Associations between physical activ

Associations between physical activity and fat mass in adolescents:
the Stockholm Weight Development Study1–3
Ulf Ekelund, Martin Neovius, Yvonné Linné, Søren Brage, Nicholas J Wareham, and Stephan Rössner
ABSTRACT
Background: Obesity is multifactorial. However, the accumulation
of fat mass (FM) is proposed to be due to a positive energy balance,
which may be caused by reduced physical activity (PA).
Objective: The objectives of the study were to describe the independent
associations between PA and FM in adolescents and to
describe the intergenerational association of FM between mothers
and their offspring.
Design:Weconducted a cross-sectional study in 445 (190 M, 255 F)
17-y-old adolescents and their mothers. PA was assessed with a
self-reported questionnaire and validated by comparison with accelerometric
data in a subsample of the cohort. Body composition was
measured by using air-displacement plethysmography.
Results: Males were significantly more active than were females
(P
0.01). PA was significantly and inversely associated with FM
(
 3.63, P  0.005) and percentage FM (
 3.117,
P  0.017) in males but not in females (
 0.576, P  0.54;

 0.532, P  0.59, respectively) after adjustment for birth
weight and maternal FM and education level. However, FM and
percentage FM in females were significantly associated with maternalFM(

0.159, P
0.0001;
0.145, P0.002, respectively)
and education level (
 1.048, P
0.005;
 1.085, P 
0.006, respectively). No such associations were observed in males.
Conclusions: PA was independently associated with FM in males
but not in females. The data also showed an intergenerational association
of FM between mothers and their daughters but not between
mothers and their sons. Am J Clin Nutr 2005;81:355– 60.
KEY WORDS Adolescents, fat mass, physical activity, obesity,
intergenerational association
INTRODUCTION
Several studies consistently showed that the prevalence of
overweight and obesity in young people is increasing dramatically
(1– 4). Obesity is multifactorial, and it involves genetic (5)
and behavioral (6) components. The behavioral components include
physical activity (PA) and food habits, which are influenced
by the social, cultural, and environmental context (6, 7).
The rise in the prevalence of excess body fat in young people is
proposed to be mainly due to environmental changes such as easy
access to large-sized portions of energy-dense foods and a reduced
PA level (6–8).
The association betweenPAor sedentary behavior and obesity
in children and adolescents has not been consistently shown
(9 –14). The difference in findings between studies is most likely
due to the differences in study methods, the imprecision of the
measurement of the exposure and outcome variables, and differences
in adjustment for confounding variables. Objective methods
are generally preferable in assessing dimensions of PA in young
people. However, in many cases, self-reporting is the only feasible
method of assessing PA in epidemiologic studies, and it may provide
a valid overall estimate of the total amount of PA (15).
Although the respective contribution of shared genetic and
environmental influences on obesity is unknown, parental body
mass index (BMI; in kg/m2) is associated with that of the parents’
children (16 –19). However, even if BMI is considered a reasonably
valid marker of overweight and obesity in population-based
epidemiologic studies, it does not provide a measure of the absolute
body fat mass (FM) or distinguish FM from fat-free mass
(FFM). Therefore, more precise methods are needed to assess the
associations betweenPAand FM. For example, air-displacement
plethysmography has been shown to be a valid method of measuringFMandFFMin
children, adolescents, and adults, and thus
it would be a preferred method for increasing the precision of the
outcome measurement (20 –23).
The primary purpose of the current cross-sectional study was
to describe the independent associations between self-reported
PA and absolute and percentage FM in 17-y-old adolescents; the
secondary purpose was to describe the intergenerational association
of FM between 17-y-old adolescents and their mothers.
SUBJECTS AND METHODS
Design
The Stockholm Weight Development Study, known as
SWEDES, is a longitudinal study of weight development in the
1 From the Medical Research Council Epidemiology Unit, Cambridge,
United Kingdom; the Department of Physical Education and Health,O¨ rebro
University, Sweden; and the Obesity Unit, Karolinska Institutet, Karolinska
University Hospital, Stockholm.
2 Supported by grant no. QLK1-2000-00515 from the European Commission
and by a grant from the Swedish National Center for Research in Sports
(to UE).
3 Reprints not available. Address correspondence to U Ekelund, MRC
Epidemiology Unit, Elsie Widdowson Laboratory, Fulbourn Road,CB19NL
Cambridge, United Kingdom. E-mail: ue202@medschl.cam.ac.uk.
Received May 31, 2004.
