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Relations of moderate and vigorous physical activity to fitness and fatness in adolescents^1,2,3

¹ From the Georgia Prevention Institute, Department of Pediatrics, Medical College of Georgia, Augusta, GA (BG, MCH, and PB), and the Department of Health and Kinesiology, University of Texas at San Antonio (ZY).

² Supported by the National Institutes of Health (HL64157).

³ Reprints not available. Address correspondence to B Gutin, Georgia Prevention Institute, Department of Pediatrics, Medical College of Georgia, 1499 Walton Way, Augusta, GA 30912. E-mail: bgutin{at}mcg.edu.

	ABSTRACT

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Background: It is unclear how moderate and vigorous intensities of physical activity (PA) are associated with cardiovascular fitness (CVF) and percentage of body fat (%BF) in adolescents.

Objective: We tested the hypothesis that vigorous PA, to a greater degree than moderate PA, would be associated with better CVF and lower %BF.

Design: This was a cross-sectional study of 421 black and white high school students ( age: 16 y). PA was measured with 5 d of accelerometry and expressed in min/d of moderate or vigorous PA. CVF was measured with a multistage treadmill test and was expressed as the oxygen consumption at a heart rate of 170 bpm. %BF was measured with dual-energy X-ray absorptiometry. Multiple regressions were used to determine the degree to which variance in CVF and %BF was explained by PA, after control for age, sex, race, and the sex x race interaction.

Results: A higher index for CVF was associated with higher amounts of moderate and vigorous PA; more variance was explained by vigorous than by moderate PA. Lower %BF was associated with higher amounts of vigorous PA but not with the amount of moderate PA.

Conclusion: Black and white adolescents who engaged in relatively large amounts of free-living vigorous exercise were likely to be relatively fit and lean.

Key Words: Adolescents • physical activity • accelerometry • fitness • adiposity

	INTRODUCTION

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
The prevalence of obesity among juveniles is reaching epidemic proportions, with ominous implications for future public health (1). Poor cardiovascular fitness (CVF) is another important health problem (2). Because both of these biologic characteristics track from childhood into the adult years (3), it is desirable to formulate effective preventive recommendations and strategies starting early in life. One key issue is ascertaining the intensity of physical activity (PA) that is most likely to lead to better CVF and less fatness.

Although controlled experimental designs are desirable for establishing causal relations, such studies require long periods of controlled PA to test the hypotheses. Observational studies of free-living PA can provide data that are consistent or inconsistent with causal hypotheses. This observational study tested the hypothesis that, in adolescents, free-living PA, especially vigorous PA, would be associated with better CVF and lower percentage of body fat (%BF) than would a lack of PA (4); PA was measured objectively with accelerometry.

	SUBJECTS AND METHODS

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Subjects
Adolescents were recruited from high schools in the area of Augusta, GA. Demographic information obtained from the school systems was used to select schools that enrolled both black and white students. In the Augusta area, relatively few students are from other racial or ethnic groups, and those few were excluded from the project. After receiving approval from the school principals, we distributed flyers to all students in the selected schools. For this report, we analyzed data from 421 subjects for whom we had complete data on all relevant measures. Subjects and their parents signed informed consent and assent documents in accordance with the Medical College of Georgia Human Assurance Committee.

Pubertal development
Subjects were placed in a private room alone and asked to read a prepared script and view a series of pictures showing different stages of pubertal development (5, 6). Male subjects self-determined gonadal and pubic development on a scale of 1 to 5. Female subjects self-determined breast and pubic development on a scale of 1 to 5. Female subjects answered 2 questions about menses: 1) whether they had had their first menstrual period, and 2), if so, when was the first day of their last menstrual period. Eighty-eight percent of the adolescents were in Tanner stages 4 and 5.

Anthropometry and body composition
Body weight (in shorts and tee-shirt) and height (without shoes) were measured with an electronic scale (model CN2OL; Cardinal Detecto, Webb City, MO) and wall-mounted stadiometer (Tanita Corporation of America, Arlington Heights, IL), respectively, and converted to body mass index (BMI; in kg/m²) to provide descriptive data. We used %BF rather than BMI as the primary index of fatness because BMI can misclassify as obese persons who have large amounts of fat-free mass, such as those who do large amounts of vigorous PA, and who in fact are overweight (7). It is fatness rather than weight that is associated with poor health (8).

%BF was measured with dual-energy X-ray absorptiometry (DXA; Hologic QDR-4500, Waltham, MA; software version 6.0). We previously found DXA to provide reliable %BF values in children (9). In this project, we performed repeat measurements on the new QDR-4500 machine with 219 adolescents and found the intraclass correlation for %BF to be 0.99 (10). For some subjects, DXA values were not available from the Hologic QDR-4500W model but were available only from the Hologic QDR-1000W model. For those persons, %BF values were derived from the prediction equations based on 284 adolescents who were assessed on both instruments, with the use of linear regression; race, sex, and QDR-1000W measurement were the predictor variables. The multiple R² value for %BF was 0.99.

