Temperament questionnaires
Effortful control Information on a child’s effortful control
was obtained by teachers (21 items; Cronbach’s α = .93)
and parents (nine items; Cronbach’s α = .66) using the questions from the Children’s Behavior Questionnaire (CBQ;
Putnam & Rothbart, 2006; adapted from Blair & Razza,
2007; cf. Michel, Roethlisberger, Neuenschwander, &
Roebers, 2011). None of the other subscales of the CBQ were
assessed. Teachers and parents responded on a 7-point Likert
scale to express their opinion of how well a description of a
behavior fitted that of the child. Questions referred to attention
(e.g., Bshows strong concentration when drawing or coloring
in a book^), inhibitory control (e.g., Bis good at following
instructions^), anger (e.g., Bgets angry when s/he can’t find
something^), and approach (e.g., Bbecomes very excited before an outing^). The return rates of teacher and parent questionnaires were 100 % and 92 %, respectively. The average
score of both questionnaires was used as the dependent variable indicating the level of effortful control of the participants.
Neuroticism We used a self-reported questionnaire, form 1 of
the Hamburger Neurotizismus- und Extraversionsskala für
Kinder und Jugendliche (HANES, KJ; Buggle &
Baumgaertel, 1975) and a parent-reported questionnaire, the
Hierarchical Personality Inventory for Children, designed for
children between 6 and 12 years of age (HiPIC; Mervielde &
De Fruyt, 1999), for the assessment of the personality traits.
The HANES questionnaire is based on Eysenck’s (1967)
model of personality and is one of the German personality
questionnaires most commonly used for children and adolescents. The questions were read out loud to the class and children responded with yes or no to each question. The HiPIC
assesses the dimensions of the five-factor model of personality
with the different facets hierarchically organized under these
higher-order factors. Anxiety and self-confidence are the two
facets regarding neuroticism. Parents were asked to indicate
on a 5-point Likert scale the degree to which each statement
was characteristic of their child. For this study, only the neuroticism subscale was included in the analysis.
Results
First, data from the temperament questionnaires were analyzed. The intercorrelation of the neuroticism scale in the
self-reported and parent-reported questionnaires was r = .32
(p < .01). Regarding effortful control, the intercorrelation of
the teachers’ and parents’ ratings was r = .44 (p < .001).
Therefore, for both traits, the average score of both questionnaires was used in our data analysis. Furthermore, a correlation between the effortful control score and the behavioral
result from the cognitive control test, the Stroop task, was
detected (r = −.26, p < .01), supporting the validity of the
questionnaires.
Next, we calculated standardized gain scores for the cognitive measures and the scholastic ability tests (gain divided
by the standard deviation of the whole sample at pretest; cf.
Jaeggi et al., 2011).
For the analyses of the subgroups based on individual
differences in neuroticism and effortful control, subjects
were assigned to three subgroups (with low, medium, and
high scores) based on values around the mean and ± 1
standard deviation (SD) from the mean, as this is often
done for personality traits (cf. Jokela et al., 2013).
Because of the intercorrelation of neuroticism and effortful control (r = −.21, p < .05), a combined measure of the
mean z-scores of both temperament traits was computed.
Neuroticism scores were recoded to have the same direction as effortful control. That is, a higher combined temperament score represents higher effortful control and
emotional stability. This combined measure represents
self-regulation, as it combines innate temperamental predispositions to exercise better self-regulation and to maintain an optimal level of emotional arousal (Diamond,
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2013). The same subgroup recoding was done for this
combined measure.
Correlations among the cognitive and scholastic scores of
all participants as well as from the training and transfer variables of the WM training group, together with the reliability
data, are reported in Table 1. Note that only the two transfer
factors that showed significant improvement patterns are included in the table.
Overall WM training data
Children significantly improved their performance in the WM
training tasks (animal span: t(32) = 8.85, d = 3.13; n-back:
t(32) = 5.42, d = 1.92; both ps < .001), from an average animal
span level of 2.28 (.27) in the first two sessions to a level of
3.28 (.46) in the last two sessions, and from an average n-back
level of 1.41 (.27) to an n-back level of 1.89 (.46) (see Fig. 1).
