Body Mass Index,Physical Activity,and Physical Fitness of Adolescence

Introduction

Adolescence is the period between 10-19 years of age in the human life cycle. This is the period of growth and development of the body when habits are formed related to health. ¹ These habits include lifestyles that affect adolescent and adult health. ² Furthermore, adolescents need an average of 60 minutes each day of moderate to vigorous physical activity (MVPA). These activities can be in the form of active walking, non-school physical activities, playing, sports, and physical education. Worldwide, about 80% of teenagers are not active enough. ³ Research in several European countries shows that only 26% of boys and 9% of girls are physically active, and performed MVPA ≥60 min/day. ⁴ According to the Global Matrix 3.0 report, ⁵ physical activity levels in children and adolescents are mostly low at 49 country. Furthermore, Mazur stated that only 17.2% of 11 to 15 -old years of age in Poland met the requirements of 1 hour of MVPA every day. Physical activity has a positive role on psychological and physical health. ⁶ Júdice et al. stated that adolescents which perform moderate or vigorous physical activity, and use their free time to do an activity, significantly improve health-related fitness. ⁷ Health in youth can be predicted from physical fitness.

Regular physical activity is an important part of a healthy lifestyle. It is associated with reduced risks of heart disease, obesity, and cancer. ⁸ It is also important for psychological well-being with lower stress levels and better cognitive function. Recent studies show that nearly half of the US student population does not participate in moderate or vigorous physical activity. ⁹ Therefore, this research aimed to examine the relationship between fat mass percentage, body composition, physical activity, and physical fitness.

Design and Methods

This is an analytical, observational, and cross-sectional research design. The samples totaled 70 male and female students at a junior high school in Surabaya, East Java, Indonesia which were selected by simple random sampling technique. Anthropometric measurements, including height, were performed using a microtoise. Body weight, fat mass percentage and body mass index (BMI) were measured by bioimpedance using a Tanita device (Tanita Corporation, Japan). Furthermore, the consumption intake was carried out using a 2x24 hour recall method and analyzed via a nutrisurvey. The data on physical activity was obtained via the IPAQ (International Physical Activity Questionnaire) method, while physical fitness was calculated by measuring VO₂max. The VO₂max measurements involved the application of the Multistage Fitness Test (MFT) method, which has 23 levels, each lasting approximately 1 min. In practice, individuals go through several levels, and the speed between the beeps will decrease to give less time for the individual to complete each level, and then increase in intensity. A single sound indicates the end of each shuttle, while three simultaneous beeps signify the beginning of the next level. Data analysis used SPSS ver. 22. Descriptive analysis was calculated to determine the percentage of consumption intake, fat mass percentage, body mass index, physical activity, and physical fitness. Furthermore, the Pearson Correlation Test was used to analyze the relationships between variables. Before the data collection procedure, all participants were provided with information about the study and the right to withdraw at any time. A written, informed consent was submitted by participants to indicate their agreement to participate in the study.

Results and Discussions

Table 1 describes the characteristics of participants in this study and Table 2 shows a significant relationship (<0.05) between fat mass percentage, body mass index, and physical activity with physical fitness. The coefficient of physical activity is positive, which means that a greater coefficient value results in increased physical fitness. Alternatively, the coefficient of body mass index and fat mass percentage is negative, which means that a greater coefficient value will reduce physical fitness.

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Table 1

Characteristics of participants.

Characteristics	n	%
Sex
Boys	35	50.0
Girls	35	50.0
Energy intake
< 2000 kcal	44	63
2000 – 2499 kcal	13	19
2500 – 2999 kcal	8	11
3000 – 3499 kcal	5	7
Minimum	1000
Maximum	3360
Mean	1827,8
SD	592,9
Physical activity
Low (< 600 MET-min a day)	13	18.5
Moderate (600 - <1500 MET-min a day)	52	74.3
High (1500 - <3000 MET-min a day)	5	7.2
Body mass index
Underweight (BMI ≤18.4)	15	21.4
Normal (BMI 18.5-25)	48	68.6
Overweight (BMI ≥25.1)	7	10
Fat mass percentage
Lean (<8%)	8	11.4
Optimal (8-15%)	12	17.2
Slightly overfat (16-20%)	9	12.8
Fat (21-24 %)	10	14.3
Obesity (>25%)	31	44.3
Physical fitness
Very poor	38	54.3
Poor	16	22.8
Fair	10	14.3
Average	5	7.2
Good	1	1.4

MET, metabolic equivalents; BMI, body mass index.

