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Mechanisms opposing exercise-induced perturbations in energy balance in overweight women

Published online by Cambridge University Press:  30 June 2021

E. Manthou ,
J. M. R. Gill ,
A. Wright  and
D. Malkova
E. Manthou
Affiliation:
University of Glasgow, Glasgow, UK
J. M. R. Gill
Affiliation:
University of Glasgow, Glasgow, UK
A. Wright
Affiliation:
University of Glasgow, Glasgow, UK
D. Malkova
Affiliation:
University of Glasgow, Glasgow, UK
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Abstract

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Abstract
Information
Proceedings of the Nutrition Society , Volume 67 , Issue OCE6: A Scientific Meeting was held at the West Park Conference Centre, Dundee, Scotland, on 27 and 28 March 2008 , May 2008 , E225
Copyright
Copyright © The Authors 2008

The effectiveness of exercise in reducing body weight is individual and may be related to variability in compensatory responses( Footnote 1 ). The aim of the study was to identify the underlying mechanisms opposing exercise-induced perturbations in energy balance in overweight women.

Thirty-one healthy sedentary women (mean age 31.9 (sd 8.3) years; BMI 28.8 (sd 3.6) kg/m2; percentage body fat 39.1 (sd 4.7) participated in a supervised 8-week exercise programme, which consisted of 150 min cycling per week at an intensity of 90–95% lactate threshold. Body composition, activity energy expenditure (AEE; calculated as energy expended during all active activities including exercise sessions), inactivity energy expenditure (IEE; calculated as energy expenditure of sedentary activities), sleeping energy expenditure (SEE) and energy intake (EI) were assessed at baseline and during week 8 of the exercise programme. AEE and IEE were estimated from individual relationships between VO2 and VCO2 and heart rate (HR) and records of HR and physical-activity diaries obtained during waking hours of week 0 and week 8( Footnote 2 ). SEE was obtained from basal metabolic rate (BMR) measurements (Deltatrac System; Datex Instrumentation Inc., Baldwin Park, CA, USA). EI was assessed by 7 d self-recorded weighed intake. Measures of body mass and its components were taken using bioelectrical impedance scales (Tanita TBF-300; Tanita UK Ltd, Yiewsley, Middlesex, UK). Nine of the subjects achieved ≥75% predicted body-fat loss and were classified as responders (R), while another twenty-two subjects fell into the group of non-responders (NR). Changes in all variables from baseline to post-intervention assessment were compared by two-way ANOVA (group×time) with repeated measures on the ‘time’ factor and post hoc Tukey test was used to identify changes within a group.

There was a significant interaction (P<0.05) for the change in AEE between groups R and NR, with AEE during week 8 being significantly higher (P<0.05) in comparison with baseline only in group R. Changes in IEE, SEE and EI from week 0 to week 8 were not significant within both groups and not different between groups R and NR. Reported daily EI of 41% of participants was below BMR×1.3.

In conclusion, in overweight women reduction in physical activity in the non-exercise time can be expected during supervised exercise programmes and thus explain a lower-than-predicted weight loss.

References

1. King, NA, Hopkins, M, Caudwell, P, Stubbs, RJ & Blundell, JE (2008) Int J Obes 32, 177–184.CrossRefGoogle Scholar

2. Moon, JK & Butte, NF (1996) J Appl Phys 81, 1754–1761.Google Scholar