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J Exerc Rehabil > Volume 13(4);2017 > Article
Yoon, Kim, and Rhyu: Effects of 16-week spinning and bicycle exercise on body composition, physical fitness and blood variables of middle school students

Abstract

The purpose of this study was to investigate the effects of 16 weeks of spinning and bicycling exercises on body composition, physical fitness and blood variables in female adolescents. Subjects participated in this study were 24 female middle school students (12 spinning cycles, 12 general bicycles) attending to Seoul Yeoksam middle school. Each group was trained for 16 weeks, 3 times a week, and 1 hr per day after school. Body composition, physical fitness (1,200 running, sit-ups, back strength, sit and reach, side-steps) and blood variables (low-density lipoprotein cholesterol, glucose, reactive oxygen species, and malondialdehyde) were examined before and after 16 weeks of training. As the results, body weight did not show any significant difference; however, body mass index, and % body fat were significantly difference in spinning group. The enhancement in physical fitness factors were recognized in both groups, which was greater in spinning group in sit-ups, back strength, and side steps. Blood parameters were significantly difference between groups, but between group and time interactions were significantly difference in glucose and reactive oxygen species. In conclusion, this study suggests that 16 weeks of bicycle exercises were positive changes in body composition, physical fitness and blood constituents, indicating that spinning cycle is more beneficial as compared to ordinary bicycle.

INTRODUCTION

Physical changes in adolescence begin from the age of 11 to the early 20 years, and sex differences are noticeable with changes in the endocrine system during the middle school period, which results in the rapid growth of secondary development. In addition to the development of the musculoskeletal system, somatic development may occur and, at the same time, differences in growth rates due to physical imbalance may arise (Greydanus and Omar, 2014).
In this period, most youth in Korea have experienced a great reduction in physical activities due to the rapid development of game culture using electronic devices instead of educational policies and physical activities centered on entrance examinations (Lee et al., 2015).
Regular physical activity plays an important role in improving the quality of life by preventing various diseases related to cardiovascular and pulmonary system and by preventing the incidence of degenerative diseases of the musculoskeletal system (Petersen and Ueda, 2008). In addition, regular exercise is known to reduce mental depression and anxiety and promote self-confidence (American College of Sports Medicine, 2013). In particular, the development of physique and physical fitness in adolescence has been reported to be particularly important since the poor health outcomes at this age may be carried out to adulthood and youthfulness (Cattuzzo et al., 2016). Regular physical activity has been shown to improve memory and learning skills, therefore, it is particularly important for school-aged adolescents (Chaddock et al., 2011).
Several studies in Korea have reported that sustained aerobic exercise has positive influence on obesity prevention and physical fitness in adolescents (Lee et al., 2010; Rhyu et al., 2014). Some studies have reported positive effects on body composition and blood lipid as a result of continuous exercise program participation (Lee et al., 2012; Strong et al., 2005).
Bicycling is one of the most popular sporting events in Korea. Many middle and high school students in Korea commute to school by bicycle. Recently, the popularity of spinning cycles is high, but it is an exercise that is carried out indoors rather than outdoors. It is an exercise modality using both upper body and lower body together with music of fast rhythm on a fixed bicycle, and is known as a popular sport especially for women. Especially, spinning is reported as an exercise that consumes twice as much calories as a general bicycle exercise (Battista et al., 2008; Caria et al., 2007; Hazelhurst and Claassen, 2006; Kang et al., 2005; López-Miñarro et al., 2010).
The purpose of this study was to investigate the effect of 16 weeks of spinning or bicycling exercises on body composition, physical fitness and blood variables of female middle school students and to propose an effective exercise mode for prevention of obesity and improvement of physical fitness.

MATERIALS AND METHODS

Participants

Twenty-four female middle school students participated in this study. Among them 12 students were randomly assigned to spinning cycle group (13.3±0.42 years) and the rest 12 students were to general bicycle group (13.4±0.38 years). Physical characteristics of the subjects are listed in Table 1.

Experimental procedures

Evaluation of body composition

The measurement of body composition was processed after arriving in examination place, removing the carried metals, urinated 30 min before measurement, and taking 5 min of break in comforting status. Weight, body mass index, and percentage of body fat were assessed using body composition measuring instrument, Inbody 720 (Biospace Co., Seoul, Korea).

