To examine the first-trimester maternal serum placental growth factor (PlGF) and pregnancy-associated plasma protein A (PAPP-A) levels in pregnancies associated with pre-eclampsia (PE) or small-for-gestational-age (SGA) infants, and determine the predictive accuracy of PlGF and of PAPP-A for either PE or SGA infants.
This prospective, observational study included 175 pregnant women, and of these women, due to participant withdrawal or loss to follow-up, delivery data were collected from the medical records of 155 women, including 4 who had twin pregnancies. The women's maternal history was recorded, and the PlGF and PAPP-A levels at 11 to 13 gestational weeks were measured. During the second trimester, the maternal uterine artery's systolic/diastolic ratio was measured. Multiples of the median (MoM) of PlGF and PAPP-A were determined, and the associations of these values with the risk factors of SGA and PE were evaluated. Logistic regression analysis was used to determine whether PlGF and PAPP-A are useful markers for predicting SGA infants.
The PAPP-A MoM level was significantly lower in women with advanced maternal age, multipara women, and women with gestational diabetes than in their counterparts. The PlGF and PAPP-A MoM levels were higher in women with a twin pregnancy than in those with a singleton pregnancy. There was a significant relationship between the maternal serum PAPP-A MoM level in the first trimester and the uterine artery systolic/diastolic ratio in the second trimester. Results of logistic regression analysis showed that low PlGF and PAPP-A MoM levels were predictors of SGA infants (odds ratio, 0.143; 95% confidence interval, 0.025 to 0.806; odds ratio, 0.191; 95% confidence interval, 0.051 to 0.718, respectively).
PlGF and PAPP-A are potentially useful as first-trimester markers for SGA infants and some hypertensive disorders of pregnancy.
Pre-eclampsia (PE) is a multi-system disorder characterized by the new onset of hypertension and proteinuria or end-organ dysfunction, or both during the second half of pregnancy. Although most pregnancies with PE are associated with delivery at term or near term, with good maternal and fetal outcomes, these pregnancies have a high risk for maternal and/or fetal mortality or serious morbidity [
Currently, there is no reliable, valid, and economical screening test for SGA infants and PE. Previous studies have assessed associations between the suggested fetal weight through ultrasonography and pregnancies that resulted in SGA infants or between placenta-related proteins and pregnancies that resulted in PE or SGA infants to establish early biomarkers for SGA infants and PE [
The placental growth factor (PlGF) is a dimeric glycoprotein that belongs to the vascular endothelial growth factor family. It was first isolated in 1991, and it was later found to be predominantly expressed by trophoblast cells, placental villi, and human umbilical vein endothelial cells during pregnancy [
Pregnancy-associated plasma protein A (PAPP-A) is a metalloprotease that belongs to the metzincin superfamily of zinc-dependent metalloproteases. It is used as a biochemical marker of chromosomal anomalies, especially in those with Down syndrome, and it is measured during the second trimester of pregnancy. Studies have shown that low PAPP-A levels are associated with chromosomal anomalies in fetuses, and they can predict adverse pregnancy outcomes such as fetal growth restriction, spontaneous miscarriage, moderately and extremely premature births, PE, and stillbirths [
An increased umbilical artery systolic-diastolic ratio has been reported to result from poorly vascularized placental villi, and it is seen in extreme cases of fetal growth restriction [
These purposes of this study were to examine the first-trimester maternal serum placental growth factor (PlGF) and pregnancy-associated plasma protein (PAPP-A) levels in pregnancies associated with pre-eclampsia (PE) or small-for-gestational-age (SGA) infants, and to determine the predictive accuracy of PlGF and of PAPP-A for either PE or SGA infants using fetal umbilical artery systolic-diastolic ratio, which is already a well-known modality for observing placental vascularization markers.
This prospective, observational study was performed between May 1, 2012 and June 30, 2014, and it included pregnant women who received antenatal care at the National Health Insurance Service Ilsan Hospital, Goyang, Republic of Korea. One hundred seventy-five pregnant women were recruited, and blood was sampled from them during the first trimester. However, 20 women either withdrew from the study because they aborted their fetus before 25 weeks of gestation or they were lost to follow-up. Therefore, 155 women's medical records were reviewed and data were collected regarding their delivery. Among the women, 10 delivered at another hospital, and data regarding their delivery were obtained by phone. Four women had twin pregnancies, and 151 had singleton pregnancies.
