Normative reference of standing long jump indicates gender difference in lower muscular strength of pubertal growth ()
1. INTRODUCTION
Physical fitness tests are highly recommended as part of a successful health and fitness screening and surveillance system for their moderate tracking of physical activity from childhood to adulthood [1]. Proper field tests offer reliable and valid results in mass testing [2,3], and many physical educators should adopt field tests instead of sophisticated laboratory equipment to assess physical fitness in schools and communities.
Among these field tests, the standing long jump (SLJ) is considered the most valid field-based muscular fitness test compared with isokinetic strength exercises [4]. A cross-sectional study of Brazilian students aged 7 - 15 showed that the single SLJ could possibly reflect the overall fitness level indicated by other muscular tests such as the 1-minute curl-up, pull-up, ball throw, 9-minute run, 20-meter run and 4-meter shuttle run [5]. Recent studies of healthy Caucasian girls aged 6 - 17 have also indicated a strong association between the SLJ and other lower-body muscular strength tests [6]. Indeed, SLJ tests can be practical, time-efficient and affordable methods for assessing muscular fitness in young children.
However, an updated SLJ reference standard is required for the physical educators, particularly for China. Sufficient normative data on schoolchildren are not available for physical educators to interpret and compare measured results. The few recent related studies published limited data [7-11]. In addition, the age ranges (9 - 10, 6 - 12 and 7 - 15) and sample sizes (no more than 500) of these studies have been narrow [7,9,11]. The results from these studies are difficult to apply as normative data. A recent systematic review attempted to consolidate the data for this purpose, but the results were validated only for 9- to 15-year-olds and Australian children.
In fact, nationwide student fitness surveys were conducted in Taiwan in 1997 [12] and in mainland China in 2000 and 2005 [13,14]; and limited long jump data were published for comparison. Among the three Chinesepopulated locations surveyed, only Hong Kong has not established a systematic physical fitness assessment on a large scale. This study aimed to generate normative SLJ test data for schoolchildren aged 8 - 18 and to present the first large-scale SLJ norms for Chinese children in Hong Kong. The results could prove useful in the screening of lower muscular fitness for children in school settings.
2. SAMPLES AND METHODS
From September 2005 to December 2011, a university research team conducted comprehensive physical fitness assessments for primary and secondary schoolchildren. A snowball sample process was implemented to recruit and refer schools that were interested in carrying out the assessments. Each student completed a battery of field tests according to the China Education Bureau Protocol [15]. This study followed the Helsinki Deceleration of 1975 and was approved by the Ethics Committee of the University. All of the students and their parents were given information sheets describing the purpose and application of the physical fitness assessments. They were asked to sign consent forms before the assessments were administered. Its measurement and instrument details were described [16,17] previously. Body height in centimeters (cm) and body weight in kilograms (kg) were measured in the physical fitness assessment. Body weight was taken and rounded to the nearest 0.1 kg and body height was taken and rounded to the nearest 1 cm.
The SLJ measurement model was used and calibrated on each day of data collection. Children aged 8 or above were invited to take an SLJ test. Each student’s longest jump distance from the starting point to the endpoint after two attempts was measured in centimeters. PE teachers and university student helpers were responsible for conducting the mass field measurements at the schools. All PE teachers and university student helpers were trained to use the equipment and ensure that the participating students gave their best performances during the tests.
In total, six primary schools and 17 secondary schools carried out physical fitness assessments. According to the data collected, a total of 14,988 students took part. Because students aged under 8 did not take the SLJ tests and some of the students were not of Chinese ethnicity, only 12,712 students aged 8 - 18 contributed to the establishment of normative standards in this study.
3. DATA ANALYSIS
All analysis was conducted with Statistical Package for the Social Sciences, version 20. Paired t-test was used to compare means of distances performed in SLJ between boys and girls at the same age. A significance level of 1% was used for statistical testing. The results are presented stratified by age and sex, stating the interquartile range of SLJ performed distance, as well as percentiles of P5, P10, P25, P50, P75, P90, and P95. Interpolated 10th, 30th, 50th, 70th and 90th percentile curves of the SLJ results for the total cases were presented by gender.
Body mass index (BMI) was calculated with body weight in kilograms over square of body height in meters. BMI was categorized into “underweight”, “normal”, “overweight” and “obese” with the BMI cut-off points in Chinese population [13]. Median (P50) of SLJ with ages was plotted in BMI categories by sex. Continuous data of age and BMI were used to predict results in SLJ with linear regression.
4. RESULTS
The SLJ performances were significantly different between boys and girls, with all age groups at a 0.01 significance level (Table 1). The boys performed better than the girls in each age group. The mean difference increased as the age increased, depicting a prominent variance in muscular strength between boys and girls at age 12, and the variance became larger at age 18.
The interquartile range (IQR) showed a gender-specific normal distribution for the SLJ performances. The IQR shown in Table 2 indicated a narrow bell-shaped distribution for boys at lower ages that became wider as the age increased. The IQR also began with a narrow bell-shaped distribution for girls aged 8 and 9. The bell-shaped curve became wider as the age increased to 15 before decreasing at ages 16 - 18.
