Gestational weight management and pregnancy outcomes among women of advanced maternal age
- Authors:
- Published online on: July 9, 2019 https://doi.org/10.3892/etm.2019.7752
- Pages: 1723-1728
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Copyright: © Lin et al. This is an open access article distributed under the terms of Creative Commons Attribution License.
Abstract
Introduction
Pregnancy weight management is a goal of prenatal care in China. Since the implementation of the two-child policy, the proportion of pregnant women of advanced maternal age (AMA, pregnant women >35 years of age) has increased; this proportion accounts for approximately 60% of all pregnancies, and half of these women are older than 40 years (1). Women of AMA are more frequently overweight before the pregnancy (2), and are more likely to have had internal and surgical diseases, and are more likely to be multiparas; in addition, age is an independent risk factor for maternal and child adverse outcomes (3). Therefore, AMA pregnancy management aims to improve pregnancy outcomes.
Pre-pregnancy overweight may lead to gestational diabetes mellitus (GDM), hypertensive disorders complicating pregnancy (HDCP), fetal macrosomia, and other adverse pregnancy outcomes (4). Women of AMA may disregard pregnancy weight management recommendations, and excessive weight gain during pregnancy can increase the incidence of adverse outcomes (5).
Controlling pre-pregnancy weight and gestational weight gain (GWG) reduces the incidence of GDM, HDCP, preterm births (PTBs), shoulder dystocia and the incidence of large for gestational age (LGA) births; weight control increases vaginal delivery rates, and decreases the incidence of low birth weight and of small for gestational age (SGA) births (6). Therefore, the evidence-based management of pre-pregnancy and gestational weights maximizes good pregnancy outcomes.
In this study, we analyzed the clinical data of 1,015 women of AMA admitted to Fujian Provincial Maternity and Children's Hospital to detect associations between their pre-pregnancy body mass indexes (BMIs) or GWGs and their pregnancy outcomes.
Materials and methods
Study population
From January to June, 2017, 1,015 women of AMA delivered babies at the Fujian Provincial Maternity and Children's Hospital. We included data from women older than 35 years of age at delivery with single pregnancies who had had >5 prenatal checkups We excluded data from women with internal and surgical diseases, and those with incomplete information. The Ethics Committee of the Fujian Provincial Maternity and Children's Hospital approved the study and waived the need for informed consents given its retrospective nature.
Research methods
We collected medical and hospitalization information, including data on pregnancy outcomes (GDM, HDCP and PTB) and neonatal complications (macrosomia and SGA). Data were grouped according to the women's age during childbirth into an advanced age group (35–40 years) and a super-advanced age group (≥40 years).
Alternatively, data were grouped according to the women's pre-pregnancy BMIs [according to the guidelines for pregnancy weight management published by the National Institute of Medicine (IOM) in 2009 (7)] into the underweight group (BMI <18.5 kg/m2) with 105 cases; normal weight (BMI 18.5–24.9 kg/m2) group with 789 cases; overweight group (BMI 25.0–29.9 kg/m2) with 107 cases; and, obese group (BMI ≥30 kg/m2) with 14 cases. Finally, we also subdivided data according to GWG among women with normal BMIs (IOM guidelines) into 3 subgroups as follows: A (GWG <11.5 kg with 188 cases), B (GWG between 11.5 and 16.0 kg with 405 cases), and C (GWG >16.0 kg with 196 cases). We compared the mean variables and outcome incidences between the groups.
Statistical analysis
We performed all statistical analyses using SPSS 21.0 software (SPSS, Inc.). We calculated measurement data as the means ± standard deviation (SD). We used one-way ANOVA for testing hypotheses between groups and used the Scheffe test for comparing between groups to prove the significance of ANOVA. Chi-square tests for qualitative difference analyses. We applied a logistic regression analysis to examine the influence of variables on the pregnancy outcomes. Values of P<0.05 were considered to indicate statistically significant differences.
Back-propagation (BP) neural network applications
Among the 1,015 women, 800 cases of AMA were randomly selected as the training dataset. The BP neural network is a supervised model divided into 3 layers (input, hidden and output) (8). In this study, we designed a 3-layer BP neural network to examine the effects of pre-pregnancy BMI and GWG on pregnancy outcomes. We set the characteristic value ×1 as the pre-pregnancy BMI and ×2 as the GWG; the output value y1 included GDM, HDCP, PTB, macrosomia, SGA and neonatal birth weight (NBW). The two input values (×1 and ×2) were set as the input layer nodes, and the output values were set as the output layer nodes (y1) (Fig. S1).
