The effect of duration of exercise at the ventilation threshold on subjective appetite and short-term food intake in 9 to 14 year old boys and girls

Natalie C Bozinovski, Nick Bellissimo, Scott G Thomas, Paul B Pencharz, Robert C Goode, G Harvey Anderson, Natalie C Bozinovski, Nick Bellissimo, Scott G Thomas, Paul B Pencharz, Robert C Goode, G Harvey Anderson

Abstract

Background: The effect of exercise on subjective appetite and short-term food intake has received little investigation in children. Despite a lack of reported evaluation of short-duration activity programs, they are currently being implemented in schools as a means to benefit energy balance. The purpose of this study was to determine the effect of duration of exercise at the ventilation threshold (VeT) on subjective appetite and short-term food intake in normal weight boys and girls aged 9 to 14 years.

Methods: On 4 separate mornings and in random order, boys (n = 14) and girls (n = 15) completed 2 rest or 2 exercise treatments for 15 (short-duration; SD) or 45 min (long-duration; LD) at their previously measured VeT, 2 h after a standardized breakfast. Subjective appetite was measured at regular intervals during the study sessions and food intake from a pizza meal was measured 30 min after rest or exercise.

Results: An increase in average appetite, desire to eat, and hunger (p < 0.05) was attenuated by SD exercise, but was further increased (p < 0.05) by LD exercise. However, food intake after SD and LD exercise was similar to after rest in both boys and girls (p = 0.55). The energy cost of SD and LD exercise resulted in a lower net energy balance compared to resting during the study measurement period in boys (SD: Delta = -418 +/- 301 kJ; LD: Delta = -928 +/- 196 kJ) and in girls (SD: Delta = -297 +/- 105 kJ; LD: Delta = -432 +/- 115 kJ).

Conclusion: Neither SD nor LD exercise at the VeT increased short-term food intake and SD exercise attenuated increases in appetite. Thus, SD exercise programs in schools may be an effective strategy for maintaining healthier body weights in children.

Figures

Figure 1
Figure 1
Effect of short-duration exercise at the VeT on subjective appetite scores. 1Average appetite (a) desire to eat (b) hunger (c) fullness (d) PFC (e) at 15, 30, and 45 min during short-duration sessions. 2SDRT = short-duration rest, SDEX = short-duration exercise, PFC = prospective food consumption. 3Change from baseline appetite scores increased with time for average appetite (p = 0.0005), desire to eat (p = 0.011), hunger (p = 0.0027), and PFC (p = 0.0047), and subjective fullness decreased (p < 0.0001). SDEX attenuated the increase in average appetite (p = 0.027), desire to eat (p = 0.049), and hunger (p = 0.0072) when compared with SDRT, but did not affect fullness (p = 0.98) or PFC (p = 0.15). Sex was not a factor on change from baseline average appetite (p = 0.11), desire to eat (p = 0.41), hunger (p = 0.46), fullness (p = 0.81), or PFC (p = 0.22). However, there was a significant treatment × sex interaction on PFC (p = 0.013). 4Test meal began at 45 min.
Figure 2
Figure 2
Effect of long-duration exercise at the VeT on subjective appetite scores. 1Average appetite (a) desire-to-eat (b) hunger (c) fullness (d) PFC (e) at 15, 30, 45, 60, and 75 min during long-duration sessions. 2LDRT = long-duration rest, LDEX = long-duration exercise, PFC = prospective food consumption. 3 Change from baseline average appetite (p < 0.0001), desire to eat (p < 0.0001), hunger (p < 0.0001), and PFC (p < 0.0001) increased with time, and fullness decreased (p < 0.001). LDEX stimulated a greater rate of increase in average appetite (p = 0.0045), desire to eat (p = 0.047), and hunger (p < 0.0001) compared with LDRT, however there was no effect on fullness (p = 0.19) or PFC (p = 0.18). Sex was not a factor on change from baseline average appetite (p = 0.22), desire to eat (p = 0.15), hunger (p = 0.80), fullness (p = 0.17), or PFC (p = 0.17). 4Test meal began at 75 min.
Figure 3
Figure 3
Physical comfort during (a) short- and (b) long-duration sessions in boys and girls. 1SDRT = short-duration rest, SDEX = short-duration exercise, LDRT = long-duration rest, LDEX = long-duration exercise. 2 Change from baseline physical comfort increased over time during SD (a) (p = 0.036), but not LD (b) (p = 0.26) sessions. Neither treatment (p = 0.49), nor sex (p = 0.58) was a factor affecting physical comfort during SD sessions. Physical comfort during LD sessions was affected by treatment (p < 0.0001), but not sex (p = 0.73), and there was a significant treatment × sex interaction (p = 0.0007). 3Test meals began at 45 min (a) and 75 min (b).

