7:12 1464–1471J Wang et al. GDM and offspring’s obesity

RESEARCH

Maternal gestational diabetes and different 
indicators of childhood obesity: a large study
Jing Wang1,2, Leishen Wang1, Huikun Liu1, Shuang Zhang1, Junhong Leng1, Weiqin Li1, Tao Zhang1, Nan Li1, 
Wei Li1, Andrea A Baccarelli3, Lifang Hou4 and Gang Hu2

1Tianjin Women’s and Children’s Health Center, Tianjin, China
2Chronic Disease Epidemiology Laboratory, Pennington Biomedical Research Center, Baton Rouge, Louisiana, USA
3Department of Environmental Health Sciences, Columbia University Mailman School of Public Health, New York, New York, USA
4Department of Preventive Medicine, Feinberg School of Medicine, Northwestern University, Chicago, Illinois, USA

Correspondence should be addressed to G Hu: gang.hu@pbrc.edu

Abstract

Previous studies found conflicting results about the associations between the exposure 

to hyperglycemia in utero and the later risks of childhood overweight and obesity. The 

aim of the present study is to compare the children’s BMI growth between offspring 

exposed to maternal gestational diabetes mellitus (GDM) and those not exposed 

and assess the associations between maternal GDM and their offspring’s overweight 

and obesity risk. We performed a large observational study in 1156 women and their 

offspring (578 GDM and 578 non-GDM mother–child pairs, matched by their offspring’s 

gender and age). Maternal GDM was diagnosed according to the World Health 

Organization criteria. Childhood height, weight, waist circumference, body fat and 

skinfold were measured using standardized methods. After adjustment for maternal 

and children’s characteristics, children born to mothers with GDM during pregnancy 

had higher mean values of Z scores for BMI-for-age, Z scores for weight-for-age, waist 

circumferences, body fat, subscapular skinfold and suprailiac skinfold, in comparison 

with their counterparts born to mothers with normal glucose during pregnancy (all P 

values <0.05). Moreover, maternal GDM was associated with a higher risk of childhood 

overweight and obesity with multivariate-adjusted odds ratios of 1.42 (95% confidence 

interval (CI): 1.02–1.97) and 1.18 (95% CI: 1.11–1.24), respectively, compared with the 

children of mothers without GDM during pregnancy. This study demonstrates that 

maternal GDM is an independent risk factor of childhood overweight and obesity and is 

associated with higher BMI in the offspring.

Introduction

The worldwide rise in over-nutrition, sedentary life and 
obesity has resulted in a steep increase in the number of 
women who develop gestational diabetes mellitus (GDM) 
during pregnancy (1). Nearly 7% of pregnancies in the 
United States were affected by GDM, which is defined 
as any degree of glucose intolerance with onset or first 
recognition during pregnancy (2). The global prevalence 
of GDM ranged from 5.8 to 12.9% (3). Women with prior 

GDM are known to increase the risk of hypertensive 
disorders of pregnancy, the need for cesarean delivery, the 
possibility of fetal macrosomia (1) and the long-term risk 
of developing type 2 diabetes in later life, compared with 
non-GDM women (4).

With respect to the long-term effects on the growth 
and development of children with GDM mothers, 
there are conflicting findings in previous studies. In the 

-18-0449

Key Words

 f gestational diabetes 
mellitus

 f childhood obesity

 f maternal glucose levels

 f childhood growth

 f early childhood risk factors

Endocrine Connections
(2018) 7, 1464–1471

ID: 18-0449

7 12

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J Wang et al. GDM and offspring’s obesity 14657:12

Northwestern Diabetes in Pregnancy Study in Chicago, 
diabetes during pregnancy (GDM and preexistent  
diabetes) was positively associated with the offspring’s 
BMI at birth and after 5 years old (5, 6). The offspring 
of Pima Indian women with preexistent diabetes 
and GDM had much higher rates of obesity at age 
5–19  years, compared with their counterparts born to 
prediabetic and nondiabetic women (7, 8). However, 
these differences may be due to the high type 2 diabetes 
(T2D) risk in the specialized population from the Pima 
Indians and a specialized pregnancy clinical population 
in Chicago (9). Regarding to the general population, 
two recent studies from the Hyperglycemia and Adverse 
Pregnancy Outcome study (HAPO) (10) and Kaiser 
Permanente Northwest and Hawaii (11) presented that 
maternal hyperglycemia during pregnancy increased 
the offspring’s risk of overweight and obesity among 
7-year-old girls and during the first decade among 
normal birth weight infants, respectively. However, 
other studies did not find a clear association between 
maternal GDM and obesity in offspring of more than 
5 years old (12, 13, 14). Thus, more studies are expected 
to provide evidence and illustrate the impact of GDM 
on children’s growth and development. The present 
study aims to compare different indicators of childhood 
obesity between offspring exposed to maternal GDM and 
those not exposed and assess the associations between 
maternal GDM and their offspring’s overweight and 
obesity risk.