For the reading training group, no training data were
registered.
Overall transfer data
To examine training benefits, we conducted ANOVAs for repeated measures (pretest and post-test session) and analyzed
the improvement pattern as a function of group (WM training
vs. reading training vs. no-contact control). Regarding near
transfer on WM performance, there was a significant group
Table 1
× session interaction at the p < .10 level on the improvement in
the backward color span task (group × test session: F(2,92) =
2.09, p = .065, ηp2 = .06), showing that the WM training
group was the only one significantly improving from pretest
to post-test (t(34) = 3.64, p < .05; see Fig. 1a). There was no
such significant interaction regarding performance in the
Stroop task (F < 1).
Regarding far transfer, our analyses revealed a significant differential training effect on the measure of vocabulary (group × test session: F(2,92) = 4.42, p = .02; ηp2 =
.10, again establishing the WM training group as the only
group with significant improvements from pretest to posttest (t(32) = 2.55, p < .05, see Fig. 1b). We found no
significant training group interaction on the performance
in the Raven’s Progressive Matrices (F(2,92) = 1.57, p =
.22, ηp2 = .004).
Regarding scholastic abilities, the children of the WM
training group demonstrated greater improvement by
trend compared to the rest of the sample, but the group
× test session interaction did not reach significance (math:
F(2,92) = 1.22, p = .15, ηp2 = .02; reading: F(2,92) =
2.33, p = .10, ηp2 = .04).
Considering individual differences in transfer, there was a
positive association between WM task performance at pretest
and near transfer (r = −.50, p < .01) as well as far transfer (r =
−.12, p < .05), suggesting stronger profit for children with
initially lower WM capacity (see Table 1).
Correlations between cognitive baseline, training, and temperament variables
(1)
Cognitive measures
(all participants)
(1) Working memory (WM) (MS) (MS)
(2) Vocabulary (Gc)
(3) Matrices (Gf)
(4) Reading
(5) Math
Training outcomes
(WM training group)
(6) Training mean
(7) Training gain
(8) Near transfer to WM WweeefefefWs?MS
(9) Far transfer to Gc
Temperament factors
(10) Neuroticism
(11) Effortful control
(2)
(3)
(4)
(5)
(6)
(7)
(8)
-
(9)
(10)
(11)
.78
-.21*
.80
.25
.02
.12
.18*
.27**
.68**
.81
.78
.22*
.79
-.02
.36**
.47**
.35**
.83
-.19
.17
-.50**
.29*
.12
.42**
.46**
.03
.25
.34*
.43*
.06
.44**
.12
.22
.49**
.16
-.19
-.12*
-.01
.40*
.12
.37
.49**
.18
.03
.16
-.11
.20*
-.21*
.36**
-.08
.21*
-.36*
.29**
-.32*
.54**
-.09
.33*
-.06
.04
-.28*
.24
Note: N = 99; n = 33; *p < .05; **p < .01; values in italics represent test-retest reliabilities of the control group and Cronbach’s alpha for the temperament
variables
Working memory (WM) = backward color recall task; Gc = proxy for crystallized intelligence (vocabulary task); Gf = proxy for fluid intelligence (matrix
reasoning task); Training mean = average training level over all training sessions; Training gain = last two training session – first two training sessions
�Mem Cogn
B) Far trransfer on vocabulary
v
y
A) Near trransfer on WM
W
12
*
7
6
WM traaining group
5
Ac�ve control group
Score in vocabulary task
Score in working memory task
8
11
*
10
9
8
WM trraining group
7
Ac�vee control group
No-contact control group
No-con
ntact control group
6
4
P
Pre
Post
Prre
Postt
Fig. 1 a Gain scores in memory span and b gain scores in vocabulary (proxy for Gc, crystallized intelligence) as a function of the intervention group.
Error bars represent standard errors of the mean. *p < .05. WM = working memory
Long-term effects of training
We found no significant long-term effects in the variables
memory span, cognitive control, Gf, Gc, and scholastic tests
(all T < 1.4).
Moderator variables: Neuroticism and effortful control
Correlations of the temperament factors with the cognitive
baseline and training measures are shown in Table 1.