References

    1. Government of Ontario . Policy/Program Memorandum No. 138: Daily Physical Activity in Elementary Schools, Grades 1 - 8. Ontario Ministry of Education; 2005.
    1. International Life Sciences Institute The PAN Report: Physical Activity and Nutrition. 2000. pp. 1–8.
    1. Liu A, Hu X, Ma G, Pan Y, Chang S, Zhao W, Chen C. Evaluation of a classroom-based physical activity promoting programme. Obesity Reviews. 2008;9:130–134. doi: 10.1111/j.1467-789X.2007.00454.x.
    1. Moore MS, Dodd CJ, Welsman JR, Armstrong N. Short-term appetite and energy intake following imposed exercise in 9- to 10-year-old girls. Appetite. 2004;43:8. doi: 10.1016/j.appet.2004.02.008.
    1. Dodd CJ, Welsman JR, Armstrong N. Energy intake and appetite following exercise in lean and overweight girls. Appetite. 2008;51:482–483. doi: 10.1016/j.appet.2008.03.009.
    1. Bellissimo N, Thomas SG, Goode RC, Anderson HG. Effect of short-duration physical activity and ventilation threshold on subjective appetite and short-term energy intake in boys. Appetite. 2007;49:644–651. doi: 10.1016/j.appet.2007.04.004.
    1. Barlow SE, Dietz WH. Obesity evaluation and treatment: Expert Committee recommendations. The Maternal and Child Health Bureau, Health Resources and Services Administration and the Department of Health and Human Services. Pediatrics. 1998;102:1–11. doi: 10.1542/peds.102.3.e29.
    1. Brook CGD. Determination of Body Composition of Children from Skinfold Measurements. Archives of Disease in Childhood. 1971;46:182–184. doi: 10.1136/adc.46.246.182.
    1. Bellissimo N, Desantadina MV, Pencharz PB, Berall GB, Thomas SG, Anderson GH. A comparison of short-term appetite and energy intakes in normal weight and obese boys following glucose and whey-protein drinks. Int J Obes (Lond) 2008;32:362–371. doi: 10.1038/sj.ijo.0803709.
    1. Bellissimo N, Pencharz PB, Thomas SG, Anderson GH. Effect of television viewing at mealtime on food intake after a glucose preload in boys. Pediatr Res. 2007;61:745–749.
    1. Bellissimo N, Thomas SG, Pencharz PB, Goode RC, Anderson HG. Reproducibility of short-term food intake and subjective appetite scores after a glucose preload, ventilation threshold, and body composition in boys. Applied Physiology, Nutrition, and Metabolism. 2008;33:326–337. doi: 10.1139/H07-194.
    1. Van Strien T, Frijters JER, Van Staveren WA, Defares PB, Deurenberg P. The Predictive Validity of the Dutch Restrained Eating Scale. International Journal of Eating Disorders. 1986;5:747–755. doi: 10.1002/1098-108X(198605)5:4<747::AID-EAT2260050413>;2-6.
    1. Mahon AD, Cheatham CC. Ventilatory Threshold in Children: A Review. Pediatric Exercise Science. 2002;14:16–29.
    1. Rowland TW, Cunningham LN. Oxygen uptake plateau during maximal treadmill exercise in children. CHEST. 1992;101:485–489. doi: 10.1378/chest.101.2.485.
    1. Hebestreit H, Staschen B, Hebestreit A. Ventilatory threshold: a useful method to determine aerobic fitness in children? Medicine & Science in Sports & Exercise. 2000;32:1964–1969.
    1. Borg G. Borg's Perceived Exertion and Pain Scales. Champaign: Human Kinetics; 1998.