Methods

GDM screening process

We used a two-step approach in the GDM diagnosis in 
Tianjin, China. We first invited all pregnant women (at 
their 26–30 gestational weeks) to participate in a 1-h oral 
glucose tolerance test (OGTT) with 50 g glucose load in 
their community health centers. Then, those whose 
glucose reading ≥7.8 mmol/L were referred to the Tianjin 
Women’s and Children’s Health Center to undergo a 2-h 
OGTT with 75 g glucose load. If the pregnant women met 
the 1999 World Health Organization (WHO)’s criteria 
of diabetes (fasting glucose ≥7 mmol/L or 2-h glucose 
≥11.1 mmol/L) or impaired glucose tolerance (IGT) (2-h 
glucose ≥7.8 mmol/L and <11.1 mmol/L), they would be 
diagnosed as GDM (15). From 1999, all pregnant women 
living in the six urban districts of Tianjin have been 
screened for GDM (16).

Study population

We conducted a large study in 578 GDM mother–child  
pairs and their 578 counterparts with non-GDM 
mothers, matched by children’s genders and ages. 
The GDM mothers came from the Tianjin Gestational 
Diabetes Mellitus Prevention Program (17), a randomized 
controlled trial conducted among GDM women living in 
the six urban districts in Tianjin. A total of 4644 eligible 
women, who were diagnosed with GDM between 2005 
and 2009, were invited to join the program by mailing. 
During August 2009 to July 2011, a total of 1263 
GDM women at their postpartum 1–5  years finished 
the baseline survey. Of them, 83 were diagnosed as 
having type 2 diabetes, and the rest 1180 GDM women 
then attended the Tianjin Gestational Diabetes Mellitus 
Prevention Program. The recruitment, inclusion and 
exclusion criteria have been described in detail elsewhere 
(17). We randomly chose 578 GDM mother–child pairs 
who finished the year 1 or 2 follow-up survey and also 
stored blood samples. Simultaneously, we also enrolled 
578 non-GDM mother–child pairs, with age and sex 
frequency matched to the 578 children of GDM mothers 
(Fig. 1). We collected written informed consents from all 

Tianjin GDM Screening
76,325 pregnant women (26-30wk) in Tianjin, China (2005 to 2009)

4,644 women with GDM 71,681 women without GDM

1,688 GDM women were willing 
to make an appointment

2,956 were excluded

1,303 (28.1%) eligible finished 
baseline survey

385 were excluded

40 were excluded

1,263 (27.2%) eligible finished baseline survey 
(completed a self-reported questionnaire and 
underwent a physical examination.)

Follow-up Surveys

Case Group

578 GDM mother-child pairs were randomly 
chosen from participants who finished the 
Year 1 or 2 follow-up visit and also stored 
blood samples

Control Group

578 non-GDM mother-child pairs 
were enrolled, matched by children’s
gender and age

Figure 1
Flow chart.

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J Wang et al. GDM and offspring’s obesity 14667:12

participants, and this study was approved by the Human 
Subjects Committee of Tianjin Women’s and Children’s 
Health Center.

Mothers’ information was collected by a self-
administered questionnaire, including socio-demographic 
characteristics, such as age, marital status, education (<13, 
13–16, and ≥16 years), family income (<5000, 5000–8000 
and ≥8000 yuan/month), and occupation; pregnancy 
outcomes (prepregnancy weight, weight gain during 
pregnancy, gestational age and the number of births in 
the index pregnancy) and lifestyle in the past year, such as 
smoking status (non-smokers, former smokers and current 
smokers), passive smoking, drinking status, sitting time 
and leisure-time physical activity (0, 1–29, and ≥30 min/
day). Children’s information was collected by another 
questionnaire completed by their mothers, including 
children’s general information, such as gender, birth date, 
age, birth weight, birth length, the mode of infant feeding 
within the first 6 months (exclusive formula, mixed breast 
and formula or exclusive breast) and lactation duration; 
history of diseases and medication; dietary habits (using 
a validated food frequency questionnaire (FFQ) (18)) and 
routine activities (indoor and outdoor activities, screening 
watching time and sleep duration).

All mother–child pairs underwent a physical 
examination. Using the standardized protocol, all 
participants’ height and weight were measured in light 
indoor clothing and without shoes by trained research 
doctors. Moreover, the children’s physical examination 
also included the measurement of body fat, waist 
circumference, triceps skinfold, subscapular skinfold and 
suprailiac skinfold. Body weight was measured with a beam 
balance scale to the nearest 0.1 kg; height was measured by 
a stadiometer to the nearest 0.1 cm. Waist circumference 
was measured midway between the 10th rib and the 
top of the iliac crest to the nearest 0.1 cm. Body fat was 
measured by a body composition analyzer (InBody J20) 
to the nearest 0.1%. Triceps skinfold, subscapular skinfold 
and suprailiac skinfold were measured by skinfold caliper 
to the nearest 0.5 cm.