Effortful control was positively related to pretest performance
in the scholastic measures and intelligence tests Gc and Gf.
Regarding the WM training group, effortful control was positively associated with the average training level during the
4 weeks of training, the training gain, and by trend with the
gain score in Gc. In contrast to this, neuroticism was negatively associated with Gf and math scores and, regarding the WM
training group, it was negatively related to the average training
level and the gain score in Gc.
Generally, WM performance in pretest was negatively correlated with the transfer gain scores in WM and Gc, suggesting that children with lower WM capacity profited most from
the WM training.
training gain, temperament variables accounted for 16 % of
the variance (p < .05, f2 = .19), whereas the initial task performance did not account for variance of this factor. Looking at
the contributions of the temperament variables to the prediction models, it appears that only effortful control was a significant unique predictor, whereas the effects of neuroticism
disappeared.
Figure 2 shows the performance in both WM training tasks
of the subgroups with high, medium, and low neuroticism and
effortful control, respectively. Regarding neuroticism, the performance difference between the subgroups was not significant (see Fig. 2a and b). Regarding effortful control, high
scorers clearly yielded higher levels of training performance
(average training level in both tasks = 2.61(.29)) than children
with average (2.29(.27); t(27) = 3.03, p = .003, d = 1.14) and
low effort control (2.15(.27); t(20) = 3.23, p = .002, d = 1.64).
More importantly, children with high effortful control showed
significantly higher training gain (average training gain in
both tasks = 0.82(.39)) than children with low effort control
(0.37(.34); t(19) = 2.29, p = .015, d = 1.23 ). As shown in
Table 2 Results of regression analyses testing main effects of
neuroticism and effortful control on working memory training
performance
Effortful control predicts WM training success
To disentangle the effects of the temperament variables on
training outcome exceeding the influence of initial training
task performance, general linear models were performed separately for the mean training level and the training gain score
as dependent variables. As predictors, the score in the first two
training session was entered in step 1, and both temperament
variables were entered in step 2 (see Table 2).
Results indicated that temperament variables accounted for
20 % of the variance of average training score, which significantly improved the prediction model (p < .01, f2 = .25) after
controlling for the influence of initial training task performance accounting for 41 % of the variance. Regarding
Average training level
Initial task performance
Step 2
Neuroticism
Effortful control
Training gain score
Initial task performance
Step 2
Neuroticism
Effortful control
R2 change
B
SE B
β
.41**
.20**
.69
.01
.35
.15
.01
.05
.64**
.11
.48**
<.00
-.17
-.26
-.12
.16*
.06
.44
.08
.20
.14
.45*
Note. N = 99; n = 33; * p < .05, ** p < .01; gender and age were entered on
Step 0
�Mem Cogn
B) Animal span training & neuroticism
A) N-back training & neuroticism
4
2.2
3.5
Mean n-back score
2
1.8
1.6
1.4
1.2
High Neuro
Medium Neuro
Low Neuro
Mean animal span score
2.4
3
2.5
2
1
1
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
D) Animal span training & effortful control
2.4
4.5
2.2
4
2
3.5
1.8
1.6
1.4
1
High EC
Medium EC
Low EC
Mean animal span score
Mean n-back score
C) N-back training & effortful control
1.2
High Neuro
Medium Neuro
Low Neuro
1.5
3
2.5
2
High EC
Medium EC
Low EC
1.5
1
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
Fig. 2 Mean training level (n-back task, animal span task) obtained during working memory training as a function of neuroticism (Neuro) and effortful
control (EC) (recorded in three groups: high/medium/low scores). Error bars represent standard errors of the mean. *p < .05
Fig. 2d, the moderation effect of effortful control was most
obvious in the animal span task, a less complex and more
monotonous WM training task than the more stimulating nback task.
training group and pre-post gain varies according to the level
of temperament, as demonstrated in the following subgroup
analyses.
Subgroup analyses of training effects
Causal interaction of intervention and temperament
on pre-post gain
To test moderator effects of temperament on pre-post gain in
the intervention groups, multiple regressions were performed
separately for the near- and far-transfer measures with standardized gain score entered as the dependent variable and, in
the first step, intervention group as well as temperament traits
as independent variables. In the second step, the interaction
term (intervention group × temperament) was added to the
equation (see Baron & Kenny, 1986). Interaction terms were
created by multiplying the centered temperament scores with
the group dummy variables.