Accepted for publication September 22, 2004.
Am J Clin Nutr 2005;81:355–60. Printed in USA. © 2005 American Society for Clinical Nutrition 355
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offspring of mothers participating in the Stockholm Pregnancy
and Weight Development Study (24, 25). Briefly, 2342 pregnant
women were recruited in 1984 and 1985 and followed during and
after their pregnancies. Of this group, 1423 completed the study
at 1-y follow-up, and 481 of those mothers and their 481 children
participated in the follow-up study at 17 y. Anthropometric,
metabolic, psychological, and lifestyle variables (including PA)
were measured at follow-up. We report here the cross-sectional
associations between PA and body fatness in the offspring.
Subjects
Data on the body composition and socioeconomic status of the
mothers and complete data on adolescents’ birth weight, selfreported
PA, and body composition were available for 455 (255
females and 190 males) of the 481 adolescent subjects at followup.
There were no significant differences in height, weight, or
BMI between participants and those who did not provide complete
data (P  0.5).
The ethics committee of Huddinge University Hospital approved
the study. Written informed consent was obtained from
both the mothers and the adolescents.
Measurements
Anthropometric measures
Standing height was measured to the nearest 0.5 cm while the
subjects stood in bare feet against a wall-mounted stadiometer,
and body weight was measured to the nearest 0.1 kg by using the
BodPod scale (Life Measurement Instruments, Concord, CA)
while they wore light clothing. BMI was calculated, and the
adolescent subjects were classified as normal-weight, overweight,
or obese according to the age- and sex-adjusted cutoffs
described by Cole et al (26). The absolute values for overweight
in 17-y-old males and females are a BMI of 24.46 and 24.70,
respectively (26), and those for obesity are a BMI of 29.41 and
29.69 (26). In the mothers, overweight and obesity were determined
by BMIs  25 and  30, respectively. Body volume was
measured by using air-displacement plethysmography and the
BodPod scale after adjustment for predicted thoracic lung volume
and estimated surface area artifact. FM, percentage FM, and
FFM were calculated by using the software provided by the
manufacturer and the equation of Siri (27). Body volume was
measured in duplicate, and a third measurement was taken when
the first 2 measurements differed by150 mL. All subjects were
measured while wearing tight underwear or swimwear and a
swim cap. The same procedures were adopted for the mothers
and the offspring, and they were examined on the same day.
Maturity
Sexual maturity was assessed by using the 5-stage Tanner
scale for breast development in females and for pubic hair in
males (28). A dichotomous variable, puberty passed (Tanner
stage 5) or puberty not passed (Tanner stage
5) was created.
Physical activity
A self-administered PA questionnaire was developed for use
in Swedish adolescents. The questionnaire was designed to collect
information on the frequency, duration, and intensity of PA
in 3 different domains—ie, school, transportation, and leisure
time—during the previous 7 d. These 3 domains were selected to
encompass most of the possible physical activities performed by
adolescents. The first domain comprised PA and sedentary behavior
(ie, sitting) at school, including PA during physical education
classes and ordinary classes and during breaks. The second
domain related to transportation-related PA, eg, PA during
transit to and from school and that during other types of transportation.
The third domain included all PAs during leisure time,
including PA during paid and unpaid work, exercise, sports, and
other recreation. Questions regarding participation in moderate
and vigorous PA during leisure time were supplemented by concrete
examples of activities. Two questions about the type of
moderate and vigorous PA performed during leisure time were
also asked. The last part of the questionnaire comprised 2 questions
about the duration of sitting during leisure time on weekends
and weekdays. Data from the questionnaire were manually
checked for out-of-range values (ie, 3 SD) within each PA
domain, and these values were deleted. However, including all
out-of-range values within each activity domain affected only the
mean of total PA [metabolic equivalents (METs)-min/wk] and
not the ranking of individuals. Data were summed within each
domain to estimate the total amount of time spent inPAper week.
Total weekly PA was estimated by weighting the reported time
within each activity domain by a specific MET energy expenditure
estimate assigned to each category of PA (29, 30).
The weighted minutes of METs per week were calculated as
duration  frequency  MET intensity across activity domains
to produce a total estimate of PA (MET-min/wk).
We assessed the validity of the questionnaire in a subsample
(n  49; 18 males) of study participa