Calculation of BMI

BMI was obtained by dividing weight in kilograms by the 
square of height in meters. All mothers’ prepregnancy 
BMI calculation used their self-reported prepregnancy 
weight and their height. According to the Chinese BMI 
cut-offs (19), prepregnancy BMI was categorized as <24, 
24–27.9 and ≥28 kg/m2. Children’s BMI calculation used 
their body weight and height examined in the study visit.

Children’s Z scores and overweight/obesity

Children’s Z scores (including Z scores for height-for-
age (Z-height), Z scores for weight-for-age (Z-weight), 
Z scores for BMI-for-age (Z-BMI)), calculated based on 
the protocol from the WHO, are gender-independent 
classification systems, representing equivalent height/
weight/BMI-for-age percentile based on the WHO growth 
reference (20).

Children’s overweight and obesity was defined 
by children’s Z-BMI: we defined normal weight as a 
BMI less than the 85th percentiles for age and gender 
based on the WHO growth reference (Z-score <1.035), 
overweight as a BMI above the 85th percentiles (Z-score 
≥1.035), and obesity as a BMI above the 90th percentiles 
(Z-score ≥1.645) (21). Central obesity was defined as waist 
circumference ≥the 90th percentiles for age- and gender-
specific distribution, according to the National Health and 
Nutrition Examination Survey (NHANES) III (22). High 
body fat was defined as body fat ≥the 90th percentiles of 
the NHANES IV (23) (since the references were available 
from 5  years old, we defined high body fat only among 
the children over 5 years old).

Statistical analyses

We used t-test and chi-square test to compare the general 
characteristics (continuous and categorical variables) 
of both mothers and children according to maternal 
GDM status. General linear models were applied to 
assess the differences in children’s Z-BMI, Z-weight, 
Z-height, body fat, waist circumference, triceps 
skinfold, subscapular skinfold and suprailiac skinfold 
according to maternal GDM status. Cox proportional 
hazards models were used to estimate hazards ratios 
for children’s overweight, obesity, central obesity and 
high body fat according to maternal GDM status. The 
analyses included three multivariable adjusted models: 
Model 1 adjusted for maternal age, gestational age 
and education; Model 2 adjusted for the variables in 
Model 1 and also for maternal smoking status, passive 
smoking status, alcohol drinking status, as well as 
children’s feeding method during the first 6  months 
after birth, children’s vegetables and fruits intake 
frequency, outdoor time, screen watching time and 
sleeping duration; Model 3 adjusted for the variables 
in Model 2 and also for maternal prepregnancy BMI 
and maternal gestational weight gain. All analyses were 
performed using IBM SPSS Statistics 24.0 (IBM SPSS) 
with a statistical significance at 0.05.

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Table 1 Maternal and children’s characteristics according to maternal gestational diabetes status.

Maternal and children’s characteristics Non-GDM GDM P value

Number of subjects 578 578
Maternal characteristics
 Age at delivery, years 29.7 ± 2.91 30.5 ± 3.58 <0.001
 Gestational age at delivery, weeks 39.1 ± 1.52 39.1 ± 1.34 0.54
 Prepregnancy BMI, kg/m2 21.4 ± 2.94 22.9 ± 3.06 <0.001
 Prepregnancy BMI categories, % <0.001
  <24.0 85.6 68.0
  24.0–27.9 10.7 25.8
  ≥28 3.6 6.2
 Gestational weight gain, kg 18.2 ± 6.70 16.6 ± 5.85 <0.001
 Education, % <0.001
  ≤12 years 10.7 20.1
  13–15 years 75.6 72.8
  ≥16 years 13.7 7.1
 Current smokers, % 3.8 1.7 0.046
 Passive smokers, % 54.8 52.8 0.48
 Alcohol drinkers, % 31.7 21.6 <0.001
Child characteristics
 Boy, % 52.2 52.2 1.00
 Age, months 70.4 ± 14.7 70.4 ± 14.9 0.98
 Mode of infant feeding, % 0.45
  Exclusive breastfeeding 40.9 44.3
  Mixed breast and formula 44.5 42.9
  Exclusive formula feeding 14.6 12.8
 Vegetables intake frequency, % <0.001
  ≤ 1 time/day 13.1 3.3
  2 times/day 81.3 93.6
  ≥ 3 times/day 5.5 3.1
 Fruits intake frequency, % 0.60
  <1 time/day 3.1 4.2
  1 time/day 38.4 37.0
  >1 time/day 58.5 58.8
 Outdoor activity, h/day 2.12 ± 0.86 2.20 ± 0.91 0.10
 Screen watching time, h/day 0.95 ± 0.76 1.17 ± 0.83 <0.001
 Sleeping duration, % 0.019
  ≤8 h/day 11.1 14.5
  9–10 h/day 67.3 69.6
  ≥11 h/day 21.6 15.9
 Birth BMI, kg/m2 13.3 13.7 <0.001
 Height, cm 118 ± 9.18 118 ± 9.75 0.50
 Z-score for height-for-age 0.69 ± 1.01 0.75 ± 1.01 0.25
 Weight, kg 22.1 ± 5.99 23.1 ± 6.91 0.011
 Z-score for weight-for-age 0.45 ± 1.20 0.70 ± 1.26 0.001
 Body mass index, kg/m2 15.7 ± 2.30 16.2 ± 2.59 <0.001
 Z-score for body mass index-for-age 0.02 ± 1.28 0.34 ± 1.35 <0.001
 Waist circumference, cm 54.7 ± 6.09 56.3 ± 6.77 <0.001
 Body fat, % 19.1 ± 7.42 20.7 ± 7.97 <0.001
 Triceps skinfold, mm 12.8 ± 5.36 12.7 ± 5.81 0.69
 Subscapular skinfold, mm 7.22 ± 3.82 8.10 ± 4.42 <0.001
 Suprailiac skinfold, mm 9.67 ± 5.96 11.6 ± 6.99 <0.001
 Overweight (Z-BMI ≥1.035), % 18.5 27.0 0.001
 Obesity (Z-BMI ≥1.645), % 10.6 17.0 0.002
 Central obesity, % 5.7 8.8 0.04
 High body fat, % 19.9 28.6 0.001

