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As the burden of disease increases, there is a growing awareness of the dangers of elevated blood glucose (1). The incidence of diabetes among adolescents is increasing year over year, and the average annual growth rate of diabetes among children and adolescents in the United States is 2.3%. Elevated blood glucose has many hazards if not treated in time and regularly as it will not only affect the growth and development of children but also cause complications such as diabetic ketoacidosis and cataracts. In severe cases, it can lead to blindness and psychological disorders for children (2). Obesity is thought to be the catalyst for diabetes which can lead to an increase in blood glucose in individuals. A close relationship has been observed in recent decades between rising rates of obesity and an increased incidence of type-2 diabetes among adolescents (3-4). In the 2020 diabetes medical standard published by the American Diabetes Association (ADA), Body Mass Index (BMI) is the primary risk factor in the screening and diagnosis of adolescent type-2 diabetes (5). This paper used the blood glucose data of 7,786 adolescents aged 12–20 years from 1999 to 2018 of the National Health and Nutrition Examination Survey (NHANES). Quantile regression was used to analyze the blood glucose of adolescents to explore the influence of gender on blood glucose under different quantiles. At the same time, the results of model correction of BMI were also analyzed. The blood glucose of the female 15-year-old group was close to the normal distribution, and the blood glucose of adolescents of men and women of other ages did meet the normal distribution and was not suitable for typical linear regression analysis. The regression coefficients of gender factors in different ages and quantiles were obtained through the two models and revealed that male blood glucose was higher than female blood glucose and all age groups were statistically significant (P<0.05). A picture of regression coefficients based on different scales showed a downward trend in regression coefficient with the increase of age. There is an urgent need to set up standards for adolescent blood glucose according to various ages and genders.
The NHANES is a sustained survey project implemented by the US CDC since 1999, which uses a much more complex stage probability sampling to sample the American population (6-7). A cycle takes two years and is designed to assess the health and nutritional status of adults and children in the United States. The data of the project is free to the public, and no additional ethics application is required. In this study, the blood glucose data of 12–20 years old adolescents from 1999 to 2018 in NHANES was used for analysis, and 7,786 individuals had suitable data.
The statistical analysis was carried out with SAS software package (version 9.4, 100 SAS Campus Drive Cary, NC 27513). Quantile regression does not require the distribution of data but requires the minimization of residual error. Different estimators of regression coefficients under different quantiles reflect that explanatory variables have different effects on different levels of explanatory variables. Quantile regression integrates the concept of the quantile into ordinary linear regression. However, the conclusion no longer only reflects the central position but can reflect the whole distribution situation. Model one was a single factor quantile regression analysis without any controlling factors, and model two was a multivariate quantile regression analysis after controlling BMI.
According to ADA’s medical standards for diabetes in 2020, the normal range of adult blood glucose is 70–100 mg/dL. In this dataset, the blood glucose level in the 1st percentile was 72 mg/dL, the 85th percentile was 100 mg/dL, and their middle position was in the 42nd percentile. Therefore, the regression equation was established at the five percentiles of P1, P42, P50, P85, and P90, and the partial regression coefficients under different quantile regression were recorded. The inspection level α was set to 0.05.
The analysis showed that for adolescents aged 12–20 years, the distribution of blood glucose levels at different ages varied (Table 1). By analyzing the regression coefficients of gender factors at different ages and different quantiles, gender factors in each age group of 12–20 years old were found to be statistically significant except in the P1, and the blood glucose level were higher in males than in females. After controlling for BMI, Model two found that the decrease in blood glucose levels was inconsistent with Model 1, such that for the 12-year-old age group, the regression coefficients for gender of Model 1 and Model 2 at P42 were –2.7 and –3.1, respectively; at P50, the gender factor was –2.8 and –3.07, respectively; and at P85, the gender factor was –4.0 and –4.1, respectively (Table 2). Other age groups also show the same phenomenon.
Age (years) Total Male Female n P25 P50 P75 n1 P25 P50 P75 n2 P25 P50 P75 12 1,001 88.5 93.7 98.0 463 90.0 95.0 99.7 538 87.7 92.3 96.4 13 914 88.0 93.0 98.0 466 90.0 95.0 99.5 448 86.2 92.0 96.0 14 902 87.8 92.1 97.3 407 89.2 95.0 100.0 495 86.0 90.3 95.0 15 838 87.0 92.0 97.0 419 89.7 95.0 99.0 419 85.0 89.5 94.4 16 1,032 86.0 91.0 97.0 481 89.0 95.0 99.0 551 83.0 98.0 93.0 17 934 86.0 91.0 96.0 465 87.3 93.0 98.0 469 85.0 89.4 93.9 18 909 86.2 92.0 97.0 502 88.0 93.0 98.8 407 84.8 90.0 95.0 19 873 87.0 91.6 97.1 456 89.3 94.0 99.7 417 84.7 89.0 94.2 20 383 85.3 91.0 97.0 181 89.0 95.0 102.3 202 83.7 88.5 93.0 12–20 7,786 87.0 92.0 97.0 3,840 89.0 94.0 99.0 3,946 85.0 90.0 95.0 Note: P25, P50 and P75 represent the 25th, 50th, and 75th percentiles, respectively. The unit of blood glucose level in each percentile in the table is mg/dL Table 1. Different percentiles of blood glucose in American teenagers aged 12–20 years.
