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Risk prevention of different forms of gestational diabetes mellitus based on energy metabolism prior to diagnosis

Article type: Research Article

Authors: Lu, Jiayua; 1 | Jiang, Hongqingb; 1 | Zhang, Songa | Yang, Yimina | Hao, Dongmeia | Li, Xuwena | Chen, Aiqingc | Shao, Jingc | Liu, Xiaohongc | Yang, Lina; *

Affiliations: [a] Faculty of Environment and Life Sciences, Beijing University of Technology, Intelligent Physiological Measurement and Clinical Translation, Beijing International Base for Scientific and Technological Cooperation, Beijing, China | [b] Haidian Maternal and Children Health Hospital, Beijing, China | [c] Beijing Yes Medical Devices Co. Ltd., Beijing, China

Correspondence: [*] Corresponding author: Lin Yang, Faculty of Environment and Life Sciences, Beijing International Science and Technology Cooperation Base for Intelligent Physiological Measurement and Clinical Transformation, Beijing 100124, China. Tel.: +86 13426181228; E-mail: yanglin@bjut.edu.cn.

Note: [1] Jiayu Lu and Hongqing Jiang are the co-first authors.

Keywords: Diabetes mellitus in the second trimester, diagnosis of diabetes mellitus in the third trimester, energy metabolism

DOI: 10.3233/THC-THC228027

Journal: Technology and Health Care, vol. 30, no. S1, pp. 285-292, 2022

Published: 25 February 2022
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Abstract

BACKGROUND:

Gestational diabetes mellitus (GDM) is a metabolic disease that seriously endangers the health of mothers and children. It is important to monitor GDM in real-time before diagnosis and to prevent it effectively.

OBJECTIVE:

GDM was divided into the second trimester diagnosed diabetes mellitus (GDM_24) and the third trimester diagnosed diabetes mellitus (GDM_30). The risk prediction of two types of GDM was performed in normal pregnant women at 11–13 and 16–19 weeks of pregnancy, respectively.

METHODS:

By stages, the K-W test was used to analyze the differences between basic information and energy metabolism factors, and multiple logistic regression was used to analyze the risk of energy metabolism factors and to correct the confounders with significant differences.

RESULTS:

For the GDM_24 group, each additional unit of oxygen consumption (VO2), carbon dioxide production, and resting energy expenditure (REE) increased the risk by 2.4%, 3.5%, 0.4%, and 2.1%, 2.6%, and 0.3%, respectively, at 11–13 and 16–19 weeks of pregnancy. For the GDM_30 group, each additional unit of VO2 and REE was associated with an increased risk of 2.3% and 0.3%, respectively, at 16–19 weeks of pregnancy.

CONCLUSION:

The risk of GDM_30 only appeared in pregnant women during 16–19 weeks of pregnancy, which may indicate that GDM_24 and GDM_30 have different pathogenesis.

1.Introduction

Gestational diabetes mellitus (GDM) during pregnancy is the most common metabolic disorder, it is defined as the start or during the pregnancy for the first time found that glucose intolerance [1]. According to the diagnostic criteria of GDM proposed by the International Association for the Study of Diabetes and Pregnancy (IADPSG), oral glucose tolerance test (OGTT) is carried out for all pregnant women at 24–28 weeks of pregnancy [2]. Some Chinese hospitals will carry out the second OGTT for all pregnant women after 30 weeks of pregnancy under this standard. Due to stricter screening, the incidence of OGTT has increased rapidly in recent years, reaching 22.3% in 2017 [3]. Due to higher insulin resistance in GDM, said its adverse metabolic characteristics, at the same time, also have a higher risk of adverse pregnancy outcomes [4, 5, 6], which cause serious damage to the life of the maternal and fetal health and safety. This study hypothesizes that the pathogenesis of gestational diabetes is different in different stages of diagnosis. Therefore, according to the different diagnosis times of GDM, it is divided into pregnant women diagnosed with diabetes in the second trimester and the third trimester. In the perspective of energy metabolism before the inquiry on the diagnosis of GDM pregnant women for effective risk prevention, to reduce the prevalence of GDM.