Figure 1 shows that the 30th, 50th, 70th and 90th percentile curves for male students all sloped up as the age increased. However, the 10th percentile curve differed from the other percentile curves, dropping at age 16. The 10th, 30th, 70th and 90th percentile curves of female students had similar shapes. However, unlike the male student percentile curves, they were flat and did not increase much with the age. The female students’ 50th percentile curve lined in a similar way but peaked at age 15. In comparison, the boys showed better lower muscular strength performances than the girls. Girls in the 70th percentile performed similarly to boys performing in the 10th percentile.
Medians of SLJ in each BMI categories were depicted in Figure 2. The results of boys in the four body size were in upward trends with underweight group performed the best, followed by normal body size, overweight and obese. Patterns of medians SLJ were regular for boys, except results at age 18 which showed a significant increase in the test performance. However, the patterns of SLJ were in saw tooth shape for girls. Similar to the boys, underweight girls performed the best in SLJ, followed by normal size girls, overweight girls and obese girls.
With linear regression, age and BMI were the predict-
Table 1. Gender differences in standing long jump results by paired t-test.
tors for the dependent variable of SLJ. The statistic results of R, R square and SEE were 45.0%, 20.2% and 33.272 (p < 0.001) respectively in boys, while those corresponding results of girls were 17.3%, 3.0% and 26.459 (p < 0.001). The formulated regression equations were as follows:
Boys: SLJ = 112.97 + 7(Age) − 2.08(BMI)
Figure 1. Interpolated 10th, 30th, 50th, 70th and 90th percenttile curves of the standing long jump for the total cases by gender.
(a)(b)
Figure 2. Relationships of SLJ performance on age, sex and different body size.
Girls: SLJ = 129.6 + 1.36(Age) − BMI With all constants and independent variables significantly contributed in predicting SLJ (p < 0.001).
5. DISCUSSION
According to the Census and Statistics Department [18], there were 423,700 children aged 10 - 19 in Hong Kong in 2011. This study covered 3% of the children and adolescents in Hong Kong’s population and we measured lower muscle strength with SLJ distance testing. While
Table 2. Standing long jump (cm) percentile summary of Hong Kong schoolchildren by age and gender.
the normative reference should be ethnic specific, most of the few published works on SLJ tests have focused on Caucasian populations. Criterion-referenced standards for Chinese were published with the data collected in 2000, however, the validity of criterion-referenced standards in classifying test results could not be found. Therefore, it has long been a problem for physical educators or sports trainers to evaluate the ability of a child’s lower muscular strength with standard reference. This study established the first normative data for the SLJ test for Hong Kong Chinese school students which proposed reference values and explored variations between boys and girls at the same age.
The data collected in this study showed that the gender differences in lower muscular strength were small when the children were aged 8 - 11. The differences in lower muscular strength enlarged by age 12 and further broadened until ages 17 - 18. This corresponds to the puberty stages of boys and girls. Under the influence of gonadal steroid hormones and the growth hormone, bone mineral content or muscle mass increases faster in boys. In addition, while testosterone affects boys with a significant increase in bone and muscle growth, it decreases the deposition of fat in the limbs. The increase in skeletal size and muscle mass leads to augmented strength in boys, and more than 90% of an adolescent’s peak skeletal mass is present by age 18 [19-21].
The onset of muscle strength for boys found in this study also corresponded to the finding of Leung [22] that 50% of Chinese boys develop a testis size of 4 millilitres by ages 11 - 12, positioning the age of sexual maturation in Chinese boys between 11 and 12. The testosterone produced also influences the rapid increase in muscle tissue in boys at these ages, contributing to the muscle spurts found in this normative data.
It was found that body size affected the performance in SLJ test, regardless of gender. The findings of better performance in underweight and poor performance in obese supported the assumption that heavy body discounted lower muscular strength significantly. However, with the growth in muscle mass along with age increase, boys in different body size showed increasing lower muscle strength in puberty and this pattern could not be found for girls. This could be explained by the formulated model in linear regression that the constants in predicting SLJ were similar in boys and girls. But the coefficient of age in boys was about 5 times that of girls. It indicated that each advance in age for boys multiplied the age factor five times that of girls. Besides, BMI factor in boys was two times deduction than that in girls for predicting the SLJ, showing body size of boys affect SLJ results more than that of girls. The findings in this model addressed the proliferated SLJ performance with age and BMI in gender difference. Boys and girls in younger ages could possibly perform similarly if they were in similar BMI. But the performance difference could increase drastically studied in higher forms and this difference becomes broadened to overweight and obese boys and girls.
6. LIMITATIONS
This study has limitations associated with the wide recruitment range of the participating students at each age. It is a common situation for Hong Kong schools to have fewer classes at the upper level of study (Form 6 and Form 7) and more classes at the lower level of study (Form 1 to Form 5), as half of the students cannot be promoted after taking their Hong Kong Certificate Examination in Form 5. This means that significantly fewer students aged 16 - 18 were recruited if their entire schools signed on for our physical fitness assessments. In addition, the birth rate in Hong Kong has dropped dramatically in the last decade, making it difficult for the research team to recruit a commensurate sample of primary school students compared with secondary school students.
7. CONCLUSION
This study is the first to publish normative SLJ test data for a large sample size of Chinese students in Hong Kong. The normative data covered a wide range of ages (8 - 18) and indicated the lower muscular strengths of boys and girls across the childhood, puberty and maturity stages. The SLJ performances tends to increase with age and the findings identified muscular strength differences between genders during growth, adding supporting evidence to the hormonal influence of muscle growth during puberty. This study also explained the effect of age and body size on SLJ performance, and how the gender difference affect the SLJ results.