Age (years) Quantile (Model 1 *) Quantile (Model 2 †) P1
(95% CI)P25
(95% CI)P42
(95% CI)P50
(95% CI)P75
(95% CI)P85
(95% CI)P90
(95% CI)P1
(95% CI)P25
(95% CI)P42
(95% CI)P50
(95% CI)P75
(95% CI)P85
(95% CI)P90
(95% CI)12 −1.3
(−12.2, 9.6)−2.3
(−3.5, −1.1)−2.7
(−3.7, −1.7)−2.8
(−3.9, −1.7)−3.3
(−4.6, −2.1)−4
(−5.6, −2.4)−4.2
(−5.7, −2.7)−2.5
(−13.4, 8.3)−2.7
(−4.1, −1. 3)−3.1
(−4.2, −2)−3.0
(−4.2, −1.8)−3.3
(−4.5, −2.1)−4.1
(−5.8, −2.4)−4.5
(−6.3, −2.8)13 −0.2
(−5.7, 5.3)−3.8
(−5.1, −2.5)−3.5
(−4.7, −2.3)−4.0
(−5.2, −2.8)−3.5
(−5.0, −2.0)−3.6
(−5.4, −1.8)−4.1
(−6, −2.2)−5.5
(−9.7, −1.3)−4.4
(−6.0, −2.7)−3.5
(−4.9, −2.2)−3.7
(−4.9, −2.4)−3.1
(−4.5, −1.7)−3.6
(−5.4, −1.8)−4.1
(−6.5, −1.7)14 −6.0
(−17.9, 5.9)−3.2
(−4.3, −2.1)−4.1
(−5.3, −2.9)−4.7
(−5.8, −3.6)−5.0
(−6.3, −3.7)−4.8
(−6.3, −3.3)−4.1
(−6.6, −1.6)−4.5
(−13.2, 4.2)−3.3
(−4.3, −2.3)−4.4
(−5.5, −3.4)−4.7
(−6.1, −3.3)−4.4
(−5.8, −3.0)−4.7
(−6.3, −3.2)−5.0
(−7.2, −2.8)15 −4.3
(−13.4, 4.8)−4.7
(−6.3, −3.1)−5.2
(−6.6, −3.8)−5.5
(−6.7, −4.3)−4.6
(−5.8, −3.4)−5.0
(−7.2, −2.8)−5.0
(−6.9, −3.1)−7.0
(−14.9, 1.0)−4.3
(−5.9, −2.7)−5.4
(−6.7, −4.2)−5.7
(−6.8, −4.5)−4.9
(−6.2, −3.7)−5.3
(−7, −3.7)−5.5
(−8.1, −2.9)16 −8.3
(−17.6, 1.0)−6.0
(−7.8, −4.2)−5.5
(−6.8, −4.2)−5.6
(−6.8, −4.4)−6.0
(−7.2, −4.9)−6
(−7.9, −4.1)−6.5
(−8.2, −4.8)−6.8
(−15.5, 1.9)−6.4
(−7.9, −4.8)−5.1
(−6, −4.2)−5.5
(−6.7, −4.4)−6.4
(−7.4, −5.4)−5.5
(−7.5, −3.6)−5.9
(−7.2, −4.5)17 0.3
(−7.2, 7.8)−2.3
(−4.0, −0.7)−3.1
(−4.3, −1.9)−3.6
(−4.3, −2.9)−4.1
(−5.8, −2. 5)−4.6
(−6.1, −3.1)−4.8
(−6.6, −3)−1.4
(−7.7, 4.9)−3.0
(−4.3, −1.6)−3.3
(−4.6, −2)−3.3
(−4.3, −2.3)−4.0
(−5.7, −2.3)−4.7
(−6.4, −2.9)−4.9
(−7.5, −2.4)18 −6.3
(−16.1, 3.5)−3.2
(−4.9, −1.5)−3.6
(−4.7, −2.5)−3.4
(−4.5, −2.3)−3.8
(−5.2, −2.4)−4.0
(−5.9, −2.1)−4.0
(−6.3, −1.7)−6.8
(−17, 3.4)−3.8
(−5.2, −2.4)−3.2
(−4.3, −2.1)−3.2
(−4.6, −1.9)−4.1
(−5.7, −2.4)−4.4
(−5.9, −2.9)−4.0
(−6.9, −1.1)19 −6.5
(−14.8, 1.8)−4.5
(−5.8, −3.2)−4.5
(−5.8, −3.2)−5.0
(−6.5, −3.5)−5.5
(−6.8, −4.2)−4.0
(−6.2, −1.8)−5.0
(−7.5, −2.5)−3.6
(−9.1, 1.8)−4.5
(−5. 9, −3.1)−4.9
(−6, −3.8)−5.1
(−6.6, −3.7)−4.5
(−6.1, −2.9)−5.1
(−6.8, −3.4)−4.8
(−7.2, −2.3)20 2.9
(−35.3, 41.1)−5.3
(−7.2, −3.4)−7.0
(−9.8, −4.2)−6.7
(−9, −4.4)−9.0
(−12.0, −6.0)−9.0
(−11.2, −6.8)−9.3
(−13.9, −4.7)1.0
(−24.6, 26.5)−4.9
(−7.0, −2.7)−6.3
(−8.4, −4.2)−7.1
(−9, −5.1)−8.5
(−10.7, −6.3)−8.6
(−11.3, −5.9)−7.9
(−10.1, −5.8)12−20 −1.9
(−4.2, 0.4)−3.6
(−7.2, −3.1)−4.3
(−4.9, −3.8)−4.0
(−4.3, −3.7)−4.0
(−4.4, −3.6)−4.4
(−5.3, −3.5)−4.7
(−5.8, −3.6)−2.6
(−4.9, −0.3)−3.9
(−4.4, −3.5)−4.3
(−4.7, −3.9)−4.4
(−4.9, −4)−4.4
(−4.9, −4.0)−4.6
(−5.3−3.9)−5.3
(−6.1−4.5)* Model 1: Single factor analysis;
† Model 2: adjusting for BMI;
Notes: 1) The regression coefficient in this table means the change value of blood sugar when males compared with females
2) If the range of 95%CI includes 0, there is no statistical significance;If the range of 95%CI does not include 0, it is statistically significant.Table 2. Regression coefficient of gender factors of American teenagers aged 12–20 under different ages and quantiles.