2.Materials and methods

2.1Background, population, exclusion, and inclusion criteria

From July 2018 to May 2019, a total of 168 pregnant women who underwent routine prenatal examination (file establishment) and delivered in the high-risk outpatient department of Maternal and Child Health Hospital of Haidian District, Beijing, were randomly recruited as the research subjects. All subjects were excluded by inclusion and exclusion criteria, and the study was established after obtaining informed consent. The energy metabolism of the pregnant women was measured and followed up at 11–13 weeks of pregnancy and 16–19 weeks of pregnancy from the establishment of the file, and the epidemiological parameters of the changes during pregnancy were recorded. According to the two OGTT diagnosis results, pregnant women were divided into normal pregnant women (normal group), pregnant women diagnosed with diabetes in the second trimester (GDM_24 group), and pregnant women diagnosed with diabetes in the third trimester (GDM_30 group).

Inclusion criteria: (1) single pregnancy; (2) regular menstrual cycles; (3) fetal development is consistent with the gestation period; (4) No cardiovascular disease, chronic hypertension, diabetes, anemia, and normal liver and kidney function before pregnancy; (5) thyroid function is normal, and there is no obvious acute or chronic infection and other obstetric complications.

Exclusion criteria: (1) multiple pregnancy; (2) complications of pregnancy, fetal malformation, and thyroid dysfunction during pregnancy; (3) During the measurement of energy metabolism parameters, the data were inaccurate due to objective problems such as mask leakage and shortness of breath caused by physical discomfort of pregnant women; (4) Transfer halfway.

2.2Data collection

2.2.1Physical measurement

Height and weight were recorded pre-pregnancy, 11–13 weeks, and 16–19 weeks. Body mass index (BMI) and body surface area (SA) were calculated at each stage. The body surface area was calculated by the Stevenson formula [7].

2.2.2Energy metabolic measurement

Energy metabolism was measured with indirect energy measurement instrument (BreezingTM, USA). It’s used to measure resting energy expenditure (REE), Respiratory quotient (RQ), oxygen consumption (VO2) and carbon dioxide production (VCO2). Basal metabolic rate (RMR) can be calculated by REE and SA. Carbohydrate oxidation and lipid oxidation were obtained by the Fryan formula [8].

Table 1

Basic information of pregnant women at 11–13 weeks of pregnancy

Normal groupGDM_24 groupGDM_30 group P
N522129
Age (years)    30.38± 4.13    30.95± 3.67    29.72± 2.660.615
Height (m)1.62± 0.051.63± 0.051.62± 0.040.379
Pre-pregnancy weight (kg)*54.04± 7.2859.90± 8.6956.21± 7.510.039
Pre-pregnancy BMI (kg/m2)*20.57(18.74,22.10)22.07(20.08,23.99)21.30(19.69,23.10)0.049
Weight (kg)*54.25± 7.1761.19± 9.5256.97± 7.350.014
BMI (kg/m2)*20.59± 2.3322.98± 3.6021.82± 2.680.018
GWG (kg)0.00(0.00,1.00)0.00(0.00,2.00)0.00(0.00,2.00)0.186
ΔBMI (kg/m2)0.00(0.00,0.39)0.00(0.00,0.85)0.00(0.00,0.76)0.205
History of spontaneous abortion, n yes (%)14 (26.9%)4 (19%)13 (44.8%)0.114
Family history of diabetes, n yes (%)4 (7.7%)4 (19%)  3 (10.3%)0.358

When a variable is normally distributed, data are listed as mean (± standard deviation). In cases of non-normal distribution, data are listed as median (interquartile range). Qualitative variables are expressed as n (%). BMI, body mass index; GWG, gestational weight gain; ΔBMI, gestational BMI gain. P*< 0.05 in the three groups and P< 0.05 in the normal group and GDM_24 group.