All women were informed of the nature of the study, and all who agreed to participate provided written informed consent. The study was approved by the Ethics Committee of the National Health Insurance Service Ilsan Hospital (SUYON NHIMC 2012-06-005).
We assessed the associations of known risk factors for SGA infants and PE, including nulliparity, advanced maternal age, diabetes, hypertension, obesity, a history of smoking, maternal hypertension, a family history of diabetes, and twin pregnancies with PlGF and PAPP-A. Pregnancy-related data such as maternal age, gestational age, and neonatal birth weight were obtained from the patients' electronic medical records.
Maternal serum samples were collected to measure the PlGF and PAPP-A levels as part of the 11+0 to 13+6 weeks' screening program to determine the risk of fetal abnormalities, and the nuchal translucency was simultaneously assessed. Blood samples were allowed to clot between 15℃ and 22℃ for 30 to 90 minutes. Then the samples were centrifuged for 15 minutes at 300 g. The serum was collected and stored at −20℃ for up to 4 days, and then it was stored at −70℃. At the end of the study period, all samples were transferred simultaneously to a central laboratory, and they were tested for PlGF (6007-0030 DELFIA Xpress PlGF 1-2-3 kit, PerkinElmer, Turku, Finland) and PAPP-A (6003-0020 DELFIA Xpress PAPP-A Kit, PerkinElmer) using standard routine methodologies (Wallac Oy, PerkinElmer Inc., Turku, Finland).
Uterine artery Doppler examination was performed during the second trimester between 22+0 and 24+6 gestational weeks. Ultrasound scanning was performed by one expert (EHK) to reduce inter-observer variation using the Philips Ultrasound IU22 scanner (Philips, Bothell, WA, USA). The PlGF and PAPP-A levels were converted to multiples of the median (MoM) by dividing each individual result by the expected median marker of the control group at that gestational age. Maternal serum marker levels were expressed in multiples of the normal gestation-specific median based on regression analysis among the women with singleton pregnancies by combining the first-trimester results. The median level for each completed week of gestation was regressed against the median days and weighted for the number of samples tested. Gestation was derived from the crown-rump length (CRL) using a published formula (Philips Ultrasound IU22, [CRL×1.04]0.5×8.05+23.7) [
An infant was considered an SGA infant if the infant's birth weight was less than the tenth percentile after correcting for the reference gestational age of Koreans [
Differences between the groups were assessed using the Student t test to determine which factors could significantly predict PE. The odds ratio (OR) of PlGF and PAPP-A for PE and SGA infants was obtained using logistic regression analysis. Receiver operating characteristic (ROC) curves were used to assess the efficacy of clinical parameters to predict SGA infants. All
One hundred seventy-five pregnant women were included in this study, and 155 women's medical record data regarding their deliveries could be collected. The women's demographic data are presented in
The median maternal and gestational ages were 32 years and 38 weeks, respectively. Of 175 women, 103 (58.9%) were nulliparous and 72 (41.1%) were multiparous. The median PlGF and PAPP-A MoM levels were 0.92 (95% confidence interval, 0.22 to 2.85) and 1.05 (95% confidence interval, 0.10 to 4.06), respectively.