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A set of curves obtained by quantile regression can provide enough information to study the complete picture of conditional distribution of dependent variables. This study found different genders had statistically significant effects on blood glucose at different percentiles, and blood glucose levels were different at different ages using percentile regression analysis. This suggests that the study of adolescent blood glucose or the preparation of adolescent blood glucose standards should be adjusted based on age and gender.
The prevalence of global juvenile diabetes has been increasing dramatically, especially during the past three or four decades, leading to a global epidemic that leaves diabetes as one of the most common and serious diseases facing humans (8). Some studies (9) showed that the fasting blood glucose level of boys was higher than that of girls (P<0.05), and there were some differences in the fasting blood glucose level of different age groups (P<0.001). Zhao et al. also pointed out that gender had a certain impact on the correlation between blood glucose and blood lipids (10), and patients of different genders should be targeted to monitor and control blood glucose levels. Hou et al. proposed in 2016 that adolescent obesity increased the risk of glycosylated hemoglobin for the diagnosis of diabetes in adulthood after adjusting for and controlling for confounders [(OR (95% CI): 5.93 (3.06–1.49)] (11). The conclusion is that obesity from adolescence to adulthood is a risk factor for adult diabetes, and controlling adolescent obesity is highly necessary for the early prevention and treatment of diabetes.
This study was subject to some limitations. The dataset had possible limitations due to the historicity and purpose of the data and also potentially due to some incompleteness in data disclosure. Furthermore, blood glucose is influenced by more factors beyond age and gender, such as race, nationality, lifestyle, genetic background, as well as sample size and quality control during data collection.
Adolescent obesity is of high clinical and public health importance for glycemic impact. Strengthening the detection of blood glucose and blood lipids in overweight and obese children and taking comprehensive intervention measures as early as possible will benefit children’s health and reduce the incidence of diabetes. Standards need to be established for adolescent blood glucose and adjusted according to different ages and genders.
Funding: Study on the current situation, change trend, nutrition and related factors of diabetes in children and adolescents, National Key R&D Program of China (2016YFC1305201); Beihang University & Capital Medical University Advanced Innovation Center for Big Data-Based Precision Medicine Plan (BHME- 201801); Study on the influencing factors of herpes zoster, Chinese Center for Disease Control and Prevention surplus project (59911917).
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