Sage Journals: Discover world-class research

Abstract

Objective:

To test how three custom-built balancing algorithms minimize differences in game success, time above 40% heart rate reserve (HRR), and enjoyment between youth with cerebral palsy (CP) who have different gross motor function capabilities. Youth at Gross Motor Function Classification System (GMFCS) level II (unassisted walking) and level III (mobility aids needed for walking) competed in a cycling-based exercise video game that tested three balancing algorithms.

Materials and Methods:

Three algorithms: a control (generic-balancing [GB]), a constant non-person specific (One-Speed-For-All [OSFA]), and a person-specific (Target-Cadence [TC]) algorithms were built. In this prospective repeated measures intervention trial with randomized and blinded algorithm assignment, 10 youth with CP aged 10–16 years (X ± standard deviation = 12.4 ± 1.8 years; GMFCS level II n = 4, III n = 6) played six exergaming sessions using each of the three algorithms. Outcomes included game success as measured by a normalized game score, time above 40% HRR, and enjoyment.

Results:

The TC algorithm balanced game success between GMFCS levels similarly to GB (P = 0.11) and OSFA (P = 0.41). TC showed poorer balancing in time above 40% HRR compared to GB (P = 0.02) and OSFA (P = 0.02). Enjoyment ratings were high (6.4 ± 0.7/7) and consistent between all algorithms (TC vs. GB: P = 0.80 and TC vs. OSFA: P = 0.19).

Conclusion:

TC shows promise in balancing game success and enjoyment but improvements are needed to balance between GMFCS levels for cardiovascular exercise.

Get full access to this article

View all access options for this article.

References

Bartlett

, Hanna

, Avery

, et al. Correlates of decline in gross motor capacity in adolescents with cerebral palsy in Gross Motor Function Classification System levels III to V: An exploratory study. Dev Med Child Neurol, 2010; 52:e155–e160.

Williams

. Physical and sedentary activity in adolescents with cerebral palsy. Dev Med Child Neurol, 2007; 49:450–457.

Biddiss

, Irwin

. Active video games to promote physical activity in children and youth: A systematic review. Arch Pediatr Adolesc Med, 2010; 164:664–672.

Knights

, Graham

, Switzer

, Hernandez

, Ye

, Findlay

, Xie

, Wright

, Fehlings

: An innovative cycling exergame to promote cardiovascular fitness in youth with cerebral palsy. Dev Neurorehabil, 2016; 19(2):135–140.

Warburton

DER

, Bredin

SSD

, Horita

LTL

, et al. The health benefits of interactive video game exercise. Appl Physiol Nutr Metab, 2007; 32:655–663.

Maloney

, Bethea

, Kelsey

, et al. A pilot of a video game (DDR) to promote physical activity and decrease sedentary screen time. Obesity, 2008; 16:2074–2080.

Rosenbaum

, Palisano

, Bartlett

, et al. Development of the Gross Motor Function Classification System for cerebral palsy. Dev Med Child Neurol, 2008; 50:249–253.

Hernandez

, Graham

, Fehlings

, et al. Design of an exergaming station for children with cerebral palsy. In: Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. New York: ACM Press; 2012, pp. 2619–2628.

Hernandez

, Graham

TCN

, Ketcheson

, et al. Design and evaluation of a networked game to supportsocial connection of youth with cerebral palsy. In: Proceedings of the 16th International ACM SIGACCESS Conference on Computers and Accessibility – ASSETS'14. New York: ACM Press; 2014, pp. 161–168.

10.

Stach

, Graham

, Yim

, Rhodes

. Heart rate control of exercise video games. In: Proceedings of Graphics Interface 2009. Toronto, ON: Canadian Information Processing Society; 2009, pp. 125–132.

11.

Gerling

, Miller

, Mandryk

, et al. Effects of balancing for physical abilities on player performance, experience and self-esteem in exergames. In: Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. New York: ACM Press; 2014. pp. 2201–2210.