Values are means ± s.d. unless otherwise specified.
GDM, gestational diabetes mellitus.

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Results

Table  1 presents maternal and children’s characteristics 
according to maternal GDM status. Compared with non-
GDM mothers, GDM mothers were older at delivery, 
more overweight and obese before pregnancy, less current 
smokers and less alcohol drinkers and had less gestational 
weight gain and less education level. Compared with 
children born to non-GDM mothers, children born 
to GDM mothers had higher birth BMI, longer screen 
watching time but shorter sleeping duration.

After adjustment for maternal age, gestational age, 
education, current smoking status, passive smoking 
status, alcohol drinking status and children’s feeding 
method, children’s vegetables and fruits intake frequency, 
outdoor time, screen watching time and sleeping duration 
(multivariable-adjusted Model 2), children born to GDM 
mothers had higher mean values of Z-BMI (0.33 vs 0.03), 
Z-weight (0.70 vs 0.45), body fat (20.7 vs 19.1%), waist 
circumference (56.3 vs 54.7 cm), subscapular skinfold (8.08 
vs 7.24 mm) and suprailiac skinfold (11.6 vs 9.68 mm) 
than children born to non-GDM mothers (Table  2). 

After additional adjustment for maternal prepregnancy 
BMI and gestational weight gain (multivariable-adjusted 
Model 3), these differences still remained significant.

The multivariable-adjusted (Model 2) odds ratios 
among children of GDM mothers compared with children 
of non-GDM mothers were 1.55 (95% confidence interval 
(CI) 1.14–2.10) for overweight, 1.65 (95% CI 1.14–2.40) 
for obesity and 1.53 (95% 1.11–2.12) for high body fat, 
respectively (Table 3). When further adjusting for maternal 
prepregnancy BMI and gestational weight gain, these 
associations were somewhat attenuated but remained 
significant. There was no significant association between 
GDM status and children’s central obesity.

Discussion

In this large study, we found that children born to GDM 
mothers had higher Z-weight, Z-BMI, waist circumference, 
body fat, subscapular skinfold and suprailiac skinfold  
and were associated with increased risks of overweight, 
obesity and high body fat compared with children born to 

Table 2 Comparison of children’s measurements according to maternal gestational diabetes status.

Children’s measurements Multivariable-adjusted models Non-GDM (n = 578) GDM (n = 578) P value

Z-score of BMI-for-age Model 1 0.02 (0.06) 0.33 (0.06) <0.001
Model 2 0.03 (0.06) 0.33 (0.06) <0.001
Model 3 0.07 (0.05) 0.29 (0.05) 0.006

Z-score of weight-for-age Model 1 0.45 (0.05) 0.70 (0.05) 0.001
Model 2 0.45 (0.05) 0.70 (0.05) 0.001
Model 3 0.48 (0.05) 0.67 (0.05) 0.009

Z-score of height-for-age Model 1 0.68 (0.04) 0.76 (0.04) 0.18
Model 2 0.68 (0.04) 0.76 (0.04) 0.21
Model 3 0.68 (0.04) 0.76 (0.04) 0.17

Body fat, % Model 1 19.1 (0.32) 20.7 (0.32) 0.001
Model 2 19.1 (0.32) 20.7 (0.32) <0.001
Model 3 19.3 (0.32) 20.5 (0.32) 0.008

Waist circumference, cm Model 1 54.7 (0.24) 56.3 (0.24) <0.001
Model 2 54.7 (0.25) 56.3 (0.25) <0.001
Model 3 54.9 (0.24) 56.1 (0.24) <0.001

Triceps skinfold, mm Model 1 12.9 (0.22) 12.7 (0.22) 0.59
Model 2 12.8 (0.22) 12.7 (0.22) 0.70
Model 3 12.9 (0.22) 12.6 (0.22) 0.29