Table 2

Energy metabolism information and differences of the normal group, GDM_24 group and GDM_30 group at 11–13 weeks pregnancy

Normal groupGDM_24 groupGDM_30 group P
RQ    0.71± 0.02    0.72± 0.03    0.72± 0.030.508
VO2 (ml/min)*218.20± 32.67239.77± 33.10223.10± 22.300.047
VO2/kg (ml/kg/min)4.07± 0.683.95± 0.423.96± 0.50)0.817
VCO2 (ml/min)155.39± 23.22172.76± 27.21160.04± 16.150.056
REE (kcal/d)*    1471.60± 219.541620.28± 227.691508.07± 149.380.049
REE/kg (kcal/kg/d)27.45± 4.6126.68± 2.8526.74± 3.260.817
RMR (kcal/d)962.89± 137.06993.87± 84.49966.96± 90.000.422
RMR/kg (kcal/kg/d)18.12± 3.8716.56± 2.6417.28± 2.910.243
FOX (mg/min)107.06(90.65,115.36)113.22(100.95,121.56)103.09(91.03,116.91)0.199
FOXREE (mg)105.49(95.73,108.44)100.95(91.17,108.45)100.24(95.14,108.80)0.512
FOXRMR (mg)163.70(141.14,171.31)160.82(154.02,172.06)158.25(145.67,168.73)0.557
COX (mg/min)-0.77(-7.12,21.78)12.71(-9.59,38.83)13.18(-9.23,24.65)0.414
COXREE (mg)-0.800(-8.27,24.12)10.85(-8.37,35.70)12.59(-9.18,25.55)0.505
COXRMR (mg)-1.33(-12.26,33.12)17.09(-13.17,56.79)18.99(-14.24,40.71)0.441

RQ, respiratory quotient, REE, rest energy expenditure; VO2, oxygen consumption rate; VCO2, carbon dioxide production rate; RMR, relative metabolic rate; FOX and COX, contribution of substrate oxidation (carbohydrate and fat, respectively) to the overall energetic metabolism; FOXREE and FOXRMR, the amount of fat oxidized per 1kal REE or RMR consumed; FOXREE and FOXRMR, the amount of carbohydrate oxidized per 1kal REE or RMR consumed. P*< 0.05 in the three groups and P< 0.05 in the normal group and GDM_24 group.

The energy metabolism parameters meet the following conditions: (1) fasting for 12 hours; (2) Sit quietly for 30 minutes before measurement; (3) No vigorous exercise and no caffeine intake within 12 hours; (4) The room temperature should be kept at about 25C to ensure that the subject will not lose heart or heat.

2.2.3Statistical analysis

In this study, SPSS 20.0 software was used for statistical analysis of the data. In the basic analysis of data, independent variables are divided into quantitative parameters and qualitative parameters. For quantitative parameters, normality and homogeneity of variance were tested for each group of data. Mean ± standard deviation was calculated if the data met the standard, and median (interquartile range) was used if the data did not meet the standard. For qualitative parameters, the non-parametric chi-square test was used to analyze the different distribution of parameters in the normal group, GDM_24 group, and GDM_30 group.

Table 3

Risk analysis of energy metabolism of the normal group, GDM_24 group and GDM_30 group at 11–13 weeks pregnancy

