Can Training Balance, or Enjoying Music, Improve Attention, Problem-solving and/or Behavior Control Abilities?

Postural Balance Clinical Trial

Official title: Can Training Balance, or Enjoying Music, Improve Executive Functions of Children?

Status Not yet recruiting

Clinical Trial Summary

This randomized controlled trial will investigate the hypothesis that since balance and executive functions (EFs) require a similar neural circuit and EFs are recruited when trying to maintain balance, that training balance might improve EFs as well as balance. There will be an active control condition (watching music videos) and a no-treatment condition. Children (18-12 years old) will be randomly assigned to one of these conditions for 12 weeks (36 per condition). The balance and music conditions will involve 15-min sessions 3x/week and a weekly check-in session with an investigator. Participants will be assessed pre-intervention, immediately post and 3-months post.

Clinical Trial Description

Executive functions (EFs) are critical for success in school and in life, physical and mental health, a good quality of life, and social harmony (Miller et al., 2011; Moffitt et al., 2011; Wolfe et al., 2016; Wong et al., 2010). Indeed, EFs have even been found to be more predictive of academic & career success than socio-economic status (SES) or intelligence quotient (IQ) (Alloway & Alloway, 2010). It is well established that EFs depend on prefrontal cortex (PFC) and other brain regions with which it is interconnected (Bunge et al., 2002; Diamond, 2002; Duncan & Owen, 2000). Recently, it has been demonstrated that much of balance (especially when there is reduced sensory input [e.g., eyes closed] or a reduced base of support [e.g., feet together or one leg raised]) requires PFC (Bauby & Kuo, 2000; Kwag & Zijlstra, 2022; St George et al., 2021). In fact, increased PFC activity appears to compensate for sensorimotor deficits to maintain balance in older adults (St George et al., 2021), and dorsolateral PFC has found to be significantly activated after external perturbation of postural stability (Karim et al., 2014; Mihara et al., 2008). It is well-established that motor learning and balance depend on the cerebellum and other interrelated brain regions (Glickstein & Yeo, 1990; Morton & Bastian, 2004). Importantly, however, the cerebellum has been shown to play an important role in EFs (Diamond, 2000; Koziol et al., 2014; Schmahmann, 2004, 2019; Stoodley, 2014; Strick et al., 2009). The cerebellum is topographically organized in motor, cognitive and affective areas and has important anatomical connections with PFC (Bostan & Strick, 2018; Kelly & Strick, 2003; Stoodley et al., 2012). A growing body of recent evidence supports a close association between motor and cognitive development (Diamond, 2000; Koziol et al., 2011, 2014). Further evidence of the close connection between EFs and motor function, especially balance, can be seen from the fact that children with impaired EFs (such as children with ADHD) tend to have impaired balance (Bucci et al., 2014; Buderath et al., 2008; Hassan, 2012; Hove et al., 2015; Jansen et al., 2019; Kim et al., 2017; Shum & Pang, 2009; Zoccante et al., 2021) and there is an overlap between ADHD and Developmental Co-Ordination Disorder diagnosis of around 30-50% (Pitcher et al., 2003). Further support for a close connection between balance and EFs comes from cross-sectional studies that report a positive correlation between postural stability and academic performance (Haynes et al., 2017, 2018; Shachaf et al., 2019). Finally, having to perform an EF task at the same time as meeting a balance challenge impairs performance on both, suggesting that they need shared neural resources (Bustillo-Casero et al., 2017; Fraizer & Mitra, 2007; Möhring et al., 2018; Shorer et al., 2012). Purpose: To see if improving balance might lead to improved EFs. Objectives and Hypothesis Our primary objective is to determine the effect of improving postural balance, through a balance training intervention, on EFs in children 8-12 years old. We hypothesize that training balance, especially under conditions of reduced sensory input and/or reduced base of support, will not only improve balance but also EFs. We further hypothesize that the degree of improvement in balance will be positively associated with the degree of improvement in EFs. Although studies have supported an association between postural stability and EFs (Haynes et al., 2017; Mihara et al., 2008; St George et al., 2021), the causal effect of balance training (without aerobic, bimanual or eye-hand coordination, and/or mindfulness components) on EFs has never been investigated. If positive results are obtained, this would be the first evidence that balance training programs might be an effective way to improve EFs. Better understanding the effect of improving balance on EFs may change our current approach to EFs training. The balance-training approach to be tried here has several advantages over traditional approaches - it can be done at home or most anywhere, a session takes only 15 minutes, it's inexpensive, it allows children to get up and move around (rather than having to stay seated at a desk), and hopefully participants will find it to be fun and enjoyable. We wanted an active control condition that participants would expect could improve their EFs because part of the benefit from an intervention comes about just because participants expect the intervention to produce a benefit (Boot et al., 2013; Simons et al., 2016). Expectancies can become self-fulfilling prophecies (Jenner et al., 1990; Rosenthal & Jacobson, 1968) so we wanted active control condition that would engender similar expectations of benefit. Watching music videos was chosen as the active control condition because of evidence that listening to music improves the cognitive functioning of adults with dementia or cognitive decline (Baird & Samson, 2015; Cuddy et al., 2015; Narme et al., 2014; Samson et al., 2015; Särkämö et al., 2008), playing music can improve children's EFs (Bowmer et al., 2018; Holochwost et al., 2017; Sachs et al., 2017)), listening to music improves mood (Kemper & Danhauer, 2005; Raglio et al., 2015), and improved mood leads to better EFs (Ashby et al., 1999; Isen, 2000; Yang et al., 2013). We don't expect our watching-music-videos condition to improve EFs, however, because (a) children's participation is passive (they are just consumers, watching and listening) and (b) the act of watching enjoyable music videos does not place any demands