Cardiovascular fitness
CVF was measured with a multistage treadmill test. Heart rate (HR) was monitored with the use of a Polar Accurex Plus HR monitor (Port Washington, NY). Oxygen consumption (O₂) was measured with the use of a Sensormedics Vmax 229 cardiopulmonary system (Yorba Linda, CA). The treadmill protocol began with a 3-min warm-up at 0% grade and 2.0 mph. The speed was then increased 0.5 mph every 2 min until it reached 3.5 mph, at which time the grade increased 2% every minute until it reached 16% grade, after which the treadmill speed was increased by 0.5 mph every minute until voluntary exhaustion. Verbal cues were given to encourage a maximal effort. The subject was considered to have attained O_2max if he or she met 2 of the following 3 criteria: 1) an increase in HR <5 bpm between the final 2 workloads, 2) an increase in O₂ <100 mL between the final 2 workloads, and 3) a respiratory exchange ratio >1.00 (11).

Our primary index of CVF was submaximal in nature: the O₂ at an HR of 170 bpm per unit of body weight (O₂170, mL · kg^–1 · min^–1) (12). The HR at a given submaximal level of work or energy expenditure is a well-established submaximal and objective index of fitness in adolescents (13). Using all the treadmill workloads completed by each adolescent, we computed individual regression equations of O₂ on HR for each adolescent. The O₂ (in L/min) corresponding to an HR of 170 bpm was calculated for each adolescent and expressed per unit of body weight (mL · kg^–1 · min^–1). Adolescents who are more fit exhibit a higher O₂ (ie, a higher treadmill work rate) before their HRs reach 170 bpm. That is, a given metabolic load puts less strain on the cardiovascular system of adolescents who are more fit (and often relatively lean).

Accelerometry
Free-living PA was measured with the use of MTI Actigraph monitors (model 7164; MTI Health Services, Fort Walton Beach, FL). The Actigraph uses a uniaxial accelerometer that measures vertical acceleration and deceleration in 1-min epochs. This accelerometer can be used to discriminate among light, moderate, and vigorous levels of PA (14). The monitors were initialized to begin recording when the subject left our laboratory after the first half day of testing. The monitors were affixed above the iliac crest of the right hip with an elastic belt in accordance with findings of Puyau et al (15), which suggests that this is the most efficacious placement. A research assistant instructed the subjects in the proper way to wear the monitor. The subjects were instructed to 1) wear the monitor for a period of 7 d, 2) remove it for sleep and any activity that may cause harm to either the monitor or another person (eg, during contact sports), and 3) bring the monitor back to us 1 wk later. These data were downloaded into a computer. Data from day 1 and day 7 were discarded because a full day of information was not available for those days. Because we could not always schedule the subjects for exactly 7 d after the first visit, we sometimes had less than a full week's data; thus, we used in the analyses the 5 d immediately after the first visit. Movement counts were converted to average minutes per day spent in resting or light [<3 metabolic equivalents (METs)], moderate (3–6 METs), vigorous (6–9 METs), and very vigorous (9+ METs) PA (16). The minutes per day spent doing vigorous and very vigorous levels were combined into 1 variable (vigorous PA).

Controversy continues about the best way to express PA. If it is expressed as energy expended in movement, then heavier adolescents will appear to be engaging in relatively large amounts of PA because they use more energy than do lighter adolescents to move their bodies a given amount. The net result is that it will appear that heavier and lighter adolescents engage in similar amounts of PA (17). However, when PA is expressed as movement rather than energy expenditure (18), or if adjustment is made for body weight (17), then obese adolescents will appear to engage in less PA than do nonobese adolescents. For purposes of making exercise recommendations, the time spent in activities of various intensities seems more pertinent. Therefore, we expressed free-living PA as time spent (ie, min/d) in PA of a moderate or vigorous intensity; for some analyses, we used the total of both (MVPA).

Statistical analyses
All variables used in the study were checked for normality of distribution before the analyses, and appropriate transformations were applied when necessary. Group comparisons were made on unweighted means by using 2 x 2 analysis of covariance (sex x race) with adjustment for age. Pearson's correlations were used to examine bivariate relations among the key variables. Hotelling's t test was used to test the differences between correlated coefficients of correlation.

