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Results From the Third National Health and Nutrition Examination Survey

Ross E. Andersen, PhD; Carlos J. Crespo, DrPH, MS; Susan J. Bartlett, PhD; Lawrence J. Cheskin, MD; Michael Pratt, MD, MPH

JAMA. 1998;279:938-942.

ABSTRACT
Context.— Physical inactivity contributes to weight gain in adults, but whether this relationship is true for children of different ethnic groups is not well established.

Objective.— To assess participation in vigorous activity and television watching habits and their relationship to body weight and fatness in US children.

Design.— Nationally representative cross-sectional survey with an in-person interview and medical examination.

Setting and Participants.— Between 1988 and 1994, 4063 children aged 8 through 16 years were examined as part of the National Health and Nutrition Examination Survey III. Mexican Americans and non-Hispanic blacks were oversampled to produce reliable estimates for these groups.

Main Outcome Measures.— Episodes of weekly vigorous activity and daily hours of television watched, and their relationship to body mass index and body fatness.

Results.— Eighty percent of US children reported performing 3 or more bouts of vigorous activity each week. This rate was lower in non-Hispanic black and Mexican American girls (69% and 73%, respectively). Twenty percent of US children participated in 2 or fewer bouts of vigorous activity per week, and the rate was higher in girls (26%) than in boys (17%). Overall, 26% of US children watched 4 or more hours of television per day and 67% watched at least 2 hours per day. Non-Hispanic black children had the highest rates of watching 4 or more hours of television per day (42%). Boys and girls who watch 4 or more hours of television each day had greater body fat (P<.001) and had a greater body mass index (P<.001) than those who watched less than 2 hours per day.

Conclusions.— Many US children watch a great deal of television and are inadequately vigorously active. Vigorous activity levels are lowest among girls, non-Hispanic blacks, and Mexican Americans. Intervention strategies to promote lifelong physical activity among US children are needed to stem the adverse health consequences of inactivity.

INTRODUCTION

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THE PREVALENCE of overweight continues to increase in the US adult population.^1-3 In the 12 years between the Second National Health and Nutrition Examination Survey (NHANES II, 1976 through 1980) and NHANES III (1988 through 1991), the prevalence of overweight in US adults increased from 25% to 33%.² The prevalence of overweight also increased by similar magnitudes among all sex and age groups of children and adolescents.¹ Obesity in children has been associated with subsequent morbidity and mortality in adulthood.⁴ These trends have persisted despite our nation's intense preoccupation with weight.⁵

Similarly, the prevalence of obesity in England has doubled in the past decade, yet daily energy intake and fat consumption have actually been reduced in that country during this time period.⁶ A change in the volume of daily physical activity may account for this apparent discrepancy. Increasingly, leisure time activities are more sedentary, with television watching, video games, and personal computing among the most popular pastimes. Further, people in industrialized countries are expending less energy in activities of daily living, and at work.^6-7

Several studies suggest that an active lifestyle during childhood and adolescence can play an important role in optimizing growth and development.^7-8 The Centers for Disease Control and Prevention recently recommended that comprehensive school and community programs be developed to promote physical activity among children and adolescents.⁹ The goals of these programs are to increase knowledge about activity and exercise, develop behavioral and motor skills that promote lifelong activity, and encourage physical activity outside of physical education classes.

Using data from NHANES III, this article provides estimates of daily television watching habits and weekly bouts of vigorous physical activity in a nationally representative sample of US children aged 8 through 16 years. We also examined the relationship between body mass index (BMI), body fatness, and bouts of vigorous activity and television watching.

METHODS

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Sample Design

The NHANES III was conducted by the Centers for Disease Control and Prevention, National Center for Health Statistics. The plan and operation of NHANES III have been described elsewhere.^10-11 Briefly, the survey was designed to produce a nationally representative sample of the US population. One of its main goals was to estimate the national prevalence of selected health conditions and risk factors.

The NHANES III represents a 6-year study from 1988 through 1994 and consists of two 3-year phases: phase I, 1988 through 1991; and phase II, 1991 through 1994. Although the entire 6-year survey constitutes a national survey, the survey was designed so that each phase was also a nationally representative sample. The NHANES III oversampled Mexican Americans, non-Hispanic blacks, and young children to ensure weighted, reliable estimates for these groups. Approximately 16 % of those interviewed ranged in age from 8 through 16 years. Combined data from phases I and II are reported in this article.