Univariate analysisAdjusted for epidemiology
OR (95%CI) β P OR (95%CI) β P
VO2 (ml/min)GDM_24*1.024(1.006,1.043)0.0240.0101.016(0.996,1.037)0.0160.108
GDM_301.006(0.991,1.022)0.0060.4501.003(0.986,1.019)0.0030.763
VO2/kg (ml/kg/min)GDM_240.699(0.288,1.695)-0.3590.4282.022(0.630,6.484)0.7040.236
GDM_300.729(0.330,1.609)-0.3160.4341.313(0.492,3.503)0.2720.587
VCO2 (ml/min)GDM_24*1.035(1.010,1.061)0.0350.0061.025(0.997,1.053)0.0250.075
GDM_301.010(0.989,1.031)0.0100.3591.006(0.983,1.029)0.0060.616
REE (kcal/d)GDM_24*1.004(1.000,1.006)0.0040.0081.002(1.000,1.005)0.0020.100
GDM_301.001(0.999,1.003)0.0010.4331.000(0.998,1.003)0.0000.738
REE/kg (kcal/kg/d)GDM_240.950(0.833,1.085)-0.0510.4511.115(0.937,1.327)0.1090.291
GDM_300.995(0.848,1.074)-0.0460.4411.043(0.901,1.208)0.0420.570
RMR (kcal/d)GDM_241.002(0.998,1.007)0.0020.2981.003(0.998,1.008)0.0030.181
GDM_301.000(0.996,1.004)0.0000.8781.001(0.997,1.005)0.0010.579
RMR/kg (kcal/kg/d)GDM_240.864(0.733,1.019)-0.1460.0831.091(0.862,1.380)0.0870.470
GDM_300.928(0.809,1.056)-0.0740.2901.064(0.873,1.297)0.0620.539
FOX (mg/min)GDM_241.026(0.994,1.058)0.0250.1121.014(0.981,1.049)0.0140.397
GDM_301.003(0.976,1.031)0.0030.8120.998(0.970,1.027)-0.0020.879
FOXREE (mg)GDM_240.970(0.917,1.026)-0.0310.2860.975(0.918,1.036)-0.0250.418
GDM_300.980(0.932,1.031)-0.0200.4440.979(0.928,1.033)-0.0210.440
FOXRMR (mg)GDM_241.021(0.988,1.056)0.0210.2070.993(0.957,1.031)-0.0070.725
GDM_301.001(0.973,1.029)0.0010.9550.982(0.951,1.015)-0.0180.280
COX (mg/min)GDM_241.016(0.995,1.037)0.0160.1301.012(0.990,1.035)0.0120.286
GDM_301.008(0.989,1.027)0.0080.4261.008(0.988,1.028)0.0080.452
COXREE (mg)GDM_241.012(0.990,1.035)0.0120.2861.010(0.986,1.034)0.0100.418
GDM_301.008(0.988,1.028)0.0080.4421.008(0.987,1.030)0.0080.438
COXRMR (mg)GDM_241.009(0.995,1.023)0.0090.2061.007(0.992,1.022)0.0070.380
GDM_301.006(0.993,1.019)0.0160.3511.006(0.993,1.020)0.0060.379

RQ, respiratory quotient, REE, rest energy expenditure; VO2, oxygen consumption rate; VCO2, carbon dioxide production rate; RMR, relative metabolic rate; FOX and COX, contribution of substrate oxidation (carbohydrate and fat, respectively) to the overall energetic metabolism; FOXREE and FOXRMR, the amount of fat oxidized per 1kal REE or RMR consumed; FOXREE and FOXRMR, the amount of carbohydrate oxidized per 1kal REE or RMR consumed. Epidemiology included BMI before pregnancy and BMI at 11 to 13 weeks of pregnancy. P*< 0.05 in the univariate analysis.

In the exploration of each stage, the differences of basic information and energy metabolism between the three groups of pregnant women were first analyzed by Kruskal-Wallis (K-W) test. By multiple logistic regression analysis GDM_24 before the diagnosis of GDM group and GDM_30 group compared with the normal group in the aspect of energy metabolism of risks, if there are mixed in the underlying information factor (P< 0.05) will be in the risk analysis on the correction to ensure GDM_24 group and GDM_30 energy metabolism parameters have the relatively independent risk for the normal group.

Table 4

Basic information of pregnant women at 16-19 weeks of pregnancy

Normal groupGDM_24 groupGDM_30 group P
N442626
Age (years)31.00(28.00,34.00)29.50(27.00,32.25)28.00(27.75,31.00)0.143
Height (m)1.62± 0.0.51.64± 0.051.62± 0.040.531
Pre-pregnancy weight (kg)*     54.30± 6.01     58.69± 8.60     57.37± 8.430.094
Pre-pregnancy BMI (kg/m2)*20.65± 2.0621.93± 3.0521.80± 3.100.217
Weight (kg)*56.75± 5.9261.57± 9.6460.88± 9.050.085
BMI (kg/m2)*20.59± 2.3322.98± 3.6021.82± 2.680.119
GWG (kg)2.00(1.25,1.00)2.75(1.00,4.00)3.25(1.08,5.63)0.487
ΔBMI (kg/m2)21.75(20.13,22.89)22.28(20.63,24.71)21.98(20.61,25.64)0.476
History of spontaneous abortion, n yes (%)15(34.1%)7(26.9%)11(42.3%)0.508
Family history of diabetes, n yes (%)3(6.8%)4(15.4%)4(15.4%)0.426