12.

Rhodes

, Fiala

. Building motivation and sustainability into the prescription and recommendations for physical activity and exercise therapy: The evidence. Physiother Theory Pract, 2009; 25:424–441.

13.

Yim

, Graham

. Using games to increase exercise motivation. In: Proceedings of the 2007 Conference on Future Play. New York: ACM Press; 2007. pp. 166–173.

14.

Hernandez

, Ye

, Graham

, et al. Designing action-based exergames for children with cerebral palsy. In: Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. New York: ACM Press; 2013. pp. 1261–1270.

15.

Ketcheson

, Ye

, Graham

. Designing for exertion: How heart-rate power-ups increase physical activity in exergames. In: Proceedings of the 2015 Annual Symposium on Computer-Human Interaction in Play. New York: ACM Press; 2015, pp. 79–89.

16.

Ainsworth

, Haskell

, Herrmann

, et al. 2011 Compendium of physical activities: A second update of codes and MET values. Med Sci Sports Exerc, 2011; 43:1575–1581.

17.

Verschuren

, Ketelaar

, Keefer

, et al. Identification of a core set of exercise tests for children and adolescents with cerebral palsy: A Delphi survey of researchers and clinicians. Dev Med Child Neurol, 2011; 53:449–456.

18.

Verschuren

, Maltais

, Takken

. The 220-age equation does not predict maximum heart rate in children and adolescents. Dev Med Child Neurol, 2011; 53:861–864.

19.

Denadai

, Ruas VD de

, Figueira

. Effects of the pedaling cadence on metabolic and cardiovascular responses during incremental and constant workload exercises in active individuals. Rev Bras Med do Esporte, 2005; 11:286–290.

20.

Robert

, Levin

, Guberek

, Sambasivan

. The role of feedback on cognitive motor learning in children with Cerebral Palsy: A protocol. Virtual Rehabil Proc, 2015; 141–142.

21.

McAuley

, Duncan

, Tammen

. Psychometric properties of the Intrinsic Motivation Inventory in a competitive sport setting: A confirmatory factor analysis. Res Q Exerc Sport, 1989; 60:48–58.

22.

Wobbrock

, Findlater

, Gergle

, Higgins

. The aligned rank transform for nonparametric factorial analyses using only ANOVA procedures. In: Proceedings of the SIGCHI Conference on Human Factors in Computing Systems. New York: ACM Press; 2011, pp. 143–146.

23.

Eliasson

A-C

, Krumlinde-Sundholm

, Rösblad

, et al. The Manual Ability Classification System (MACS) for children with cerebral palsy: Scale development and evidence of validity and reliability. Dev Med Child Neurol, 2006; 48:549.

24.

Tomporowski

. Effects of acute bouts of exercise on cognition. Acta Psychol (Amst), 2003; 112:297–324.

25.

Rhodes

, Warburton

DER

, Bredin

SSD

. Predicting the effect of interactive video bikes on exercise adherence: An efficacy trial. Psychol Health Med, 2009; 14:631–640.

26.

Owens

, Garner III

, Loftin

, et al. Changes in physical activity and fitness after 3 months of home Wii Fit™ use. J Strength Cond Res, 2011; 25:3191–3197.

27.

Sun

. Exergaming impact on physical activity and interest in elementary school children. Res Q Exerc Sport, 2012; 83:212–220.

28.

Weis

: Gross Motor Function Measure (GMFM-66 and GMFM-88) User's Manual. edited by Russell

, Rosenbaum

, Lane

, Avery

. Cambridge University Press on behalf of MacKeith Press, Cambridge, UK, 2002.

Balancing for Gross Motor Ability in Exergaming Between Youth with Cerebral Palsy at Gross Motor Function Classification System Levels II and III

Abstract

Abstract

Objective:

Materials and Methods:

Results:

Conclusion:

Get full access to this article

References