Results
General conditions of women of AMA
We collected clinical data from 1,015 women, 809 in the advanced-age group (79.7%) and 206 in the super-advanced age group (20.3%). Among the women in the advanced age group, 93 (11.50%) were underweight, 623 (77.01%) were at a normal weight, 83 (10.26%) were overweight and 10 (1.23%) were obese. In addition, among the women in the super-advanced age group, 12 (5.83%) were underweight, 166 (80.58%) were at a normal weight, 24 (11.65%) were overweight and 4 (1.94%) were obese. The women in the super advanced maternal age group had a higher incidence of overweight and obesity than those in the advanced maternal age group (P<0.05) (Table I).
Table I.Maternal baseline characteristics between women in the advanced-age group and those in the super-advanced age group. |
Association between maternal age at birth and pregnancy outcome
We found a higher incidence of GDM, HDCP and macrosomia in the super-advanced maternal age group than in the advanced age group (P<0.05; Table II).
Table II.Comparison of pregnancy outcomes between women of advanced age and those with a super-advanced age. |
Association between pre-pregnancy BMI and pregnancy outcome
As shown in Table III, overweight women had a significantly greater incidences of GDM, HDCP and fetal macrosomia than women who were at a normal weight (both P<0.05). In addition, birth weight differed significantly among the 4 groups (P<0.05).
Association between GWG and pregnancy outcome in the normal BMI group
The incidence of GDM in the low GWG group (group A) was 38.30%, which was higher than that in the normal GWG group (group B; 27.41%). The risk of developing HDCP and macrosomia was also increased in women with a high GWG. The risks of PTB were higher in women with low GWG than those in the normal GWG group (group B). The mean NBWs differed between the 3 groups of mothers (Table III).
BP neural network training results
Data from 800 women of AMA were randomly selected for the training dataset. We used the pre-pregnancy BMI as input ×1, the GWG as input ×2, and the pregnancy outcome as output y1. We factored in 6 pregnancy outcomes (GDM, HDCP, PTB, macrosomia, SGA and NBW). As a result, we established 6 neural networks to train the 6 pregnancy outcomes separately. We used data from 215 women of AMA and pre-pregnancy BMI, GWG and pregnancy outcomes to validate the BP neural network training model. The prediction accuracy of the 6 pregnancy outcomes from the BP neural network training model is presented in Table IV.
Table IV.BP network predicts the accuracy of 6 pregnancy outcomes and the importance of pre-pregnancy BMI and GWG for pregnancy outcomes. |
We compared the weighted influence of pre-pregnancy BMI and GWG on the pregnancy outcomes. Pre-pregnancy BMI affects the development of GDM by about half the influence of GWG; the pre-pregnancy BMI and GWG had similar influences on HDCP and macrosomia. The influence of pre-pregnancy BMI on SGA and on NBW was slightly greater than that of GWG on the same outcomes (Table IV).
Discussion
Women of AMA are more likely to be overweight and this factor, together with other medical variables, increases their risk of maternal and child adverse outcomes (1,3). Prenatal education and weight control can improve pregnancy outcomes.
Association of pre-pregnancy weight and pregnancy outcomes for women with AMA. Age is a risk factor for pre-pregnancy overweight (2), and overweight can trigger GDM, HDCP, macrosomia and other adverse pregnancy outcomes (9–11). In this study, we demonstrated that women of AMA and overweight were more likely to develop GDM than women with normal pre-pregnancy BMIs. A previous study demonstrated that the risk of developing GDM among women who were overweight before pregnancy was greater than the risk among pregnant women with normal pre-pregnancy weights (2). The body's glucose tolerance becomes impaired with age due to gradual islet β-cell dysfunction (12), and being overweight is associated with insulin resistance, insulin secretion abnormalities, and insulin receptor abnormalities(1). Thus, women of AMA and who are overweight are more prone to GDM during pregnancy than their younger counterparts. The prevalence of HDCP in obese pregnant women is up to 6-fold greater than that in pregnant women with a normal weight (10), and the probability of developing preeclampsia is also higher among these women (13). A multicenter cohort study on the association between pre-pregnancy BMI and pregnancy outcomes found that the incidence of pre-eclampsia increased with maternal pre-pregnancy weight (14). Women of AMA undergo progressive damage to their uterine myometrial vascular endothelial cells (decreased vasoconstriction and sclerosis), which causes ischemia or oxidative stress. In addition, the adipose tissue in women of AMA who are also overweight secretes excessive adipokines that increase blood pressure during pregnancy. The results of this study demonstrated that women of AMA and high pre-pregnancy BMIs had the greatest risk of developing HDCP.