The association of the risk factors of PE and SGA infants with PlGF and PAPP-A are presented in
In singleton pregnancies, PlGF and PAPP-A MoM levels were assessed in 18 women who delivered SGA infants (SGA group) and 133 women who delivered appropriate-for-gestational-age infants (control group); additionally, these levels were assessed in 10 women with PE (PE group) and 141 women without PE (control group). We found that the PlGF and PAPP-A MoM levels were significantly lower in the SGA group than in the corresponding control group, and the PlGF and PAPP-A MoM levels tended to be lower in the PE group than in the corresponding control group, without statistical significance (
According to the the results of logistic regression analysis, the PlGF MoM level was significantly positively correlated with the PAPP-A MoM level (r=0.467,
According to the ROC curves, the best cut-off points for predicting an SGA infant was 0.885 for PlGF MoM and 1.06 for PAPP-A MoM. The area under the curve (AUC) of the ROC for PAPP-A MoM (AUC, 0.728;
Recently, studies have shown that between the first and second trimesters of singleton pregnancies, changes in maternal plasma levels of angiogenic factors (e.g., vascular endothelial growth factor, PlGF, and PAPP-A) and anti-angiogenic factors (e.g., soluble fms-like tyrosine kinase-1 [sFlt-1]) and/or their ratios increase the risk of delivering SGA infants and/or developing PE [
A lower PlGF level than normal due to insufficient vascular remodeling of the spiral arteries eventually leads to reduced perfusion of the placenta, which is conceivably involved in the following adverse pregnancy outcomes: SGA, PE, HELLP (hemolysis, increased liver enzymes, and low platelets) syndrome [
Contrary to our expectation, we found that PAPP-A MoM levels were higher in primipara women and women with a BMI ≥25 kg/m2; these factors are generally regarded as risk factors for hypertensive disorders. However, the PlGF MoM levels tended to be lower, although not statistically significant, in primipara women and women with a BMI ≥25 kg/m2. One possible explanation for these findings is that PlGF is more accurate for predicting PE than PAPP-A as an independent factor, and/or PE involves more complex and various factors than delivering SGA infants. We found that the PAPP-A and PlGF MoM levels were higher in women with a twin pregnancy than in those with a singleton pregnancy. These findings are consistent with those of previous studies [
The present study's findings demonstrated that in pregnancies resulting in the birth of SGA infants, the maternal serum PlGF and PAPP-A levels at 11+0 to 13+6 weeks of gestation decrease, and in normal pregnancies, there was a significant association between the serum levels of these metabolites and birth weight, which may be predetermined, which are findings consistent with the those of previous studies [
This study has several strengths. First, this was a prospective, observational study performed by one operator, which reduced the inter-observer variability of the ultrasound scans. Second, to our knowledge, this is the first study about the associations of PlGF and PAPP-A assessed in the first trimester in terms of PE and SGA infants in South Korea. Third, to evaluate placentation, we performed uterine artery Doppler sonography in the second trimester instead of measuring the PlGF and PAPP-A levels in the first trimester. In the future, further clinical studies on the accuracy of PlGF and PAPP-A levels as predictors of PE should be performed.
However, this study has several limitations. First, the study included a small number of women; therefore, our study only confirmed that the PlGF and PAPP-A levels in the PE group were similar to those in the control group. There is a possibility that the PE group included a smaller number of women than the SGA group in our study, and PE itself has more complex factors than SGA. Second, we did not subdivide the HDP, such as gestational hypertension, PE, eclampsia, PE superimposed on chronic hypertension, and chronic hypertension. If we could have subdivided the hypertensive disorders and had a sufficient number of patients with PE, we may have found a relationship between PE and PlGF, and PAPP-A. In conclusion, the PlGF and PAPP-A levels are potentially useful as first-trimester markers for SGA infants and some HDP. The measurement of PlGF and PAPP-A in the first trimester may be more useful in developing countries where regular antenatal care during pregnancy cannot be provided. Further studies are needed to demonstrate the different roles of PlGF and PAPP-A in placentation. Additionally, large-scale studies should be performed to further evaluate the usefulness of these markers alone and in combination with an ultrasonography examination, and other markers such as sFlt-1 should be studied further. Furthermore, early interventional trials should be designed to prevent these pregnancy complications.
This study was supported by the National Health Insurance Service, Ilsan Hospital (no. SUYON 2013-21) .
No potential conflict of interest relevant to this article was reported.
Characteristics | Value |
---|---|
Maternal age (yr) | 32.0 (20–43) |
Body mass index (kg/m2) | 21.8 (16.2–36.0) |
PlGF MoM level | 0.92 (0.22–2.85) |
PAPP-A MoM level | 1.05 (0.10–4.06) |
Gestational weeks | 38.0 (15–41) |
Fetal body weight (g) | 3,085 (150–4,230) |
Parity | |
Nulliparous | 103 (58.9) |
Parous | 72 (41.1) |
Data are presented as median (range) or number (%).