Whereas the statistical interaction term of neither neuroticism × intervention nor effortful control × intervention became significant, the interaction of the combined temperament
measure self-regulation × intervention significantly improved
the prediction of WM gain (β = .22, t(84) = 1.53, p = .06, f2 =
.26) as well as the prediction of vocabulary gain (β = .20, t(83)
= 1.88, p = .03, f2 = .24). That is, the relationship between
Figure 3 visualizes the improvements in WM and Gc performance of the WM training group at different levels of neuroticism (Fig. 3a and b) and effortful control (Fig. 3c and d). As
can be seen, the subgroups with high neuroticism and low
effortful control, respectively, showed no transfer effects, justifying presenting data of the combined self-regulation measure (see Fig. 4).
General linear models (ANOVAs) with group (WM training vs. reading training vs. no-contact control) as the independent variable and the gain scores of WM and Gc performance
were computed separately for the subgroups with
high/medium/low self-regulation. Regarding near transfer on
WM, a significant intervention group × session interaction on
the improvement in the measure of WM was found only in the
subgroup with high emotional regulation (group × test session: F(2,39) = 3.42, p < .05, ηp2 = .14). There was no such
significant interaction in the subgroup with medium emotional
regulation (F(2,28) = 1.28, p = .49, ηp2 = .04) nor in the
subgroup with low emotional regulation (F(2,10) = .056, p =
�Mem Cogn
A) Gain in WM (near transfer)
B) Gain in Gc (far transfer)
0.8
0.4
Stand. score in vocabulary test
Stand. score in WM task
0.6
0.4
0.2
0
High Neur
-0.2
Mean Neurr
-0.4
0.2
0
High Neur
-0.2
Mean Neur
Low Neurr
Low Neur
-0.6
-0.4
Pre
Post
Pre
D) Gain in Gc (far transfer)
C) Gain in WM (near transfer)
0.6
0.6
0.4
0.2
0
High EC
-0.2
Medium EC
Low EC
-0.4
Stand. score in vocabulary test
Stand. score in WM task
P
Post
0.4
0.2
0
High EC
-0.2
Medium EC
Low
w EC
-0.4
Pre
Post
Pre
Post
Fig. 3 Gain in working memory (WM) performance (backward color
span task) and gain in vocabulary performance (proxy for Gc, crystallized
intelligence) as a function of the intervention group, WM training group
(WMT) versus active control group (AC) versus no-contact control group
(PC), and of the combined temperament trait self-regulation (recoded in
three groups: high/medium/low self-regulation (SR)). Error bars represent
standard errors of the mean. *p < .05
.95, ηp2 = .02). Regarding far transfer, subgroup analyses
again revealed a significant differential training effect on the
measure of vocabulary only in the subgroup with high emotional regulation (group × test session: F(2,42) = 5.54, p < .01,
ηp2 = .20), whereas no such interaction was detected in the
subgroups with medium emotional regulation (F(2, 30) =
2.62, p = .09, ηp2 = .07) within the subgroup with low emotional regulation (F(2,12) = .64, p = .55, ηp2 = .03). These
results are presented in Fig. 4 and show that children scoring
high in self-regulation reach the highest transfer effects in the
WM training group, clearly outperforming the children from
the active and the no-contact controls.
Stand. gain score in WM task
1.4
1.2
1
0.8
WMT
0.6
AC
0.4
PC
0.2
0
Stand. gain score in vocabulary task
B) Gain in Gc
A) Gain in WM
1
0.8
0.6
WMT
0.4
AC
0.2
-0.2
-0.2
High SR
Mean
n SR
Low SR
Fig. 4 Near transfer to working memory (WM) performance (backward
color span task) and to vocabulary performance (proxy for Gc,
crystallized intelligence) as a function of neuroticism (Neur) and
PC
0
H SR
High
Me
ean SR
Low
w SR
effortful control (EC) (recorded in three groups: low/medium/high
scores) of the WM training group. Error bars represent standard errors
of the mean. *p < .05
�Mem Cogn
Discussion
Studies investigating effects of WM training in healthy children have led to inconsistent conclusions about near and far
transfer effects on non-trained tasks. This study aimed to test
such training effects in a school setting and to examine whether individual differences in neuroticism and effortful control
can account for some differences in training and transfer success exhibited by children.