Performance-related physical fitness tests

Performance-related physical fitness was evaluated by conducting tests related to aerobic capacity, muscle strength, muscle endurance, flexibility and Agility. Aerobic capacity was evaluated by measuring the time taken to finish a 1,200-m sprint. Muscle strength was evaluated based on the measurement of back muscle strength (Model 5402, Takei, Niigata, Japan) using a digital measuring instrument, muscle endurance by measuring the number of sit-ups performed in 60 sec, flexibility by measuring sit and reach, and agility by measuring side-step test.

Blood analysis

Blood samples were obtained from all subjects before and after the 16 weeks of exercise training. Blood samples were collected from the antecubital vein using 22-G needles after 30-min rest following body composition evaluation. The collected blood was subjected to analyses of total cholesterol (TC), low-density lipoprotein cholesterol (LDL-C), glucose, reactive oxygen species (ROS), and malondialdehyde (MDA).

Exercise program

The spinning group and bicycle group participated in exercise program, each group was trained for 16 weeks, 3 times a week, and 1 hr per day after school. Each exercise session consisted of a 10-min warm-up exercise, 40-min spinning or bicycle exercise, and 10-min cool-down exercise. The warm-up and cool-down exercises were comprised of 10 min of stretching and breathing exercises. The spinning and bicycle exercise were designed with consideration of target heart rate (THR) 45%–60%. All exercises were performed with supervision to ensure all exercise motions were performed accurately.

Statistical analysis

Statistical processing was performed using IBM SPSS Statistics ver. 21.0 (IBM Co., Armonk, NY, USA). It was used to calculate the mean and standard deviation values for data processing in the present study. To determine intergroup mean differences, repeated-measure two-way analysis of variance was conducted to analyze the main and interaction effects. The significance level (α) was set to P<0.05.

RESULTS

Table 2 shows the changes in body composition between spinning cycle and general bicycle groups following 16-week training. There were significant differences between groups (height: F= 64.816, P=0.001; % body fat: F=13.673, P=0.002). Also there were significant differences in the group×time (BMI: F=5.261, P=0.002; % body fat: F=11.922, P=0.001).
Table 3 shows the changes in physical fitness between spinning cycle and general bicycle groups following 16-week training. There were significant differences between groups (1,200-m run: F=29.173, P=0.000; sit-up: F=90.829, P=0.000; back strength: F=65.179, P=0.000; sit and reach: F=75.932, P=0.000; and side-step: F=204.223, P=0.000). Also there were significant differences in the group×time (sit-up: F=16.333, P=0.001; back strength: F=12.912, P=0.002; and side step: F=7.606, P=0.011).
Table 4 shows the changes in blood variables between spinning cycle and general bicycle groups following 16-week training. There were significant differences between groups (TC: F= 125.483, P=0.000; LDL-C: F=153.395, P=0.000; glucose: F=14.773, P=0.001; ROS: F=177.560, P=0.000; and MDA: F=45.794, P=0.000). Also there were significant differences in the group×time (glucose: F=8.048, P=0.01; ROS: F=7.707, P=0.011).

DISCUSSION

Results showed that 16 weeks of regular aerobic exercises induced positive changes in body composition, physical fitness, and blood variables, which is remarkably greater in spinning exercise group as compared to general bicycle group. It corresponds to the findings that spinning exercise consumes more energy than bicycling at the same exercise intensity (THR, 40%–65%) as reported by Dandanell et al. (2017) that 16-week aerobic exercise in female middle school students reduced BMI and % body fat, indicating that aerobic exercise is an effective tool to prevent obesity and reduce body fat. As results of regular aerobic exercise, cardiopulmonary endurance, muscular endurance and strength, flexibility and agility were improved, and regular exercise programs are important for maintenance and care. It is reported that it helps to improve the physical fitness of girls, especially those who have low activity (Lee et al., 2017).
The effect of 16 weeks of aerobic exercise on blood lipids was improved and the antioxidant function was also positively changed in this study, which corresponds to the previous report (Devries et al., 2008) that the blood lipids decreased and the ROS and MDA showed positive changes through regular aerobic exercise.
As shown in this study, physical activity of female middle school students improved physique, physical fitness, blood lipid index, and antioxidant function. In addition, it was concluded that even with the same intensity of aerobic exercise, the more energy consuming modality such as spinning exercise are more beneficial for physical development and fitness.