The interview was conducted in the child's home and a detailed clinical examination was performed in a mobile examination center. During the home interview part of NHANES III, 5365 children were interviewed and the analytic sample consisted of 4063 children aged 8 through 16 years who completed the physical activity questionnaire and the body measurement component at the mobile examination center. Children who were mentally retarded or had a proxy answer questions for them were excluded from the analyses, as were those with cerebral palsy, muscle weakness, or paralysis of the arms or legs.

Interviewing staff consisted of experienced persons, many of whom were of Hispanic origin or bilingual in English and Spanish. Interview forms were available in both languages. All staff attended yearly training sessions to ensure maintenance of effective interviewing skills.

Information on self-reported race and ethnicity was used to classify persons as non-Hispanic white, non-Hispanic black, or Mexican American (persons of Mexican origin living in the United States). Age was defined as age in years at the time of the household interview, which preceded the examination by 2 to 3 weeks.

Dependent Variables

Participating children were asked how many times per week they "played or exercised enough to make them sweat or breathe hard." These activities did not exclude school-related involvements such as physical education. The interview also included a question on the number of hours of television watched the day before the interview was administered. Body composition was estimated by calculating the BMI [the weight (in kilograms) divided by the height (in meters, squared)], since it has been found to be significantly related to the percentage of body fat and total body fat in boys and girls.¹² We also calculated the sum of the subscapular and suprailiac skinfolds as an index of trunk fat.

Statistical Analysis

Statistical analyses were carried out using SAS¹³ and WesVarPC.¹⁴ For each survey, sampling weights were calculated that took into account the unequal selection probabilities resulting from the cluster design and from planned oversampling of certain subgroups. All analyses incorporated the sampling weights. For variance estimation, the balance repeated replication method in the software package WesVarPC¹⁴ was used. Statistical differences were determined using 2-tailed t tests taking the sampling weights and the complex sample design into account.¹⁴ Furthermore, the General Linear Model procedure in SAS¹³ was used to calculate the least square means to adjust for Tanner stages¹⁵ in estimating physical activity and hours of television watching.

RESULTS

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The cross-sectional prevalence estimates of the number of bouts of vigorous activity per week for US children aged 8 through 16 years from 1988 through 1994 are shown in Table 1. Overall, 80% reported participating in play or exercise that made them sweat or breathe hard 3 or more times per week; the rate was higher in boys (85%) than in girls (74%). Among non-Hispanic white boys, 88% reported exercising vigorously 3 or more times per week, whereas 78% of non-Hispanic black boys and 80% of Mexican American boys met this criterion; 72.6% of Mexican American girls and 69% of non-Hispanic black girls reported performing 3 or more bouts of vigorous activity each week, whereas only 12.2% of non-Hispanic white boys reported fewer than 3 bouts of vigorous activity per week. Table 1 also presents prevalence rates of bouts of vigorous physical activity among various age groups of US children. Boys and girls reported similar patterns of vigorous play in both the 8 through 10 years and the 11 through 13 years age groups with the boys reporting slightly more physical activity in each group. However, only 65% of girls aged 14 through 16 years reported 3 or more bouts of vigorous activity per week, whereas 86% of age-matched boys achieved this level. Few boys or girls reported 1 or less bouts of vigorous activity per week, with the exception of 20.1% of 14- to 16-year-old girls reporting this level of inactivity. Further analyses (data not shown) revealed that 8.7% of the 14- to 16-year-old girls reported less than 1 bout of vigorous activity per week.

View this table: [in this window] [in a new window] Table 1.—Unadjusted and Age-Specific Prevalence (per 100) of the Number of Reported Sessions of Weekly Play or Exercise That Results in Sweating or Hard Breathing Among US Children, 1988 Through 1994

The cross-sectional prevalence rate estimates of hours of television watched per day among US children are presented in Table 2. Overall, 26% of American children reported watching 4 or more hours of television per day; the rate was lower in girls (23%) than in boys (29%). Forty-three percent of non-Hispanic black boys and girls reported watching television for more than 4 hours per day. In contrast, non-Hispanic white boys and girls had the lowest prevalence of watching television more than 4 hours per day (25% of boys and 18% of girls).

View this table: [in this window] [in a new window] Table 2.—Unadjusted and Age-Specific Prevalence (per 100) of Hours of Television Watched per Day Among US Children, 1988 Through 1994

Boys and girls reported similar patterns of television watching across age groups (Table 2). The highest prevalence of watching 4 or more hours of television per day occurred in 11- to 13-year-old children. Both boys and girls in this age group also had the lowest prevalence of watching 1 or less hours of television per day.