PlGF, placental growth factor; MoM, multiples of the median; PAPP-A, pregnancy-associated plasma protein A.
Number | PlGF MoM | PAPP-A MoM | |
---|---|---|---|
Parity | |||
Primipara | 103 | 0.99±0.47 | 1.36±0.84 |
Multipara | 72 | 1.02±0.39 | 1.13±0.65 |
|
0.87 | 0.04a) | |
Maternal age (yr) | |||
<35 | 122 | 1.00±0.42 | 1.34±0.82 |
≥35 | 53 | 0.95±0.40 | 1.05±0.63 |
|
0.51 | 0.04a) | |
Obesity (kg/m2) | |||
BMI <25 | 132 | 1.02±0.45 | 1.25±0.76 |
BMI ≥25 | 43 | 0.87±0.29 | 1.31±0.83 |
|
0.07 | 0.69 | |
Family history of HiBP | |||
Controlled | 118 | 0.95±0.40 | 1.26±0.69 |
Uncontrolled | 57 | 1.08±0.44 | 1.28±0.93 |
|
0.06 | 0.83 | |
HiBP | |||
Controlled | 171 | 1.00±0.42 | 1.27±0.77 |
Uncontrolled | 4 | 0.75±0.29 | 1.10±0.63 |
|
0.19 | 0.41 | |
Presence of DM | |||
No | 169 | 1.00±0.42 | 1.28±0.77 |
Yes | 6 | 0.84±0.32 | 0.91±0.82 |
|
0.34 | 0.24 | |
Presence of GDMb) | |||
No | 140 | 0.95±0.35 | 1.22±0.68 |
Yes | 11 | 0.80±0.25 | 0.76±0.31 |
|
0.14 | 0.03a) | |
History of smoking | |||
No | 153 | 0.96±0.39 | 1.29±0.70 |
Yes | 22 | 1.15±0.55 | 1.10±0.79 |
|
0.05a) | 0.29 | |
Pregnancy type | |||
Single | 165 | 0.96±0.39 | 1.19±0.69 |
Twin | 10 | 1.41±0.70 | 2.40±1.17 |
|
0.001a) | <0.001a) |
Data are presented as mean±standard deviation.
PlGF, placental growth factor; PAPP-A, pregnancy-associated plasma protein A; MoM, multiples of the median; BMI, body mass index; HiBP, high blood pressure; DM, diabetes mellitus; GDM, gestational diabetes.
a)Statistically significant; b)Diagnosed during the second trimester in a singleton pregnancy.
Number | PlGF MoM | PAPP-A MoM | |
---|---|---|---|
Presence of SGA | |||
No | 133 | 0.97±0.34 | 1.24±0.70 |
Yes | 18 | 0.78±0.32 | 0.82±0.31 |
|
0.026a) | 0.012a) | |
Presence of PE | |||
No | 141 | 0.94±0.34 | 1.18±0.67 |
Yes | 10 | 0.99±0.43 | 1.31±0.83 |
|
0.66 | 0.58 |
Data are presented as mean±standard deviation.
SGA, small-for-gestational-age; PE, pre-eclampsia; PlGF, placental growth factor; PAPP-A, pregnancy-associated plasma protein A; MoM, multiples of the median.
a)Statistically significant.
Variable | Odds ratio | 95% confidence interval | |
---|---|---|---|
PlGF MoM | 0.143 | 0.025–0.806 | 0.027a) |
PAPP-A MoM | 0.191 | 0.051–0.718 | 0.014a) |
Pre-eclampsia | 5.600 | 1.141–27.488 | 0.034a) |
PlGF, placental growth factor; MoM, multiples of the median; PAPP-A, pregnancy-associated plasma protein A.
a)Statistically significant.
Variable | Odds ratio | 95% confidence interval | |
---|---|---|---|
PlGF MoM | 1.502 | 0.244–9.265 | 0.661 |
PAPP-A MoM | 1.281 | 0.540–3.037 | 0.575 |
Age | 1.304 | 1.053–1.614 | 0.015a) |
Body mass index | 1.230 | 1.055–1.434 | 0.008a) |
PlGF, placental growth factor; MoM, multiples of the median; PAPP-A, pregnancy-associated plasma protein A.
a)Statistically significant.