Subscapular skinfold, mm Model 1 7.26 (0.17) 8.07 (0.17) 0.001
Model 2 7.24 (0.17) 8.08 (0.17) 0.001
Model 3 7.34 (0.17) 7.99 (0.17) 0.007

Suprailiac skinfold, mm Model 1 9.70 (0.26) 11.6 (0.26) <0.001
Model 2 9.68 (0.26) 11.6 (0.26) <0.001
Model 3 9.87 (0.26) 11.4 (0.26) <0.001

Data are means (s.e.). Model 1 adjusted for maternal age, gestational age, education, and children’s age; for Z-score of BMI-for-age, Z-score of weight-
for-age and Z-score of height-for-age, adjusted for maternal age, gestational age and education only. Model 2 adjusted for covariates in Model 1 and 
also for maternal smoking status, passive smoking status, alcohol drinking status, as well as children’s feeding status, vegetables and fruits intake 
frequency, outdoor time, screening watching time and sleeping duration. Model 3 adjusted for in Model 2 and also for maternal prepregnancy BMI and 
weight gain during pregnancy.
BMI, body mass index; GDM, gestational diabetes mellitus.

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non-GDM mothers. These associations were independent 
of maternal prepregnancy BMI, gestational weight gain 
and other related maternal and infant factors.

As known in the previous studies, in utero exposure 
to GDM is a risk factor of macrosomia and large for 
gestational age at birth and developing obesity and type 
2 diabetes during adolescence or young adulthood in 
the offspring (24). However, debates on the associations 
between maternal GDM status and childhood overweight 
and obesity risks have never stopped. Studies of 
Northwestern Diabetes in Pregnancy Study in Chicago 
(5, 6), Pima Indian (8), HAPO in Hongkong (10) and 
Kaiser Permanente centers (11) claimed to find a positive 
association between maternal GDM and childhood 
obesity, while other studies including one HAPO study 
in UK argued that little association existed (12, 13, 14, 
25, 26). Discrepancies in these findings may be due to 
small sample sizes of GDM-exposed children or research 
conducted among high type 2 diabetes (T2D) risk 
populations (Pima Indians and Chicago study (9)). The 
present study included a large sample size of GDM and 
non-GDM mother–child pairs and had enough power to 
compare the differences of offspring’s growth between 
GDM and non-GDM exposure. Also, we controlled 
various covariates in the multivariable-adjusted analysis, 
such as maternal social-economic characteristics, lifestyle 
factors, infant feeding status, children’s diet and lifestyle, 
maternal weight gain during pregnancy and prepregnancy 
BMI, which were identified as important confounders of 
this association (27).

Evidence from human and animal research indicates 
that the environment in utero plays an important role 
on the growth of infants. The possible explanation 
underlying the findings could be ‘metabolic imprinting’, 
which is known as ‘the process by which a stimulus or 

insult occurring during a critical period of development 
has a long-term effect on the physiologic and metabolic 
responses of the offspring’ (28). It represented a 
determinant of an over-nutritional status of fetus and 
further leading to offspring’s diseases later in life (29). 
One of the underlying mechanisms may be the delivery 
of excessive nutrients from mothers to the fetus; maternal 
glucose but not insulin can cross the placenta which 
in turn influences the development of the fetus in utero 
and even long-term health (30). Previous animal models 
provided strong evidence that maternal diabetes increased 
the risks of offspring’s obesity and diabetes: GDM affected 
offspring’s obesity and insulin resistance in the livers, 
and further was associated with susceptibility to type 
2 diabetes mellitus (31, 32). Increasing obesity among 
children was also associated with lifestyle changes, such 
as over-nutrition and more sedentary time. In this study, 
we also found that children born to GDM mothers had 
longer screen watching time but shorter sleeping duration 
than their counterparts. In the analysis, we controlled 
these diet and lifestyle variables, but they may affect 
children’s overweight and obesity in the real world.

We tried to assess children’s obesity in a more detailed 
way than previous studies, so we included not only BMI, 
weight, height, overweight and obesity, but also body fat, 
waist circumference, triceps skinfold, subscapular skinfold 
and suprailiac skinfold as evaluating indicator of obesity. 
Moreover, the data were based on the Asian population, 
who are of increasing burden of childhood obesity and 
diabetes; as such identification and understanding of early 
life risk factors are particularly relevant. Finally, maternal 
GDM was diagnosed based on the WHO criteria. There 
were several limitations in our study. One limitation of the 
study was that it was a cross-sectional study. Thus, we could 
not make cause-and-effect inferences. Second, maternal 

Table 3 Odds ratios for childhood overweight, obesity, central obesity and high body fat by maternal GDM status.