    1. Glass S, Medicine ACoS, Dwyer GB. ASCM's Metabolic Calculations Handbook. Lippincott Williams & Wilkins; 2006.
    1. Hubert P, King NA, Blundell JE. Uncoupling the Effects of Energy Expenditure and Energy Intake: Appetite Response to Short-term Energy Deficit Induced by Meal Omission and Physical Activity. Appetite. 1998;31:11.
    1. King NA, Stubbs RJ, Blundell JE. High dose exercise does not increase hunger or energy intake in free living males. European Journal of Clinical Nutrition. 1997;51:6.
    1. Lluch A, King NA, Blundell JE. Exercise in dietary restrained women: no effect on energy intake but change in hedonic ratings. European Journal of Clinical Nutrition. 1998;52:300–307.
    1. Lluch A, King NA, Blundell JE. No energy compensation at the meal following exercise in dietary restrained and unrestarined women. British Journal of Nutrition. 2000;84:7.
    1. Pomerleau M, Imbeault P, Parker T, Doucet E. Effects of exercise intensity on food intake and appetite in women. The American Journal of Clinical Nutrition. 2004;80:1230–1236.
    1. Stubbs RJ, Sepp A, Hughes DA, Johnstone AM, King N, Horgan GW, Blundell JE. The effect of graded levels of exercise on energy intake and balance in free-living women. International Journal of Obesity. 2002;26:866–869.
    1. Whybrow S, Hughes DA, Ritz P, Johnstone AM, Horgan GW, King N, Blundell JE, Stubbs RJ. The effect of an incremental increase in exercise on appetite, eating behaviour and energy balance in lean men and women feeding ad libitum. British Journal of Nutrition. 2008;100:1109–1115.
    1. Woo R, Sunyer FXP. Effect of Increased Physical Activity on Voluntary Intake in Lean Women. Metabolism. 1985;34:6.
    1. Stubbs RJ, Sepp A, Hughes DA, Johnstone AM, Horgan GW, King N, Blundell JE. The effect of graded levels of exercise on energy intake and balance in free-living men, consuming their normal diet. European Journal of Clinical Nutrition. 2002;56:129–140.
    1. Maughan RJ, Shirreffs SM, Watson P. Exercise, heat, hydration and the brain. J Am Coll Nutr. 2007;26:604S–612S.
    1. Anderson GH. Sugars-containing beverages and post-prandial satiety and food intake. International Journal of Obesity. 2006;30:S52–S59.
    1. Hill DW, Cureton KJ, Grisham SC, Collins MA. Effect of training on the rating of perceived exertion at the ventilatory threshold. Eur J Appl Physiol Occup Physiol. 1987;56:206–211.
    1. Goode RC, Mertens R, Shaiman S, Mertens J. Voice, breathing, and the control of exercise intensity. Adv Exp Med Biol. 1998;450:223–229.
    1. Persinger R, Foster C, Gibson M, Fater DCW, Porcari JP. Consistency of the Talk Test for Exercise Prescription. Medicine & Science in Sports & Exercise. 2004;36:1632–1636.
    1. Canada Health . Canada's physical activity guide for children. Public Health Agency of Canada, Ottawa, ON; 2002.
    1. Canada Health . Canada's physical activity guide for youth. Public Health Agency of Canada, Ottawa, ON; 2002.
    1. Wittmeier KD, Mollard RC, Kriellaars DJ. Physical Activity Intensity and Risk of Overweight and Adiposity in Children. Obesity. 2008;16:415–420.

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