When a variable is normally distributed, data are listed as mean (± standard deviation). In cases of non-normal distribution, data are listed as median (interquartile range). Qualitative variables are expressed as n (%). BMI, body mass index; GWG, gestational weight gain; ΔBMI, gestational BMI gain.

Table 5

Energy metabolism information and differences of the normal group, GDM_24 group and GDM_30 group at 16-19 weeks pregnancy

Normal groupGDM_24 groupGDM_30 group P
RQ0.71(0.69,0.72)0.70(0.68,0.73)0.70(0.68,0.73)0.991
VO2 (ml/min)*222.57± 24.76237.95± 31.99236.69± 22.070.023
VO2/kg (ml/kg/min)3.95(3.67,4.16)3.82(3.50,4.35)3.78(3.47,4.52)0.930
VCO2 (ml/min)156.08± 16.65167.12± 22.27165.68± 17.630.043
REE (kcal/d)*1497.23± 164.571598.50± 219.511591.58± 149.670.022
REE/kg (kcal/kg/d)26.57(24.64,27.87)25.68(34.48,29.42)25.24(23.28,30.6)0.899
RMR (kcal/d)958.40± 90.57987.12± 133.88987.49± 91.300.538
RMR/kg (kcal/kg/d)17.07± 2.5016.42± 4.0116.64± 3.340.398
FOX (mg/min)111.03± 16.34118.28± 24.02118.55± 16.340.152
FOXREE (mg)106.56± 7.81106.35± 13.90107.35± 12.430.996
FOXRMR (mg)166.46± 15.22173.58± 27.16173.34± 22.890.534
COX (mg/min)-4.26± 21.26-3.41± 40.55-5.85± 34.600.998
COXREE (mg)-3.54± 19.91-2.33± 34.53-5.52± 31.670.997
COXRMR (mg)-5.43± 30.8-3.76± 58.30-8.61± 50.060.993

RQ, respiratory quotient, REE, rest energy expenditure; VO2, oxygen consumption rate; VCO2, carbon dioxide production rate; RMR, relative metabolic rate; FOX and COX, contribution of substrate oxidation (carbohydrate and fat, respectively) to the overall energetic metabolism; FOXREE and FOXRMR, the amount of fat oxidized per 1kal REE or RMR consumed; FOXREE and FOXRMR, the amount of carbohydrate oxidized per 1kal REE or RMR consumed. P*< 0.05 in the three groups and P< 0.05 in the normal group and GDM_24 group. P**< 0.05 in the three groups and P< 0.05 in the normal group and GDM_30 group.

3.Results

The basic information of 102 subjects at 11–13 weeks pregnancy is shown in Table 1, including 52 in the normal group, 21 in the GDM_24 group, and 19 in the GDM_30 group. According to the analysis, result shows that three sets of pre-pregnancy weight and BMI, 11–13 weeks of pregnancy weight and BMI have a significant difference, comparing two found in the normal group and GDM_24 pre-pregnancy weight (P= 0.011) and BMI (P= 0.019), 11–13 weeks of pregnancy weight (P= 0.004) and BMI (P= 0.008) are different. After correction by Bonferroni method, pregnancy weight (P= 0.034), weight (P= 0.011) and BMI (P= 0.023) at 11–13 weeks of pregnancy still have difference. In consideration of the practical significance and collinearity that BMI was more accurate than body weight in the clinical analysis, BMI before pregnancy and BMI at 11–13 weeks of pregnancy with significant differences between the three groups were selected and corrected in the subsequent risk analysis.