In this context, emphasis should be placed on two results
from our analysis. First, WM training brings about a significant
improvement in both a near-transfer WM task and a far-transfer
task of crystallized intelligence. However, we intended not only
to answer the hypotheses of Bif it works^ but also Bfor whom it
works^ (see Wu & Zumbo, 2008). That is, the moderator analysis allows us to understand to what degree WM training is
more or less effective for subgroups of children. Therefore our
second result is not less important, as it shows the critical role of
temperament dispositions regarding training performance and
transfer profit: Only children with low neuroticism and high
effortful control, respectively or taken together, with high
self-regulation profited from the WM training and
outperformed the active and the no-contact controls, whereas
this intervention did not show any impact for children with high
neuroticism and low effortful control.
With regard to the first finding, children who took part in
the WM training significantly improved their performance
both in a backward color recall task, a measure for WM, and
in a vocabulary test, a proxy for crystallized intelligence (Gc),
in comparison to an active and no-contact control group.
Participants in the WM training group had an average increase
of almost 2 to 3 test points in WM and Gc measures, respectively, which represents a gain of 40–50 % in performance.
Comparable to previous findings, children with initially low
WM and therefore more room to improve showed higher
transfer (see Au et al., 2014, for a review). Furthermore, transfer was found to be positively related to the average WM
training score as well as associated with a trend to training
gain (cf. Jaeggi et al., 2011). Regarding near-transfer performance on the WM task, the results replicate findings from
studies demonstrating improved performance in non-trained
WM tasks after an intense training period (e.g., Dahlin et al.,
2008; Schmiedek, Lovden, & Lindenberger, 2010). Bearing in
mind the significance of WM capacity for scholastic achievements, this result indicates promising possibilities for school
settings, as for instance in the support of children with poor
WM. Our far transfer result on a measure of Gc is comparable
to the outcome of a WM training study by Alloway and her
colleagues (2013). Based on the assumption that WM capacity
is a crucial factor for learning and the ability to acquire new
knowledge (cf. Gathercole, Alloway, Williw, & Adams,
2006), we suppose that the WM training applied in this study
improved WM capacity and with it the acquisition of new
knowledge, on the one hand, and the activation of present
knowledge, on the other. Furthermore, as the CFT vocabulary
task requires choosing a synonym from a choice of five words,
it puts considerable strain on WM. The meaning of the target
word needs to be decoded and memorized while decoding the
five response options and comparing their meanings with the
target word. Even though it would be premature to draw
strong conclusions about this result, a supposition regarding
the improvement in vocabulary is that WM training can be
especially beneficial for children with word-activation problems, a hypothesis that needs to be corroborated in further
research.
The question on whether and how long transfer effects last
beyond the training period is still unresolved. In our study, we
did not find long-term maintenance of transfer effects of WM
training, which is in line with other short intervention studies
(e.g., Buschkuehl et al., 2008; Kronenberger et al., 2011). We
can only speculate about reasons, such as reduced motivation
in the follow-up testing, or simply that the transfer effects were
not strong enough to endure cognitive inferences following
the intervention. However, there are a handful of studies providing encouraging evidence of long-term maintenance of
transfer effects (e.g., Alloway et al., 2013; Borella et al.,
2013; Holmes, Gathercole, & Dunning, 2009; Jaeggi et al.,
2011; Salminen, Strobach, & Schubert, 2012). Much more
research is needed into the possible reasons for training profit
sometimes lasting and sometimes disappearing, and if
methods like the occasional practice of booster sessions might
be necessary in order to achieve better long-term effects (see
e.g. Cepeda, Pashler, Vul, Wixted, & Rohrer, 2006).
Furthermore, we did not find significant transfer to matrix
reasoning as a proxy for Gf, or to the scholastic ability tests.