Outcomes No. of cases/participants
Odds ratios (95% CIs)

Model 1 Model 2 Model 3

Overweight Non-GDM 107/578 1.00 1.00 1.00
GDM 156/578 1.60 (1.20–2.13) 1.55 (1.14–2.10) 1.42 (1.02–1.97)

Obesity Non-GDM 61/578 1.00 1.00 1.00
GDM 98/578 1.73 (1.22–2.46) 1.65 (1.14–2.40) 1.18 (1.11–1.24)

Central obesity Non-GDM 33/578 1.00 1.00 1.00
GDM 51/578 1.60 (1.00–2.55) 1.60 (0.97–2.62) 1.60 (0.94–2.70)

High body fat Non-GDM 96/483 1.00 1.00 1.00
GDM 140/489 1.60 (1.18–2.17) 1.53 (1.11–2.12) 1.47 (1.03–2.08)

Model 1 adjusted for maternal age, gestational age, and education. Model 2 adjusted for covariates in Model 1 and also for maternal smoking status, 
passive smoking status, alcohol drinking status, as well as children’s feeding method, vegetables and fruits intake frequency, outdoor time, screening 
watching time and sleeping duration. Model 3 adjusted for in Model 2 and also for maternal prepregnancy BMI and weight gain during pregnancy.
CI, confidence intervals; GDM, gestational diabetes mellitus.

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J Wang et al. GDM and offspring’s obesity 14707:12

prepregnancy weight and gestational weight gain were 
based on self-reported data, which may introduce recall 
bias. Nevertheless, validation studies in the United States 
and England have found good concordance between 
self-reported information during pregnancy and clinical 
records (33). Moreover, the children’s body measurements 
taken at different ages may conceal at what age this 
association between GDM and childhood overweight/
obesity becomes apparent.

In conclusion, maternal GDM is an independent 
risk factor of childhood overweight and obesity, and it is 
associated with children’s faster growth of BMI. Children 
who are exposed to hyperglycemia in utero have higher 
risks of becoming overweight and obese. Therefore, 
for this high-risk population, appropriate intervention 
strategies are needed.

Declaration of interest
The authors declare that there is no conflict of interest that could be 
perceived as prejudicing the impartiality of the research reported.

Funding
This study was supported by the Tianjin Women’s and Children’s Health 
Center, Tianjin Public Health Bureau, European Foundation for the Study 
of Diabetes (EFSD)/Chinese Diabetes Society (CDS)/Lilly programme for 
Collaborative Research between China and Europe. Dr Hu was partly 
supported by the grant from the National Institute of Diabetes and Digestive 
and Kidney Diseases (R01DK100790) and the National Institute of General 
Medical Sciences (U54GM104940) of the National Institutes of Health.

Author contribution statement
G H and J W designed this study. L W, H L, J L, S Z and W L conducted the 
field research. J W, W L, T Z and N L conducted data organization and 
analysis. J W drafted the manuscript. A A B, L H and G H critically reviewed 
and revised the manuscript.

Acknowledgements
The authors would like to appreciate all the hard-working people from 
Tianjin Women’s and Children’s Health Center dedicating to the Tianjin 
Gestational Diabetes Mellitus Prevention Program.

References
 1 American Diabetes Association. Gestational diabetes mellitus. 

Diabetes Care 2003 26 (Supplement 1) S103–S105.
 2 Metzger BE & Coustan DR. Summary and recommendations of 

the Fourth International Workshop-Conference on Gestational 
Diabetes Mellitus. The Organizing Committee. Diabetes Care 1998 21 
(Supplement 2) B161–B167.

 3 Zhu Y & Zhang C. Prevalence of gestational diabetes and risk of 
progression to type 2 diabetes: a global perspective. Current Diabetes 
Reports 2016 16 7. (https://doi.org/10.1007/s11892-015-0699-x)

 4 Bellamy L, Casas JP, Hingorani AD & Williams D. Type 2 diabetes 
mellitus after gestational diabetes: a systematic review and  

meta-analysis. Lancet 2009 373 1773–1779. (https://doi.org/10.1016/
S0140-6736(09)60731-5)

 5 Silverman BL, Rizzo T, Green OC, Cho NH, Winter RJ, Ogata ES, 
Richards GE & Metzger BE. Long-term prospective evaluation of 
offspring of diabetic mothers. Diabetes 1991 40 (Supplement 2) 
121–125. (https://doi.org/10.2337/diab.40.2.S121)

 6 Silverman BL, Rizzo TA, Cho NH & Metzger BE. Long-term effects 
of the intrauterine environment. The Northwestern University 
diabetes in pregnancy center. Diabetes Care 1998 21 (Supplement 2) 
B142–B149.