on EFs (whereas doing balance exercises should). The no-treatment group is included in case the Music Condition produces some small EF benefits, in which case the difference in benefits between the Balance and Music Conditions might not be significant. We would expect, however, that while the Balance Condition will produce EF benefits significantly greater than no-treatment, the Music Condition, if it produces EF benefits at all, will not produce ones significantly greater than no-treatment. Study Population Assuming a significance level of 0.05, power analyses using G*Power 3.1 (Faul et al., 2007) showed that a sample size of 30 per group would be needed to give us 80% power to detect a medium effect size (d' = 0.5) for EF change over time and for improvements in postural sway over time in children based on findings from other studies of EF or balance training in children (re: EF training: see review by Diamond & Ling, 2019; re: balance, see, e.g., ; Granacher et al., 2011; Heleno et al., 2016). Considering potential drop-out and non-compliance rates, we are allowing for 10-20% of the participants to not complete the study. Therefore, our aim is to recruit 108 participants (36 per condition). Study Design The study interventions consist of: Balance Training (BT), Music Training (MT), and business as usual. The BT and MT interventions will run for 12 weeks, 3 sessions per week, 15 minutes each and a weekly check-in session with a member of the research staff. For the business-as-usual group, participants will have no intervention. Assessment of EFs and balance will occur at baseline, 12 weeks later, and 3 months after that. For BT, sessions will include a combination of dynamic (i.e., balance challenges while moving, such as balancing a book on your head while walking) and static balance exercises (i.e., balance challenges while standing still, such as standing on one foot). For MT, participants will have access to 10 music videos each week tailored to each child's specific interests from which they can choose 4 to watch in any session. Assessments To assess the core EF skills, working memory (WM), inhibitory control (IC), and cognitive flexibility (CF), plus higher-order EF skills of problem-solving and planning, the following validated tests will be administered: N-back (WM), Re-ordering digits (WM), Hearts and Flowers (WM, IC (response inhibition), and CF), Flanker/Reverse Flanker (IC (selective attention) and CF), Stroop (IC and CF), Farmer Joe (auditory sustained attention), Tower of London (planning and problem solving), and Design Fluency (creative problem-solving). Scores for both accuracy and reaction time will be recorded. To assess static balance, the child's center of pressure will be measured using the Wii Balance Board under the following postural stances with eyes open and eyes closed: 1) bipedal, feet shoulder-distance apart, 2) tandem, one foot in front of the other with toes of the rear foot almost touching the heel of the front foot, and 3) unipedal, standing on one leg. To assess dynamic balance, we will measure the maximum time participants can maintain their balance standing on a wobble board with eyes open. Statistical Analysis First, we will look at whether variance of continuous outcome variables is normally distributed and roughly equal across conditions. Distributional characteristics of variables will be evaluated by Kolmogorov-Smirnoff goodness of fit test and by inspection of histograms. Such graphical inspection will reveal if any important deviations from normality were missed by the K-S test. Homoscedasticity will be evaluated using the Levene test. Mathematical transformations such as logarithms will be applied to improve the compliance to normality if deviations are found. In case the normality assumption is not met even after mathematical transformations, we will use the non-parametric Friedman's test as our study includes repeated outcome measures at different points in time. We will look at whether the groups differed significantly in any background variable, like age, and whether any of these variables are significantly related to any outcome variables. We will control for any background variables that show significant effects. To determine whether our balance training program is effective in improving balance, we will use mixed-model regression to compare participants performance on static and dynamic balance tests among all 3 groups at pre-intervention (to tell us if there were any differences among groups at the outset), post-intervention and 3-month follow-up (to tell us if any of the groups is performing significantly better than the others immediately after and/or 3 months after the intervention period). If we find a significant result, we will then do post-hoc pairwise comparisons to see which groups are significantly different from one another. Tukey or Bonferroni corrections will be used to correct for multiple comparisons potentially inflating the likelihood of finding a significant difference by chance. We will also compare degree of improvement (from pre- to post-intervention and from pre-intervention to 3-months follow-up) to see if any group(s) improved more than others and do post-hoc pairwise comparisons if any significant effects are found. To determine whether training balance improved EFs more than enjoying music or business as usual we will again use a mixed-model regression. As described above for balance assessments, all 3 groups will be compared at pre-intervention, post-intervention and 3-month follow-up. If we find a significant result, we will then do post-hoc pairwise comparisons to see which groups are significantly different from one another. Tukey or Bonferroni corrections will be used to correct for multiple comparisons. We will also compare degree of improvement to see if any group(s) improved more than others. To determine whether the degree of improvement in balance performance is significantly related to the degree of improvement in the EFs, we will use Pearson correlation. We will also conduct a mediation analysis using the difference in coefficients method to estimate the mediated effect of sway-area change on EF change (Mackinnon et al., 2007). ;

Related Conditions & MeSH terms

• Executive Functions
• Postural Balance

• NCT number: NCT05602857
• Study type: Interventional
• Source: University of British Columbia
• Contact: Priscilla Paz, MD
• Phone: 6046490702
• Email: pspaz@student.ubc.ca
• Status: Not yet recruiting
• Phase: N/A
• Start date: October 25, 2022
• Completion date: August 30, 2023