Figure 1 shows the Tanner-score adjusted mean BMI (A) and the sum of the trunk skinfolds (B) in relation to the number of bouts of vigorous activity completed weekly. Boys who reported 6 to 8 sessions of vigorous activity per week had the highest BMIs, whereas those who reported 3 or fewer sessions of vigorous activity per week had the lowest. In the girls, no clear trend occurred.

View larger version (17K): [in this window] [in a new window] Figure 1.—Mean body mass index (BMI) (A) and the mean sum of the subscapular and suprailiac skinfolds (B) in relation to the number of vigorous activity sessions completed weekly among US children aged 8 to 16 years, 1988 through 1994. Asterisk indicates significantly different (P<.001) from 3 or less times per week.

Figure 2 shows the Tanner-score adjusted mean BMI (A) and the sum of the trunk skinfolds (B) in relation to the number of daily hours of television watched. Boys and girls who watched 4 or more hours of television per day had the highest skinfold thicknesses and highest BMIs; conversely, children who watched less than 1 hour of television per day had the lowest BMIs.

View larger version (15K): [in this window] [in a new window] Figure 2.—Mean body mass index (BMI) (A) and the mean sum of the subscapular and suprailiac skinfolds (B) in relation to daily hours of television watched among US children aged 8 to 16 years, 1988 through 1994. Asterisk indicates significantly greater (P<.001) than the less than 2-hour group; dagger indicates significantly greater (P<.001) than the 2- to 3-hour group.

We cross-tabulated thirds of daily television watching and thirds of weekly bouts of vigorous activity to examine the interaction that these measures may have on Tanner score–adjusted BMI and the sum of trunk skinfolds (Figure 3). We observed that television watching was more closely related to skinfolds and BMI than was vigorous activity. Multivariate analyses revealed no interaction between television watching and physical activity. Furthermore, significant effects were seen for television watching but not for physical activity.

View larger version (46K): [in this window] [in a new window] Figure 3.—Mean body mass index (BMI) (A, B) and the sum of the subscapular and suprailiac skinfolds (C, D) by combinations of daily hours of television watched (TVW) and weekly sessions of vigorous play or exercise (VA) among US children aged 8 to 16 years, 1988 through 1994.

COMMENT

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We found that US children are currently more active than their adult counterparts, with almost 80% reporting 3 or more bouts of vigorous activity each week.¹⁶ However, there are several worrisome trends among adolescent females and ethnic minority groups. Of concern, 26% of all girls and 31% of non-Hispanic black girls report 2 or fewer bouts of vigorous activity per week. Our data reconfirm that vigorous activity among ethnic minority children is lower than in non-Hispanic white children.^17-18 Such information must be considered when developing physical education curricula and community-based intervention strategies aimed at increasing physical activity among different target populations.

One of the objectives of Healthy People 2000 is to increase vigorous physical activity to at least 3 days per week for 20 minutes or more per occasion in at least 75% of children and adolescents.¹⁹ Boys of all ages appear to be meeting this criterion. However, a decrease in physical activity seems to occur as girls move from the 11- to 13-year age group to the 14- to 16-year age group. Moreover, 20.1% of girls aged 14 to 16 years reported 1 or fewer bouts of vigorous physical activity each week. These data are consistent with the 1992 National Health Interview Survey-Youth Risk Behavior Survey, which reported that 8.7 % of 15-year-old females reported no participation in moderate or vigorous activity,¹⁶ and that 18.5% of 17-year-old females were sedentary. Malina²⁰ has suggested that the adolescent decline in physical activity that occurs after the growth spurt is probably related to the social demands of adolescence, changing interests and the transition from school to work or school to college. However, the level of physical activity in our study may be optimistically high because children who lived in northern states were surveyed during the summer when physical activity is known to be at its peak. Furthermore, the question about physical activity did not assess moderate activity or duration of vigorous activity, so a brief bout of vigorous activity could have been reported as a single bout of exercise.