On the one hand, our data fail to replicate some earlier findings from WM training studies with school-aged children,
which found improvement in Gf (e.g., Jaeggi et al., 2011) or
in reading skills (Chein & Morrison, 2010; Looslie et al.,
2011). On the other hand, the results are in line with a handful
of studies which did not find far transfer on Gf or scholastic
abilities (e.g., Holmes et al., 2010; Thorell et al., 2009). Some
researchers presume that the lack of transfer to scholastic
achievement as measured with standardized test instruments
might not reflect actual improvement in everyday school performance (cf. St. Clair-Thompson, Stevens, Hunt, & Bolder,
2010). In any case, the aim is to enhance scholastic achievement rather than performance on laboratory-based assessments, therefore our results represent open questions and limitations on the utility and effectiveness of WM training. But
even more than that, these findings point to the need to further
investigate moderating variables regarding training regimen
and individual factors which might explain some sources of
these inconsistent results regarding WM training effects.
Regarding our second goal investigating the effects of two
prominent temperament variables, namely on neuroticism and
�Mem Cogn
effortful control, on training outcomes, we found that they do
account for significant variance in training performance and
improvement in untrained tasks. It is important to note that we
observed no differences in baseline WM and cognitive task
performances as a function of temperament. Therefore, none
of the described effects of temperament on training and transfer can be attributed to initial performance differences.
Regarding training performance and gain, even though effortful control did not relate to WM performance at pretest,
our analyses revealed that effortful control is a good predictor
for WM training mean and gain scores. It seems that individuals with low effortful control can show improved WM performance by increasing effort for the task, but that good effortful control is needed for a successful WM training by
enabling a child to efficiently regulate emotional and cognitive processes and maintaining motivation and the optimal
arousal for the training task (see Blair & Diamond, 2008).
Effortful control is furthermore associated with successfully
regulating external or internal distractions, which in our case
was crucial for successful training, since training was conducted in groups in the classroom (cf. Carver, 2004). The differences between the subgroups were most obvious in the animal
span task. This training task is less complex and more monotonous than the n-back task. Therefore, this result confirms the
suggested role of effortful control to keep up training motivation and focused concentration even when the training task
becomes monotonous and tedious.
Regarding neuroticism, we found a relation with decreased
WM training average score of children (r = −.32). This replicates our previous result found in a sample of young adults (r =
.24; Studer-Luethi et al., 2012). This effect can be attributed to
cognitive and emotional interferences or stressful thoughts that
adversely affect WM training performance, as the training
largely relies on attentional control. Therefore, when effortful
control and neuroticism were entered in the same prediction
model for training performance, neuroticism did not explain
additional significant variance in training performance. The
experience of stress was shown to impair complex operations
in the prefrontal cortex, but it could also improve the performance of simple or well-rehearsed tasks (see Arnsten, 2009).
This is in line with the finding that neuroticism is not negatively
related to WM training gain (r = −.09, n.s.), again replicating
our previous finding in young adults (r = −.03, n.s., StuderLuethi et al., 2012). Correspondingly, subjects with neuroticism were able to improve their WM training scores to levels
comparable to emotionally more stable children. Another explanation comes from Eysenck and Calvo (1992), postulating
that highly anxious individuals are afraid of negative evaluation
and therefore highly motivated to improve their performance.
That is, as the WM training tasks were not too complex, individuals with high neuroticism managed to compensate for their
lower performance efficacy and reach good task performance
by increasing their effort and using strategies. Furthermore, this
finding is in line with accumulating research demonstrating that
WM training can be beneficial for emotionally vulnerable subjects to improve cognitive performance and neural function,
and even more than that, to increase regulation skills (see,
e.g., Owens, Koster, & Derakshan, 2013).