The occurrence of PTB and pre-pregnancy BMI in this study had a ‘U’-shaped association, with the incidence of PTB being higher in women with low pre-pregnancy BMIs, lower in women with normal BMIs, and higher again in women with high pre-pregnancy BMIs. This may be explained by nutrient deficiencies with insufficient body fluid expansion in women with low BMIs that increases the spontaneous incidence of PTB (15), and by the triggering of gestational hypertension, pre-eclampsia and other inadvertent pregnancy outcomes that can lead to an increase in iatrogenic PTB in women with pre-pregnancy overweight (16). Pre-pregnancy BMIs and GWGs have been shown to be positively associated with NBW and macrosomia, and to be negatively associated with SGA (4).
A meta-analysis of global pregnancy cases demonstrated that a low BMI increased the risk of SGA, while a high BMI decreased this risk (17). Women of AMA tend to present with hyperlipidemia (1), and higher GWGs than younger women. In addition, women of AMA are more often diabetic, and more prone to developing GDM, which increases the chance of macrosomia (9,18). The incidence of macrosomia in this study increased with the BMIs of the mothers. In addition, the risk SGA was greater in women with low pre-pregnancy BMIs than in women with normal pre-pregnancy BMIs; however, women with high pre-pregnancy BMI had a decreased risk of SGA.
Association between GWG and pregnancy outcomes in women of AMA. We found low GWG to be a risk factor for GDM. The results of BP neural network revealed that the effect of GWG on GDM was 2-fold stronger than that of pre-pregnancy BMI, similarly to the results of a previous study (9). In this study, the women who had regular prenatal checkups received dietary and exercise guidance after receiving a diagnosis of GDM. Therefore, they conducted routine blood glucose monitoring and controlled their weight for the rest of the pregnancy. Strict pregnancy weight management should maintain a lower GWG for women with GDM than for women without GDM (4). The results of this study revealed that the risk of HDCP in women with excessive GWG was greater than that in women with normal GWG, but insufficient GWG was not associated with HDCP. Although excessive GWG is positively associated with HDCP, distinguishing the cause and effect between GWG and HDCP is difficult. Excessive weight gain may increase the incidence of HDCP; however, HDCP induces edema and fluid retention, thus leading to increased weight (10).
The association between GWG and PTB is also controversial. In this study, we found that the incidence of PTB in women with insufficient GWG was greater than that in women with normal GWG. The results of our BP neural network revealed that the influence of GWG on the risk of PTB was 2-fold greater than the influence of pre-pregnancy BMI, suggesting that insufficient GWG is the main cause of PTB. In addition, the risk of macrosomia in women with excessive GWG was greater than that in women with normal GWG. Insufficient GWG was not associated with macrosomia. A previous study found a greater risk of macrosomia in women with excessive GWG than that in women with normal GWG (19). In this study, we did not observe reductions in the risk of macrosomia in women with insufficient GWG. In addition, the risk of SGA in women with insufficient GWG was greater than that in women with normal GWG, and excessive GWG was not associated with SGA. Studies have shown indirect associations between SGA and GWG (10,20).
In conclusion, according to the findings of this study, among women of AMA, compared with with those who are at a normal weight pre-pregnancy, being overweight increased the risk of GDM, HDCP and macrosomia. The incidence of macrosomia was higher in the group of women who gained more weight during pregnancy than those who met the IOM standard. On the contrary, the incidence of PTB was higher in the group of women who gained less weight during pregnancy than in the group whose GWG met the IOM standard. According to the recommended IOM guidelines. Women of AMA should control their pre-pregnancy BMI and maintain a normal GWG to diminish the risks of adverse pregnancy outcomes. The BP neural network is a suitable approach for the study of weight changes in women with AMA during pregnancy.
Supplementary Material
Supporting Data
Acknowledgements
Not applicable.
Funding
This study was supported by the Fujian Science and Technology Key Project (2018Y0005), and Fujian Medical Innovation Subject (2017-CX-11), and the Key Clinical Specialty Discipline Construction of Fujian, P.R. China [(2015) no. 593].
Availability of data and materials
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
Authors' contributions
JL, YF and JY conceived and designed the study; QH, RC and HZ collected and analyzed the data of this study; JL, YF and QH wrote the manuscript; and JY reviewed and edited the manuscript. All authors have read and approved the final manuscript.
Ethics approval and consent to participate
The Ethics Committee of the Fujian Provincial Maternity and Children's Hospital approved this retrospective medical record review (approval no. 2017-CX-11).
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
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