Notes

CONFLICTS OF INTEREST

No potential conflict of interest relevant to this article was reported.

ACKNOWLEDGMENTS

This work was supported by the Daejeon Health Institiute of Thchnology Research Fund (No. 2016018).

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Table 1
Physical characteristics of the subjects (n=24)
Group Age (yr) Height (cm) Weight (kg)
SC (n=12) 13.3±0.42 157.00±3.57 49.38±3.44
GB (n=12) 13.4±0.38 156.57±4.59 47.47±5.74

Values are presented as mean±standard deviation.

SC, spinning cycle; GB, general bicycle.

Table 2
Changes in body composition
Variable SC group (n=12) GB group (n=12) F-value


Pre Post Pre Post
Height (cm) 157.00±3.57 158.70±3.17 156.57±4.59 157.72±4.76 G 67.816***
T 0.178
G×T 2.526

Weight (kg) 49.38±3.44 49.21±3.30 47.47±5.74 48.89±5.69 G 1.841
T 0.36
G×T 2.954

BMI (kg/m2) 20.05±1.11 19.54±1.23 19.30±1.47 19.70±1.41 G 0.081
T 0.336
G×T 5.261*

Body fat (%) 22.07±1.23 20.85±1.07 22.40±2.84 22.35±2.59 G 13.673**
T 1.19
G×T 11.922**

Values are presented as mean±standard deviation.

SC, spinning cycle; GB, general bicycle; BMI, body mass index; G, group; T, time.

* P<0.05.

** P<0.01.

*** P<0.001.

Table 3
Changes in performance related physical fitness factors
Variable SC group (n=12) GB group (n=12) F-value


Pre Post Pre Post
1,200-m run (sec) 433.67±39.74 411.83±28.01 436.25±36.19 422.58±29.14 G 29.173***
T 0.25
G×T 1.544

Sit-up (rep/30 sec) 32.75±4.33 36.75±3.98 32.5±4.46 34.17±3.90 G 90.829***
T 0.712
G×T 16.333**

Back strength (kg) 64.62±6.23 69.83±5.03 62.50±6.31 64.50±5.62 G 65.179***
T 2.549
G×T 12.912**

Sit and reach (cm) 17.48±1.49 19.62±1.71 17.71±2.20 19.04±2.41 G 75.932***
T 0.049
G×T 4.214

Side step (rep/20 sec) 25.83±2.32 28.67±2.35 25.08±2.81 27.00±2.76 G 204.223***
T 1.357
G×T 7.606*

Values are presented as mean±standard deviation.

SC, spinning cycle; GB, general bicycle; G, group; T, time.

* P<0.05.

** P<0.01.

*** P<0.001.

Table 4
Changes in blood various
Variable SC group (n=12) GB group (n=12) F-value


Pre Post Pre Post
TC (mg/dL) 163.16±11.46 152.42±8.99 165.66±14.18 158.25±12.53 G 125.483***
T 0.751
G × T 4.225

LDL-C (mg/dL) 89.25±6.81 80.33±5.19 90.25±8.86 82.75±7.35 G 153.395***
T 0.358
G × T 1.142

Glucose (mg/dL) 83.50±6.41 77.42±6.76 82.08±8.66 81.17±5.81 G 14.773**
T 0.186
G × T 8.048*

ROS (pg/mL) 80.06±6.49 86.83±5.88 82.50±6.42 86.94±7.07 G 177.560***
T 0.238
G × T 7.707*

MDA (pmol/mg) 0.151±0.014 0.126±0.015 0.145±0.016 0.128±0.019 G 45.794***
T 0.97
G × T 2.293

Values are presented as mean±standard deviation.

SC, spinning cycle; GB, general bicycle; TC, cholesterol; LDL-C, low-density lipoprotein cholesterol; ROS, reactive oxygen species; MDA, malondialdehyde; G, group; T, time.

* P<0.05.

** P<0.01.

*** P<0.001.

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