Because a sedentary lifestyle is considered a risk factor for coronary artery disease,²¹ parents and health care professionals need to encourage adolescent females in particular to maintain active lifestyles throughout adolescence. The International Consensus Conference on Physical Activity Guidelines for Adolescents recommends that "all adolescents . . . be physically active daily, or nearly every day, as part of play, games, sports, work, transportation, recreation, physical education, or planned exercise, in the context of family, school, and community activities" and that "adolescents engage in three or more sessions per week of activities that last 20 minutes or more at a time and that require moderate to vigorous levels of exertion."²²

We also found that non-Hispanic white children were the most active, with 77% of girls and 88% of boys reporting 3 or more bouts of vigorous activity per week. However, only 69% of non-Hispanic black girls and 73% of Mexican American girls reached this threshold. Concerns about crime may present a major barrier to some children becoming more physically active.⁷ In a survey of parents, 46% of US adults believed that their neighborhoods were unsafe.²³ Parents in minority populations are twice as likely as non-Hispanic white parents to report that their neighborhoods were unsafe. This information may partially explain the lower bouts of vigorous activity and higher prevalence of television watching reported in non-Hispanic black and Mexican American children. Successful implementation of policies to address this problem may help to increase physical activity in these 2 groups. For example, neighborhood watch programs and increased policing in high crime areas may help alleviate fears and foster an environment where parents feel it is safe for their children to play. Furthermore, Healthy People 2000 calls for increased community availability and accessibility of physical activity and fitness facilities.¹⁹ Thus, studies that specifically attempt to promote enjoyable, lifetime activities among ethnic minorities should receive high priority in the public health arena.

Troiano and colleagues¹ reported that the prevalence of overweight is increasing among boys and girls of all age groups and suggested increasing physical activity as a means to address this important health problem. Physical activity is inversely related to body weight, body composition, and the waist-to-hip ratio in adults. Sedentary leisure time activities such as television watching, playing video games, and personal computing have contributed to the increasing prevalence of overweight in America.^24-27 Our report shows that television watching was associated with increased skinfold thickness and BMI among US youth.

Overall, we found high rates of television watching, with 26% of US children (and 43% of non-Hispanic black children) watching 4 or more hours per day. Strasburger²⁸ has calculated that the average high school graduate will likely spend 15000 to 18000 hours in front of a television but only 12000 hours in school. Next to sleeping, television watching occupies the greatest amount of leisure time during childhood.²⁷ We found that skinfold thicknesses increased in both boys and girls as the amount of television watched increased. This finding is consistent with an earlier study that found a significant relationship between television watching and the prevalence of obesity in children.²⁶

We also found a relationship between television watching, physical activity, and body composition. Children who watched more television and were less likely to participate in vigorous activity tended to have higher BMIs. This is consistent with the findings of Durant et al.²⁹ Two studies have reported strong inverse relationships between television watching and physical activity after television was introduced into small communities in Canada³⁰ and Scotland.³¹ Additional research is needed to further identify types of physical activities that could serve as alternative activities, especially for minority children, among whom television watching is greatest. Studies among persons of low socioeconomic status and among certain racial groups have demonstrated specific determinants and activity preferences. This information has been used to effectively tailor culturally appropriate physical activity promotion programs.

Currently, 45% of Mexican American and 49% of non-Hispanic black adult women are overweight.² Low levels of vigorous activity and increased television watching most likely are contributing to this trend. Overweight children are more likely to become overweight adults than their leaner counterparts.^32-34 It appears that overweight in adulthood can more accurately be predicted from the body weight in late adolescence as opposed to younger ages.^33-34 Furthermore, the risks of obesity in adulthood appear to be greater in persons who were overweight during childhood and adolescent years.^35-36 Thus, increased efforts must be placed on preventing excessive weight gain in older children.

In our study, BMI and the sum of trunk skinfolds were similar in boys and girls who were highly active compared with those who participated in little activity. Conversely, children who watched the most television had more body fat and greater BMIs than those who watched less than 2 hours per day. This underscores the work of Epstein and colleagues,³⁷ who reported that decreasing sedentary behaviors is a key ingredient to the successful treatment of childhood obesity. Moreover, repeated exposure to television commercials for food may prompt children to increase food consumption, which ultimately leads to weight gain.³⁸ Sedentary activities that are regularly associated with eating also can become conditioned cues for eating, such that a child who is not hungry and begins television watching may find that the television watching cues eating.³⁹

For young people, learning to be physically active may be a more potent motivator for physical activity than the knowledge about why being physically active is important.^40-41 Health care professionals, parents, and educators should encourage children and adolescents to be active before, during, and after the school day. Recent guidelines for the promotion of lifelong physical activity recommend that health care professionals routinely assess levels of physical activity in their young patients. Physicians can play a key role in encouraging sedentary children and their families to adopt more active lifestyles.^42-43 Inactive children and adolescents should be guided toward school or community programs that encourage physical activity. Children and adolescents who regularly participate in physical activity should be encouraged to continue and maintain their active ways.