Regarding transfer after training, our results show that the
combined temperament measure representing self-regulation
moderates observed improvements on WM and vocabulary in
the WM training group. In other words, near and far transfer
found in this investigation are critically dependent on the participants’ level of neuroticism and effortful control, showing
the best result if combined in a self-regulation measure: WM
training leads to superior gains in near- and far-transfer measures in comparison to the control groups only in subjects with
good self-regulation, i.e., with low levels of neuroticism and
high levels of effortful control. A speculative interpretation of
this result would be that the cognitive load of the cognitive
tasks and imposed by low self-regulation skills (e.g.,
distracting thoughts and emotions, experience of distress) as
well as the suboptimal levels of arousal impede complex operations in the prefrontal cortex and diminish transfer processes to higher cognitive abilities (see also Arnsten, 2009). That
is, the effectiveness of the WM training seems to depend on
the dispositional self-regulation abilities of a child in order to
control for stressful thoughts and avoid detrimental influences
on PFC operations. This result is important from a treatment
point of view, because WM training should not hold claims to
efficacy for children if there is evidence that there are subgroups for which the intervention is ineffective. For these
subgroups, alternative interventions focusing on other cognitive or emotional abilities may be more effective.
To sum up, our findings demonstrate the potential of an
adaptive WM training, implemented in a regular school setting,
to improve task performance in a near-transfer measure and in a
far-transfer measure, and that neuroticism and effortful control
are relevant variables when seeking to explain individual differences in both the training achievement and the transfer performance. That is, effortful control abilities seem to be necessary to perform well in WM training and show significant
improvement in the training task, which can be attributed to
the greater ability to focus attention on the training task and to
inhibit impulsive responses, such as letting boredom and
demotivation take over. Also, good effortful control and emotional stability, which can be summarized as self-regulation,
seem to be necessary for the benefits of the training to extend
to non-trained abilities. This is an important message to be
considered in future training research and training regimens.
Limitations and implications
Some limitations have to be considered. The sample size for
the comparison of the subgroups was rather small, so some of
�Mem Cogn
the null effects might have resulted from a lack of power.
Also, we did not statistically control for multiple comparison
and need to acknowledge that the transfer effects found are
preliminary and require replication.
The results of the present study contribute to the call for
evidence on factors that moderate WM training success (cf.
Jaeggi et al., 2011; Morrison & Chein, 2011) and to the
growing body of literature linking temperament with cognitive performance and learning (e.g., Duncan et al., 2007;
McClelland, Morrison, & Holmes, 2000). The knowledge
of subgroups for which WM training seems ineffective is
important from a program development perspective because
this can spur further research to find out what works for these
groups so that they are not marginalized. It can move us
closer to the goal of personalized treatment programs that
match the needs of particular groups and individuals. That
is, regarding children with good self-regulation, our findings
indicate the potential of fostering their cognitive abilities by
means of adaptive WM training. Regarding children with low
self-regulation abilities, on the one hand, it could be more
beneficial to promote self-regulation so as to increase learning and training processes, in order to strengthen the ability to
acquire new knowledge, and to develop scholastic abilities
(see also Blair & Razza, 2007). Even though most researchers
recognize that some individual differences in the capacity for
mastering emotionally challenging tasks are biologically
grounded, most approaches assume that a significant proportion of self-regulation skills can be improved with practice
and training (cf. Diamond, Barnett, Thomas, & Munro,
2007). For example, Lyons and Beilock (2011) concluded
from their findings that schools should implement educational interventions which emphasize self-regulation rather than
additional skill training in order to support children with
scholastic weaknesses. A study which implemented such a
classroom curriculum demonstrated improved cognitive control of preschool children (Diamond, Barnett, Thomas, &
Munro, 2007). Additionally, a growing number of interventional studies have demonstrated that specific training programs targeting attention, focusing, and control can scaffold
attentional control and self-regulation skills (e.g., Rueda,
Rothbart, McCandliss, Saccamanno, & Posner, 2005; Tang
et al., 2007). On the other hand, results from studies
implementing cognitive training, such as emotional WM
training, point to the high potential of cognitive training to
be beneficial regarding affective and attentional control for
both healthy and emotionally vulnerable subjects (e.g.,
Owens, Koster, & Derakshan, 2013; Schweizer et al., 2013).
Finally, the aim should be to design effective programs that
focus on the unique needs of an individual. Such interventions
should increasingly be promoted in schools and other institutions. More research is warranted to further disclose the role of
individual differences in cognitive abilities, training, and
transfer.
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