The energy metabolism information and differences of the normal group, GDM_24 group, and GDM_30 group at 11–13 weeks of pregnancy are shown in Table 2. According to the results of statistical analysis, there were significant differences in VO2 and REE among the three groups. After pair comparison, it was found that there were differences in VO2 (P= 0.013) and REE (P= 0.014) between the normal group and the GDM_24 group. After correction by the Bonferroni method, the differences in VO2 (P= 0.040) and REE (P= 0.042) were still significant.

The energy metabolism risk analysis of the normal group, GDM_24 group, and GDM_30 group at 11–13 weeks of pregnancy is shown in Table 3. The VO2, VCO2, and REE of the GDM_24 group were significantly at risk compared with the normal group. An increase of one unit of VO2, VCO2, and REE increased the risk of GDM_24 in normal pregnant women by 2.4%, 3.5%, and 0.4%, respectively, but the risk was no longer significant after adjustment for basic information.

The basic information of 96 subjects at 16–19 weeks of pregnancy is shown in Table 4, including 52 in the normal group, 21 in the GDM_24 group, and 19 in the GDM_30 group. According to the result, in 16–19 weeks of gestation, there is no significant difference between the three, so will not risk analysis.

Table 6

Risk analysis of energy metabolism of the normal group, GDM_24 group and GDM_30 group at 16–19 weeks pregnancy

Univariate analysis
OR (95%CI) β P
VO2 (ml/min)GDM_24*1.023(1.003,1.044)0.0230.025
GDM_30*1.021(1.001,1.041)0.0210.038
VO2/kg (ml/kg/min)GDM_240.976(0.393,2.423)-0.0240.959
GDM_301.020(0.412,2.526)0.0200.966
VCO2 (ml/min)GDM_24*1.034(1.005,1.063)0.0330.021
GDM_30*1.026(1.001,1.058)0.0290.042
REE (kcal/d)GDM_24*1.003(1.000,1.006)0.0030.028
GDM_30*1.003(1.000,1.006)0.0030.040
REE/kg (kcal/kg/d)GDM_240.992(0.865,1.137)-0.0080.907
GDM_301.002(0.874,1.148)0.0020.979
RMR (kcal/d)GDM_241.002(0.997,1.007)0.0020.361
GDM_301.003(0.998,1.008)0.0030.258
RMR/kg (kcal/kg/d)GDM_240.936(0.799, 1.095)-0.0660.409
GDM_300.957(0.820,1.117)-0.0440.581
FOX (mg/min)GDM_241.022(0.995,1.050)0.0220.118
GDM_301.023(0.995,1.051)0.0220.105
FOXREE (mg)GDM_240.998(0.954,1.044)-0.0020.937
GDM_301.007(0.963,1.052)0.0070.770
FOXRMR (mg)GDM_241.017(0.993,1.041)0.0170.168
GDM_301.016(0.992,1.041)0.0160.181
COX (mg/min)GDM_241.001(0.985,1.017)0.0010.911
GDM_300.998(0.983,1.014)-0.0020.835
COXREE (mg)GDM_241.002(0.984,1.020)0.0020.858
GDM_300.997(0.980,1.015)-0.0030.771
COXRMR (mg)GDM_241.001(0.990,1.012)0.0010.878
GDM_300.998(0.988,1.009)-0.0020.772

RQ, respiratory quotient, REE, rest energy expenditure; VO2, oxygen consumption rate; VCO2, carbon dioxide production rate; RMR, relative metabolic rate; FOX and COX, contribution of substrate oxidation (carbohydrate and fat, respectively) to the overall energetic metabolism; FOXREE and FOXRMR, the amount of fat oxidized per 1kal REE or RMR consumed; FOXREE and FOXRMR, the amount of carbohydrate oxidized per 1kal REE or RMR consumed. Epidemiology included BMI before pregnancy and BMI at 11 to 13 weeks of pregnancy. P*< 0.05 in the univariate analysis.

The energy metabolism information and differences of the normal group, GDM_24 group, and GDM_30 group at 16–19 weeks of pregnancy are shown in Table 5. There were significant differences in VO2, VCO2, and REE among the three groups. After pair comparison, it was found that there were differences in VO2 (P= 0.024), VCO2 (P= 0.027) and REE (P= 0.019) between the normal group and the GDM_24 group, and there were differences in VO2 (P= 0.022), and REE (P= 0.025) between the normal group and the GDM_30 group. However, the differences were no longer significant after correction by the Bonferroni method.