In summary, although many American children (80%) are regularly active, rates of inactivity among adolescent girls, non-Hispanic blacks, and Mexican Americans are cause for concern. One quarter of all US children watch 4 or more hours of television each day, as do 43% of non-Hispanic blacks. Hours of television watching is related to both BMI and skinfold thickness. Physicians and other health care professionals should counsel children and their caregivers on the importance of regular physical activity and decreasing sedentary activities. Intervention strategies designed to promote lifetime physical activity represent a major public health challenge and priority.

AUTHOR INFORMATION

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The authors thank Ellen Smit, PhD, of the Johns Hopkins School of Public Health for expert analytical assistance and advice.

Reprints: Ross E. Andersen, PhD, Johns Hopkins School of Medicine, 333 Cassell Dr, Suite 1640, Baltimore, MD 21224 (e-mail: andersen{at}welchlink.welch.jhu.edu).

From the Divisions of Geriatric Medicine and Gerontology (Dr Andersen) and Gastroenterology (Drs Bartlett and Cheskin), Johns Hopkins University School of Medicine, Baltimore, Md; Department of Health and Fitness, National Heart, Lung, and Blood Institute, National Institutes of Health, Bethesda, Md (Dr Crespo); and the Physical Activity and Health Branch, Centers for Disease Control and Prevention, Atlanta, Ga (Dr Pratt). Dr Crespo is now with the American University Department of Health and Fitness, Washington, DC.

REFERENCES

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Pediatrics 2007;120:S193-S228.
ABSTRACT | FULL TEXT  

Evaluation and Management of Childhood and Adolescent Obesity
Singhal et al.
Mayo Clin Proc. 2007;82:1258-1264.
ABSTRACT | FULL TEXT  

Effects of Modifying Physical Activity and Sedentary Behavior on Psychosocial Adjustment in Overweight/Obese Children
Goldfield et al.
J Pediatr Psychol 2007;32:783-793.
ABSTRACT | FULL TEXT  

The Global Epidemic of Obesity: An Overview
Caballero
Epidemiol Rev 2007;0:mxm012v1.
FULL TEXT  

Children's usage of media technologies and psychosocial factors
Heim et al.
New Media Society 2007;9:425-454.
ABSTRACT  

Exposure to Food Advertising on Television Among US Children
Powell et al.
Arch Pediatr Adolesc Med 2007;161:553-560.
ABSTRACT | FULL TEXT  

Trends in vigorous physical activity and TV watching of adolescents from 1986 to 2002 in seven European Countries
Samdal et al.
Eur J Public Health 2007;17:242-248.
ABSTRACT | FULL TEXT  

Childhood Overweight: Parental Perceptions and Readiness for Change
Howard
The Journal of School Nursing 2007;23:73-79.
ABSTRACT | FULL TEXT  

Perceived parenting style and practices and the consumption of sugar-sweetened beverages by adolescents
van der Horst et al.
Health Educ Res 2007;22:295-304.
ABSTRACT | FULL TEXT  

A comprehensive view of sex-specific issues related to cardiovascular disease
Pilote et al.
CMAJ 2007;176:S1-S44.
ABSTRACT | FULL TEXT  

Longitudinal Relationship Between Television Viewing and Leisure-Time Physical Activity During Adolescence
Taveras et al.
Pediatrics 2007;119:e314-e319.
ABSTRACT | FULL TEXT  

Lessons from sports: children's socialization to values through family interaction during sports activities
Kremer-Sadlik and Kim
Discourse Society 2007;18:35-52.
ABSTRACT  

Treatment of Obesity
Thompson et al.
Mayo Clin Proc. 2007;82:93-102.
ABSTRACT | FULL TEXT  

Estimating the Energy Gap Among US Children: A Counterfactual Approach
Wang et al.
Pediatrics 2006;118:e1721-e1733.
ABSTRACT | FULL TEXT  

Reducing Children's Television-Viewing Time: A Qualitative Study of Parents and Their Children
Jordan et al.
Pediatrics 2006;118:e1303-e1310.
ABSTRACT | FULL TEXT  

Food-Related Advertising on Preschool Television: Building Brand Recognition in Young Viewers
Connor
Pediatrics 2006;118:1478-1485.
ABSTRACT | FULL TEXT  

Television Viewing and Pedometer-Determined Physical Activity Among Multiethnic Residents of Low-Income Housing
Bennett et al.
AJPH 2006;96:1681-1685.
ABSTRACT | FULL TEXT  