Standard multiple regression was used as the primary method to determine the degree to which variance in CVF and %BF was explained by PA after control for age, sex, race, and their interaction. When we used pubertal development rather than age in the analyses, the variance explained by the demographic variables was similar; thus, in the interests of parsimony, we used age in the statistical analyses.

Parallel analyses were done with either CVF or %BF as the outcome variable. We conducted analyses by using moderate PA and vigorous PA separately as well as the combined MVPA. For each of the outcome variables, we tested a series of models. Thus, model 1 addressed the influence of moderate PA and its interactions with the covariates, model 2 examined the influence of vigorous PA and its interactions with the covariates, and model 3 examined the influence of MVPA and its interactions with the covariates. In model 4, we tested two-factor interaction terms of PA with age, sex, and race and retained them in the models if they made significant contributions.

Statistical significance was set at P < 0.05 in all analyses. The statistical analyses were conducted with SPSS software (11.5; SPSS Inc, Chicago, IL).

	RESULTS

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Descriptive statistics
The group means and the race x sex comparisons for the key variables are shown in Table 1. Although detailed discussion of these differences is beyond the scope of this report, we include them to indicate the adjustments that were made in analyzing the effect of PA. Adolescent girls had higher %BF than did adolescent boys. For CVF (O₂-170), adolescent boys and whites had significantly higher values than did adolescent girls and blacks, respectively. The adolescent boys had significantly higher values than did the adolescent girls on moderate and vigorous PA.

Table 2

Table 3

	DISCUSSION

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
The primary finding of this study is that, after adjustment for demographic factors, adolescents who engaged in relatively large amounts of vigorous PA tended to have a better CVF and a lower %BF than those who did not. For %BF, participation in moderate PA did not explain a significant proportion of the variance. For CVF, moderate PA did explain a significant but smaller proportion of the variance in CVF. The relation of vigorous PA to lower levels of body fatness is consistent with the results of other recent studies in San Diego adolescents (19) and European 9–10-y-olds (20). An intervention study from our institute found that obese adolescents who maintained a higher intensity of exercise during physical training sessions tended to be those who improved most in CVF and %BF; however, some obese adolescents found it difficult to maintain high-intensity PA (12).

Some observational studies have failed to show differences between obese and nonobese adolescents in free-living PA, especially when PA was expressed as energy expenditure (derived from doubly labeled water), rather than as movement. One limitation of such studies is that it is difficult to know how to express energy expenditure during PA to account for differences in body composition; ie, heavier adolescents use more energy than do lighter adolescents to move their bodies for a given amount of PA (17). Another limitation is that such studies cannot distinguish moderate PA from vigorous PA (21). Therefore, studies that use energy expenditure to measure PA have not always found that fatter adolescents were less active than leaner adolescents, even though the former did show differences when PA was expressed as movement rather than energy expenditure (18, 22, 23).

An important limitation to this study is that it was cross-sectional in nature, thereby precluding the conclusion that high levels of vigorous PA cause adolescents to be more fit and less fat. Because there is a substantial hereditary component to both fitness and fatness (24), an adolescent who inherits a predisposition to be unfit or obese may tend to be less likely to engage in vigorous PA. The most likely scenario is that these relations are cyclic, with the result that a change in one is likely to cause a change in the other. That the cycle can be driven in a positive direction is supported by experimental studies in obese adolescents that showed controlled physical training to improve fitness and reduce fatness (25). However, the picture is less clear for nonobese adolescents, in whom several studies failed to show that such physical training improved fitness and body composition (26, 27). The limited information available suggests that, for nonobese adolescents, the interventions should be high in both intensity and volume (>80 min/d) (28, 29). Taken together, these data suggest that general exercise recommendations for adolescents should encourage vigorous PA. However, for 2 reasons, it is reasonable to recommend moderate PA for obese and unfit adolescents until higher intensities can gradually be attained. First, PA that is classified by time-motion analysis as moderate, such as brisk walking, may actually be quite strenuous for some unfit and obese adolescents. Second, vigorous PA that is especially tiring may lead adolescents to do less PA on the following day (30), thereby being counterproductive in the long term. Therefore, it seems sensible to encourage unfit and obese adolescents to engage in moderate PA and appropriate dieting, gradually progressing to higher intensities as they become more fit and less fat.

	ACKNOWLEDGMENTS

 
We appreciate the assistance of Elizabeth Stewart in data management, Mark Litaker in statistical consultation, and several research assistants in data collection; we also appreciate the schools that cooperated in subject recruitment and the adolescents who served as subjects.

BG and PB participated in the design of the study and preparation of the manuscript. ZY performed the statistical analyses and participated in the preparation of the manuscript. MCH played an important role in the implementation of the study and data collection and participated in the preparation of the manuscript. None of the authors had any conflict of interest.

	REFERENCES

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 

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