 7 Pettitt DJ, Baird HR, Aleck KA, Bennett PH & Knowler WC. Excessive 
obesity in offspring of Pima Indian women with diabetes during 
pregnancy. New England Journal of Medicine 1983 308 242–245. 
(https://doi.org/10.1056/NEJM198302033080502)

 8 Pettitt DJ, Nelson RG, Saad MF, Bennett PH & Knowler WC. Diabetes 
and obesity in the offspring of Pima Indian women with diabetes 
during pregnancy. Diabetes Care 1993 16 310–314. (https://doi.
org/10.2337/diacare.16.1.310)

 9 Dabelea D. The predisposition to obesity and diabetes in offspring of 
diabetic mothers. Diabetes Care 2007 30 (Supplement 2) S169–S174. 
(https://doi.org/10.2337/dc07-s211)

 10 Tam WH, Ma RCW, Ozaki R, Li AM, Chan MHM, Yuen LY, 
Lao TTH, Yang X, Ho CS, Tutino GE, et al. In utero exposure to 
maternal hyperglycemia increases childhood cardiometabolic 
risk in offspring. Diabetes Care 2017 40 679–686. (https://doi.
org/10.2337/dc16-2397)

 11 Hillier TA, Pedula KL, Vesco KK, Oshiro CE & Ogasawara KK. Impact 
of maternal glucose and gestational weight gain on child obesity over 
the first decade of life in normal birth weight infants. Maternal and 
Child Health Journal 2016 20 1559–1568. (https://doi.org/10.1007/
s10995-016-1955-7)

 12 Whitaker RC, Pepe MS, Seidel KD, Wright JA & Knopp RH. 
Gestational diabetes and the risk of offspring obesity. Pediatrics 1998 
101 E9. (https://doi.org/10.1542/peds.101.2.e9)

 13 Gillman MW, Rifas-Shiman S, Berkey CS, Field AE & Colditz GA. 
Maternal gestational diabetes, birth weight, and adolescent 
obesity. Pediatrics 2003 111 e221–e226. (https://doi.org/10.1542/
peds.111.3.e221)

 14 Tam WH, Ma RC, Yang X, Ko GT, Tong PC, Cockram CS, Sahota DS, 
Rogers MS & Chan JC. Glucose intolerance and cardiometabolic 
risk in children exposed to maternal gestational diabetes mellitus 
in utero. Pediatrics 2008 122 1229–1234. (https://doi.org/10.1542/
peds.2008-0158)

 15 WHO Consultation. Definition, Diagnosis and Classification of Diabetes 
Mellitus and Its Complications. Part 1: Diagnosis and Classification of 
Diabetes Mellitus. Geneva, Switzerland: World Health Organization, 
1999.

 16 Li W, Liu H, Qiao Y, Lv F, Zhang S, Wang L, Leng J, Qi L, 
Tuomilehto J & Hu G. Metabolic syndrome of weight change from 
pre-pregnancy to 1–5 years post-partum among Chinese women 
with prior gestational diabetes. Diabetic Medicine 2015 32 1492–1499. 
(https://doi.org/10.1111/dme.12790)

 17 Hu G, Tian H, Zhang F, Liu H, Zhang C, Zhang S, Wang L, Liu G, 
Yu Z, Yang X, et al. Tianjin Gestational Diabetes Mellitus Prevention 
Program: study design, methods, and 1-year interim report on 
the feasibility of lifestyle intervention program. Diabetes Research 
and Clinical Practice 2012 98 508–517. (https://doi.org/10.1016/j.
diabres.2012.09.015)

 18 Li YP, He YN, Zhai FY, Yang XG, Hu XQ, Zhao WH & Ma GS. 
[Comparison of assessment of food intakes by using 3 dietary survey 
methods]. Zhonghua Yu Fang Yi Xue Za Zhi 2006 40 273–280.

 19 Zhou B. [Predictive values of body mass index and waist 
circumference to risk factors of related diseases in Chinese adult 
population]. Zhonghua Liu Xing Bing Xue Za Zhi 2002 23 5–10.

 20 World Health Organization. The WHO Child Growth Standards. 
Geneva, Switzerland: World Health Organization, 2006.

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Published by Bioscientifica Ltd

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https://doi.org/10.1016/S0140-6736(09)60731-5
https://doi.org/10.1016/S0140-6736(09)60731-5
https://doi.org/10.2337/diab.40.2.S121
https://doi.org/10.1056/NEJM198302033080502
https://doi.org/10.2337/diacare.16.1.310
https://doi.org/10.2337/diacare.16.1.310
https://doi.org/10.2337/dc07-s211
https://doi.org/10.2337/dc16-2397
https://doi.org/10.2337/dc16-2397
https://doi.org/10.1007/s10995-016-1955-7
https://doi.org/10.1007/s10995-016-1955-7
https://doi.org/10.1542/peds.101.2.e9
https://doi.org/10.1542/peds.111.3.e221
https://doi.org/10.1542/peds.111.3.e221
https://doi.org/10.1542/peds.2008-0158
https://doi.org/10.1542/peds.2008-0158
https://doi.org/10.1111/dme.12790
https://doi.org/10.1016/j.diabres.2012.09.015
https://doi.org/10.1016/j.diabres.2012.09.015
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https://ec.bioscientifica.com


J Wang et al. GDM and offspring’s obesity 14717:12

 21 Ogden CL, Carroll MD, Kit BK & Flegal KM. Prevalence of obesity 
and trends in body mass index among US children and adolescents, 
1999–2010. JAMA 2012 307 483–490. (https://doi.org/10.1001/
jama.2012.40)