Effects of Open-Loop Feedback on Physical Activity and Television Viewing in Overweight and Obese Children: A Randomized, Controlled Trial
Goldfield et al.
Pediatrics 2006;118:e157-e166.
ABSTRACT | FULL TEXT  

Active Healthy Living: Prevention of Childhood Obesity Through Increased Physical Activity
Council on Sports Medicine and Fitness and Council
Pediatrics 2006;117:1834-1842.
ABSTRACT | FULL TEXT  

When Children Eat What They Watch: Impact of Television Viewing on Dietary Intake in Youth
Wiecha et al.
Arch Pediatr Adolesc Med 2006;160:436-442.
ABSTRACT | FULL TEXT  

Physical Activity and Sedentary Behavior Patterns Are Associated With Selected Adolescent Health Risk Behaviors
Nelson and Gordon-Larsen
Pediatrics 2006;117:1281-1290.
ABSTRACT | FULL TEXT  

Exercise Locus of Control, Behavior, and Intention Among Mexican American Youth
Guinn et al.
Hispanic Journal of Behavioral Sciences 2006;28:115-126.
ABSTRACT  

Inequality in the Built Environment Underlies Key Health Disparities in Physical Activity and Obesity
Gordon-Larsen et al.
Pediatrics 2006;117:417-424.
ABSTRACT | FULL TEXT  

Do children from an inner city British school meet the recommended levels of physical activity? Results from a cross sectional survey using objective measurements of physical activity
Trayers et al.
Arch. Dis. Child. 2006;91:175-176.
ABSTRACT | FULL TEXT  

Longitudinal Trends in Race/Ethnic Disparities in Leading Health Indicators From Adolescence to Young Adulthood
Harris et al.
Arch Pediatr Adolesc Med 2006;160:74-81.
ABSTRACT | FULL TEXT  

Assessment of Foods Advertised on Children's TV Programs
Hargunani
AAP Grand Rounds 2005;14:66-66.
FULL TEXT  

Psychosocial and Environmental Correlates of Adolescent Sedentary Behaviors
Norman et al.
Pediatrics 2005;116:908-916.
ABSTRACT | FULL TEXT  

A National Study of Neighborhood Safety, Outdoor Play, Television Viewing, and Obesity in Preschool Children
Burdette and Whitaker
Pediatrics 2005;116:657-662.
ABSTRACT | FULL TEXT  

Effects of Dietary Macronutrient Intake on Insulin Sensitivity and Secretion and Glucose and Lipid Metabolism in Healthy, Obese Adolescents
Sunehag et al.
J. Clin. Endocrinol. Metab. 2005;90:4496-4502.
ABSTRACT | FULL TEXT  

Association of physical activity with body-composition indexes in children aged 6-8 y at varied risk of obesity
Rennie et al.
Am. J. Clin. Nutr. 2005;82:13-20.
ABSTRACT | FULL TEXT  

Channel One, the Anti-Commercial Principle, and the Discontinuous Ethos
Brighouse
Educational Policy 2005;19:528-549.
ABSTRACT  

Food advertising on Australian television: the extent of children's exposure
Neville et al.
HEALTH PROMOT INT 2005;20:105-112.
ABSTRACT | FULL TEXT  

Arkansas School Nurses' Role in Statewide Assessment of Body Mass Index to Screen for Overweight Children and Adolescents
Gance-Cleveland and Bushmiaer
The Journal of School Nursing 2005;21:64-69.
ABSTRACT | FULL TEXT  

A Review of Family and Social Determinants of Children's Eating Patterns and Diet Quality
Patrick and Nicklas
J. Am. Coll. Nutr. 2005;24:83-92.
ABSTRACT | FULL TEXT  

Major differences in prevalence of overweight according to nationality in preschool children living in Germany: determinants and public health implications
Kuepper-Nybelen et al.
Arch. Dis. Child. 2005;90:359-363.
ABSTRACT | FULL TEXT  

Reducing sedentary behaviour and increasing physical activity among 10-year-old children: overview and process evaluation of the 'Switch-Play' intervention
SALMON et al.
HEALTH PROMOT INT 2005;20:7-17.
ABSTRACT | FULL TEXT  

Prevention of the Epidemic Increase in Child Risk of Overweight in Low-Income Schools: The El Paso Coordinated Approach to Child Health
Coleman et al.
Arch Pediatr Adolesc Med 2005;159:217-224.
ABSTRACT | FULL TEXT  