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Table 2

Relationship between variables.

	Pearson correlation (r)	p-value
Energy intake	0.223	0.064
Fat mass percentage	-0.615	0.000
Body mass index	-0.276	0.021
Physical activity	0.441	0.000

The aim of this research was to examine the relationship between energy intake, body mass index, percentage fat mass, physical activity, and physical fitness in schoolchildren aged 13-14 years. Physical fitness is defined as “a set of attributes that people possess or attain concerning their ability to perform physical activity”. It includes physiological, health-related, and skills-related fitness. Optimal energy requirements are very important for physical fitness, and its determinant is primarily physical activity, ¹⁰ which includes all forms of muscular and physical exercise. Specifically, physical activity involves planned and structured body movements designed to improve physical fitness.

Adequate energy requirements are the proper amounts of dietary energy required to balance total energy expenditure (TEE) and maintain body weight. TEE reflects the sum of the resting metabolic rate (60-75%), energy used for food-induced thermogenesis (10%) and energy expended through physical activity (15-30%). The energy utilized during physical activity is the most variable component of TEE. It is dependent on the subject's activity, lifestyle, type of physical exercise, gender, hormonal balance and previous nutritional status.^11,12 Another study found that overweight obese adolescents used more energy expenditure and energy intake compared to other underweight or normal weight groups. ¹³ In addition to this, certain physical activities, such as playing computer may also increase energy expenditure in adolescents. ¹⁴

Overall, the results showed that the higher the body mass index, the lower the fitness level. Conversely, when physical activity is higher, physical fitness is better. Inadequate physical activity is not only associated with an increased fat mass percentage but also causes a decrease in relative muscle mass. The more muscle mass involved during exercise, the greater the contribution of muscle pump to venous return. Therefore, an increase in muscle mass helps to improve cardiac output. In this study, a negative correlation (r = -0.615) was observed between fat mass percentage and physical fitness. This is a strong correlation which signifies that an increase in fat mass percentage may be responsible for a decrease in physical fitness. The observation of a higher correlation coefficient of body fat percentage and body fitness compared to BMI and fitness showed that obesity in terms of fat mass percentage was a better parameter for predicting low cardiorespiratory functional status or fitness in young adults than BMI. Therefore, during an exercise program, when possible, the measurement of percentage body fat is more significant than the BMI parameter. Increased physical activity or regular exercise can help to decrease the fat mass percentage which aids relative increases in non-fatty masses, thereby improving fitness. Additionally, health educators could motivate adolescents to maintain their physical activities in order to support and gain the benefits of normal weight.^15-18 Therefore, the suggestion to reduce fat mass percentage with the help of increased physical activity or exercise would reduce health risks in young adults.^19,20

In adolescents aged 12-18 years, there was a non-linear relationship observed between BMI and the results of physical fitness tests or motor performed. Respondents with an obese or obese nutritional status and other participants with skinny nutritional status had poorer fitness test scores compared to participants with normal nutritional status. ²¹ Furthermore, in the adolescents aged 12-15 years, the best results of physical fitness measurements were held by respondents with a normal BMI level, while lower results were observed in respondents with BMI in the skinny range, and the lowest observed in individuals in the obese category. This may occur due to overweight, especially the mass of body fat that shows inaction because it takes more energy and longer time to efficiently move the entire body mass.^22-25

Conclusions

An increased fat mass percentage is associated with decreased levels of physical fitness, and an increase in fat free mass significantly increases physical fitness in healthy young adults. In addition, obesity in terms of percentage fat mass is a better determinant than BMI for low physical fitness.