The energy metabolism risk analysis of the normal group, GDM_24 group, and GDM_30 group at 16–19 weeks of pregnancy is shown in Table 6. VO2, VCO2, and REE in the three groups were significantly riskier than those in the normal group. Each additional unit of VO2, VCO2, and REE increased the risk of GDM_24 in normal pregnant women by 2.3%, 3.4%, and 0.3%, respectively. Normal pregnant women had an increased risk of GDM_30 by 2.1%, 2.6%, and 0.3%, respectively.

4.Discussion and conclusion

The increased energy demands of the growing fetus are explained by changes in metabolism that occur during pregnancy. From the metabolism point of view, the pregnant woman anabolism and catabolism by two clearly defined in different periods. The first half of pregnancy is characterized by an anabolic state, storage of energy and nutrients. In this state, there is a decrease in net fat storage and endogenous fat oxidation in the mother [9, 10]. This study found that the risk of GDM 30 was seen at 16–19 weeks of pregnancy compared with 11–13 weeks of pregnancy. This may be due to the different pathogenesis of GDM_24 and GDM_30. So, it makes sense to differentiate GDM by diagnosis time. At each pregnancy stage, there are different differences in energy metabolism between the normal group and the sick group, which may be related to the metabolic regulation of the normal and sick pregnant women. It may be meaningful to add energy metabolism parameters to the related studies of GDM. Later, more data will be added to explore the results in detail.

Acknowledgments

This research was funded by the National Key R&D Program of China (2019YFC0119700), Bill & Melinda Gates Foundation (OPP1148910), and Beijing Science and Technology Project (Z161100000116005), Intelligent Physiological Measurement and Clinical Translation, Beijing International Base for Scientific and Technological Cooperation.

Conflict of interest

None to report.

References

[1] 

American Diabetes Association, Diagnosis and classification of diabetes mellitus. Journal of Diabetes Care. (2013) , 36: (Suppl 1): S67-S74.

[2] 

Metzger BE, Gabbe SG, Persson B, et al. International association of diabetes and pregnancy study groups recommendations on the diagnosis and classification of hyperglycemia in pregnancy. Diabetes Care. (2010) ; 33: (3): 676-682.

[3] 

Akgöl E, Abuşoğlu S, Deniz Gün Faik et al. Prevalence of gestational diabetes mellitus according to the different criterias. Turk J Obstet Gynecol, (2017) ; 14: (1): 18-22.

[4] 

Li MF, Ma L, Yu TP, et al. Adverse maternal and neonatal outcomes in pregnant women with abnormal glucose metabolism. Diabetes Research and Clinical Practice. (2020) ; 161: : 108-85.

[5] 

Barbour LA. Metabolic culprits in obese pregnancies and gestational diabetes mellitus: big babies, big twists. Diabetes Care. (2019) ; 42: (5): 718-726.

[6] 

Benhalima K, Crombrugge PV, Moyson C, et al. Characteristics and pregnancy outcomes across gestational diabetes mellitus subtypes based on insulin resistance. Diabetologia. (2019) ; 62: (11): 2118-2128.

[7] 

Stevenson PH. Calculation of the body2surface area of Chinese. Chin J Physiol, Report Series. (1928) ; 1: : 13-24.

[8] 

Frayn KN. Calculation of substrate oxidation rates in vivo from gaseous exchange. J Appl Physiol Respir Environ Exerc Physiol. (1983) ; 55: (2): 628-34.

[9] 

Butte NF. Carbohydrate and lipid metabolism in pregnancy: normal compared with gestational diabetes mellitus. The American Journal of Clinical Nutrition. (2000) ; 71: (5): 1256S-1261S.

[10] 

Flavien D, Giza SA, Tianna K, et al. Altered maternal and placental lipid metabolism and fetal fat development in obesity: Current knowledge and advances in non-invasive assessment. Placenta. (2018) ; 69: : 118-124.

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