 22 Fernandez JR, Redden DT, Pietrobelli A & Allison DB. Waist 
circumference percentiles in nationally representative samples of 
African-American, European-American, and Mexican-American 
children and adolescents. Journal of Pediatrics 2004 145 439–444. 
(https://doi.org/10.1016/j.jpeds.2004.06.044)

 23 Laurson KR, Eisenmann JC & Welk GJ. Body fat percentile curves for 
U.S. children and adolescents. American Journal of Preventive Medicine 
2011 41 S87–S92. (https://doi.org/10.1016/j.amepre.2011.06.044)

 24 Reece EA. The fetal and maternal consequences of gestational 
diabetes mellitus. Journal of Maternal-Fetal and Neonatal Medicine 2010 
23 199–203. (https://doi.org/10.3109/14767050903550659)

 25 Thaware PK, McKenna S, Patterson CC, Hadden DR, Pettitt DJ & 
McCance DR. Untreated mild hyperglycemia during pregnancy and 
anthropometric measures of obesity in offspring at Age 5–7 years. 
Diabetes Care 2015 38 1701–1706. (https://doi.org/10.2337/ 
dc14-2797)

 26 Pettitt DJ, McKenna S, McLaughlin C, Patterson CC, Hadden DR 
& McCance DR. Maternal glucose at 28 weeks of gestation is 
not associated with obesity in 2-year-old offspring: the Belfast 
Hyperglycemia and Adverse Pregnancy Outcome (HAPO) family 
study. Diabetes Care 2010 33 1219–1223. (https://doi.org/10.2337/
dc09-2384)

 27 Lawlor DA. The Society for Social Medicine John Pemberton Lecture 
2011. Developmental overnutrition-an old hypothesis with new 
importance? International Journal of Epidemiology 2013 42 7–29. 
(https://doi.org/10.1093/ije/dys209)

 28 Sullivan EL & Grove KL. Metabolic imprinting in obesity. Forum of 
Nutrition 2010 63 186–194.

 29 Waterland RA & Garza C. Potential mechanisms of metabolic 
imprinting that lead to chronic disease. American Journal of Clinical 
Nutrition 1999 69 179–197. (https://doi.org/10.1093/ajcn/69.2.179)

 30 Fraser A & Lawlor DA. Long-term health outcomes in offspring born 
to women with diabetes in pregnancy. Current Diabetes Reports 2014 
14 489. (https://doi.org/10.1007/s11892-014-0489-x)

 31 Oh W, Gelardi NL & Cha CJ. Maternal hyperglycemia in 
pregnant rats: its effect on growth and carbohydrate metabolism 
in the offspring. Metabolism 1988 37 1146–1151. (https://doi.
org/10.1016/0026-0495(88)90192-8)

 32 Yamashita H, Shao J, Qiao L, Pagliassotti M & Friedman JE. Effect 
of spontaneous gestational diabetes on fetal and postnatal hepatic 
insulin resistance in Lepr(db/+) mice. Pediatric Research 2003 53 
411–418. (https://doi.org/10.1203/01.PDR.0000049667.58071.7D)

 33 Dietz P, Bombard J, Mulready-Ward C, Gauthier J, Sackoff J, 
Brozicevic P, Gambatese M, Nyland-Funke M, England L, Harrison L, 
et al. Validation of self-reported maternal and infant health 
indicators in the Pregnancy Risk Assessment Monitoring System. 
Maternal and Child Health Journal 2014 18 2489–2498. (https://doi.
org/10.1007/s10995-014-1487-y)

Received in final form 14 November 2018
Accepted 30 November 2018
Accepted Preprint published online 3 December 2018

This work is licensed under a Creative Commons 
Attribution-NonCommercial 4.0 International 
License.

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https://ec.bioscientifica.com © 2018 The authors

Published by Bioscientifica Ltd

https://doi.org/10.1001/jama.2012.40
https://doi.org/10.1001/jama.2012.40
https://doi.org/10.1016/j.jpeds.2004.06.044
https://doi.org/10.1016/j.amepre.2011.06.044
https://doi.org/10.3109/14767050903550659
https://doi.org/10.2337/dc14-2797
https://doi.org/10.2337/dc14-2797
https://doi.org/10.2337/dc09-2384
https://doi.org/10.2337/dc09-2384
https://doi.org/10.1093/ije/dys209
https://doi.org/10.1093/ajcn/69.2.179
https://doi.org/10.1007/s11892-014-0489-x
https://doi.org/10.1016/0026-0495(88)90192-8
https://doi.org/10.1016/0026-0495(88)90192-8
https://doi.org/10.1203/01.PDR.0000049667.58071.7D
https://doi.org/10.1007/s10995-014-1487-y
https://doi.org/10.1007/s10995-014-1487-y
https://creativecommons.org/licenses/by-nc/4.0/
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	Abstract
	Introduction
	Methods
	GDM screening process
	Study population
	Calculation of BMI
	Children’s Z scores and overweight/obesity
	Statistical analyses

	Results
	Discussion
	Declaration of interest
	Funding
	Author contribution statement
	Acknowledgements
	References