Does Disadvantage Start at Home?: Racial and Ethnic Disparities in Health-Related Early Childhood Home Routines and Safety Practices
Flores et al.
Arch Pediatr Adolesc Med 2005;159:158-165.
ABSTRACT | FULL TEXT  

Factors affecting Nutritional Status of Malaysian Primary School Children
Anuar Zaini et al.
Asia Pac J Public Health 2005;17:71-80.
ABSTRACT  

The Metabolic Syndrome: Look for It in Children and Adolescents, Too!
Jessup and Harrell
Clin. Diabetes 2005;23:26-32.
FULL TEXT  

Promoting Lifestyle and Behavior Change in Overweight Children and Adolescents With Type 2 Diabetes
Schreiner
Diabetes Spectr. 2005;18:9-12.
FULL TEXT  

Type 2 diabetes mellitus in children and adolescents--the beginning of a renal catastrophe?
Kiess et al.
Nephrol Dial Transplant 2004;19:2693-2696.
FULL TEXT  

Physical Activity and Television Viewing in Relation to Risk of Undiagnosed Abnormal Glucose Metabolism in Adults
Dunstan et al.
Diabetes Care 2004;27:2603-2609.
ABSTRACT | FULL TEXT  

Well-Child Visits in the Video Age: Pediatricians and the American Academy of Pediatrics' Guidelines for Children's Media Use
Gentile et al.
Pediatrics 2004;114:1235-1241.
ABSTRACT | FULL TEXT  

Body image and physical activity in British secondary school children
Duncan et al.
European Physical Education Review 2004;10:243-260.
ABSTRACT  

Diet, Physical Activity, and Sedentary Behaviors as Risk Factors for Overweight in Adolescence
Patrick et al.
Arch Pediatr Adolesc Med 2004;158:385-390.
ABSTRACT | FULL TEXT  

Helping Parents Reduce Children's Television Viewing
Jason and Fries
Research on Social Work Practice 2004;14:121-131.
ABSTRACT  

Differences in Body Fat of British Children from Various Ethnic Groups
Duncan et al.
European Physical Education Review 2004;10:41-52.
ABSTRACT  

Association Between Clinically Meaningful Behavior Problems and Overweight in Children
Lumeng et al.
Pediatrics 2003;112:1138-1145.
ABSTRACT | FULL TEXT  

Television Watching and Soft Drink Consumption: Associations With Obesity in 11- to 13-Year-Old Schoolchildren
Giammattei et al.
Arch Pediatr Adolesc Med 2003;157:882-886.
ABSTRACT | FULL TEXT  

Association of Maternal Obesity and Depressive Symptoms With Television-Viewing Time in Low-Income Preschool Children
Burdette et al.
Arch Pediatr Adolesc Med 2003;157:894-899.
ABSTRACT | FULL TEXT  

Pediatric Obesity Policy: The Danger of Skepticism
Cuttler et al.
Arch Pediatr Adolesc Med 2003;157:722-724.
FULL TEXT  

Is Physical Activity Differentially Associated With Different Types of Sedentary Pursuits?
Feldman et al.
Arch Pediatr Adolesc Med 2003;157:797-802.
ABSTRACT | FULL TEXT  

Prevention of Pediatric Overweight and Obesity
Committee on Nutrition
Pediatrics 2003;112:424-430.
ABSTRACT | FULL TEXT  

Television Watching and Other Sedentary Behaviors in Relation to Risk of Obesity and Type 2 Diabetes Mellitus in Women
Hu et al.
JAMA 2003;289:1785-1791.
ABSTRACT | FULL TEXT  

Surveillance of Insulin Resistance in Children
Pereira and Ludwig
Clin. Chem. 2003;49:540-541.
FULL TEXT  

One-Year Changes in Activity and in Inactivity Among 10- to 15-Year-Old Boys and Girls: Relationship to Change in Body Mass Index
Berkey et al.
Pediatrics 2003;111:836-843.
ABSTRACT | FULL TEXT  

Behavioral Correlates of Television Viewing in Primary School Children Evaluated by the Child Behavior Checklist
Ozmert et al.
Arch Pediatr Adolesc Med 2002;156:910-914.
ABSTRACT | FULL TEXT  

Television Viewing and Initiation of Smoking Among Youth
Gidwani et al.
Pediatrics 2002;110:505-508.
ABSTRACT | FULL TEXT  

Evaluation of the Institutionalization of the Coordinated Approach to Child Health (CATCH) in a U.S./Mexico Border Community
Heath and Coleman
Health Educ Behav 2002;29:444-460.
ABSTRACT  

Assessing Risk Factors for Obesity Between Childhood and Adolescence: II. Energy Metabolism and Physical Activity
Salbe et al.
Pediatrics 2002;110:307-314.
ABSTRACT | FULL TEXT  

Management of Child and Adolescent Obesity: Psychological, Emotional, and Behavioral Assessment
Jonides et al.
Pediatrics 2002;110:215-221.
ABSTRACT | FULL TEXT  

The educational experiments of school health promotion for the youth in Japan: analysis of the 'sport test' over the past 34 years
Shingo and Takeo
HEALTH PROMOT INT 2002;17:147-160.
ABSTRACT | FULL TEXT  

School journeys and leisure activities in rural and urban adolescents in Norway
Sjolie and Thuen
HEALTH PROMOT INT 2002;17:21-30.
ABSTRACT | FULL TEXT  

Saturday Morning Children's Television Advertising: A Longitudinal Content Analysis
Byrd-Bredbenner
Family and Consumer Sciences Research Journal 2002;30:382-403.
ABSTRACT  

Fitness camp for obese children
Tso and Wong
Global Health Promotion 2002;9:44-44.
 

Evidence-Based Nutrition Principles and Recommendations for the Treatment and Prevention of Diabetes and Related Complications
Franz et al.
Diabetes Care 2002;25:148-198.
FULL TEXT  

Are Perceived Neighborhood Hazards a Barrier to Physical Activity in Children?
Romero et al.
Arch Pediatr Adolesc Med 2001;155:1143-1148.
ABSTRACT | FULL TEXT  

Physical activity in Dublin children aged 7-9 years
Hussey et al.
Br. J. Sports. Med. 2001;35:268-272.
ABSTRACT | FULL TEXT  

The Institute of Medicine's "Dietary Reference Intake" for Phosphorus: A Critical Perspective
Sax
J. Am. Coll. Nutr. 2001;20:271-278.
ABSTRACT | FULL TEXT  

Into the Mouths of Babes: The Diabetes Epidemic in Children
Levetan
Clin. Diabetes 2001;19:102-104.
FULL TEXT  

Physical Activity and Television Watching in Relation to Risk for Type 2 Diabetes Mellitus in Men
Hu et al.
Arch Intern Med 2001;161:1542-1548.
ABSTRACT | FULL TEXT  

Environmental Influences, Physical Activity, and Weight Status in 8- to 16-Year-Olds
Dowda et al.
Arch Pediatr Adolesc Med 2001;155:711-717.
ABSTRACT | FULL TEXT  

Coronary Heart Disease in the First 30 Years of the 21st Century: Challenges and Opportunities : The 33rd Annual James B. Herrick Lecture of the Council on Clinical Cardiology of the American Heart Association
Beller
Circulation 2001;103:2428-2435.
FULL TEXT  

Trends in Nutrient Intake of 10-Year-Old Children over Two Decades (1973-1994) : The Bogalusa Heart Study
Nicklas et al.
Am J Epidemiol 2001;153:969-977.
ABSTRACT | FULL TEXT  

Effects of Contingent Television on Physical Activity and Television Viewing in Obese Children
Faith et al.
Pediatrics 2001;107:1043-1048.
ABSTRACT | FULL TEXT  

The Need for Quality Physical Education
Gabbard
The Journal of School Nursing 2001;17:73-75.
ABSTRACT | FULL TEXT  

Children in Food-Insufficient, Low-Income Families: Prevalence, Health, and Nutrition Status
Casey et al.
Arch Pediatr Adolesc Med 2001;155:508-514.
ABSTRACT | FULL TEXT  

Television Watching, Energy Intake, and Obesity in US Children: Results From the Third National Health and Nutrition Examination Survey, 1988-1994
Crespo et al.
Arch Pediatr Adolesc Med 2001;155:360-365.
ABSTRACT | FULL TEXT  

Metabolic precursors and effects of obesity in children: a decade of progress, 1990-1999
Goran
Am. J. Clin. Nutr. 2001;73:158-171.
ABSTRACT | FULL TEXT  

Child Health in the Information Age: Media Education of Pediatricians
Rich and Bar-on
Pediatrics 2001;107:156-162.
ABSTRACT | FULL TEXT  

The spread of the childhood obesity epidemic
Andersen
CMAJ 2000;163:1461-1462.
FULL TEXT