DOI: S0100-7203(13)03500700006 - volume 35 - Julho 2013
Maryam Afrakhteh, Aida Moeini, Morteza Sanei Taheri, Hamid Reza Haghighatkhah
Introduction
The human placenta develops with the principal function of providing nutrients and oxygen to the fetus1. Adequate fetal growth and subsequent normal birth weight depends on the efficient delivery of nutrients from the mother to the fetus via normally functioning utero-placental organ2. It is clear that normal development of placenta during gestation is necessary for supporting of a healthy fetus3. On the other hand, any impairment in its development may have a profound impact on fetal development and pregnancy outcome1. The ratio of the birth weight to the placental weight has been used since the 1940s as an index for the appropriateness of fetal growth4.
The definitive placenta is clearly visible on ultrasound from approximately 9 - 10 weeks of gestation, when it demonstrates a uniformly granular echogenic pattern5. Ultrasonography (US) enables the evaluation of the placenta and the detection of placental abnormalities using different parameters such as placental thickness and volume or especial techniques like three-dimensional (3D) power Doppler6-10. Recent studies focused on 3D measurement of placenta to predict the adverse pregnancy outcome; however, this technique is relatively new, needs complex clinical setting and gives conflicting results regarding its reproducibility in evaluating placenta1. Ultrasound measurement of placental thickness is a relative simple, reproducible and clinical useful way, which had been used for more than two decades6-8.
Some investigators showed in two different studies that placental size in mid-pregnancy independently has relationship with birth parameters9,10; although most of the placental growth occurred in the third trimester. Other researchers like Goldenberg et al.11 stated that birth size was only predicted in the third trimester by fetal ultrasound measurements. Many studies were retrospective or cross-sectional in design and could not truly show the relationship between placental measurements and fetal outcome6,10. It seems reasonable that serial evaluation of placental thickness in second and third trimester could help to determine normal development and functional placenta and deserve as a good predictor of fetal growth and birth weight.
The aim of this prospective longitudinal study was to investigate the relationship between placental thickness during the second and third trimesters and placental and birth weights.
Methods
A total of 250 pregnant women aged between 15 and 45 years presented at our antenatal clinic of Tajrish Hospital were enrolled in a prospective observational study from January 2011 to June 2012. The exclusion criteria were systemic illness or genetic abnormality, for example, sickle cell disease, morbid obesity, missing records and unwilling to incorporate in the study. All patients provided an informed written consent after they were fully instructed about the investigation. The study was approved by ethical committee of Shahid Beheshti University of Medical Sciences.
All recruited women were observed at the 1st trimester screening at antenatal clinic and assessed for baseline demographic and obstetric data including age, parity, body mass index (BMI) and past medical events. Smoking, alcohol and drug use were also determined. At second and third trimester (15 - 20 and 30 - 34 weeks of gestation respectively), the maternal weight, weight gain, BMI, BMI gain and data of ultrasound examination were recorded. At the time of delivery after assessment of maternal weight as mentioned above, the birth weight (in grams), fetal sex, and mode of delivery were taken. After delivery, the placenta was weighed in grams as previously described by Azpurua et al.2. Fetal and neonatal status and morbidity including baby Apgar scores, fetal distress or fetal death and admission to the neonatal intensive care unit were also determined. All the examinations and data recording were performed by two senior resident physicians.
All pregnant women underwent ultrasound evaluation of placental thickness at the time of second trimester (15 - 20 weeks of gestation) as well as third trimester (30 - 34 weeks of gestation). All sonographic examinations were performed trans-abdominally using a Hitachi EUB 525 Color Doppler ultrasound scanner (Gyeonggi-do, South Korea) with a 3.5-MHz convex-array transducer. The placental thickness was measured by placing the ultrasound transducer perpendicularly to the plane of the placenta, in the area of the cord insertion, near the mid-placental portion as described by Hoddick et al.12. Each evaluation was performed by one of two experienced sonographers of our hospital with minimum inter- and intra-observer variability.
Results were given as mean plus or minus SD. Statistical analysis was performed using the SPSS 16.0 statistical software package (SPSS Inc., Chicago, IL, USA) using One-way ANOVA and one-way repeated measures ANOVA tests. Pearson's correlation analysis was used to establish the degree of relationship between placental thickness and birth and placental weights. P values of less than 0.05 were considered statistically significant.
Results
Of 250 recruited participants who fulfilled the entry criteria, 205 women were able to complete the study and their data were included in the final analyses. The mean age of the entire group was 26.4±5.1 (range 16 to 42 years). Table 1 provides a summary of the baseline characteristics of pregnant women at first visit. Thirty seven (18%) mothers had history of previous disease including diabetes, hypertension, thyroid disease and infertility. Two cases of intrauterine fetal demise were occurred in the study group. No cases of hydrops fetalis or a specific infectious disease (syphilis, cytomegalovirus infection, toxoplasmosis, schistosomiasis) were reported.
Mean±SD of gestational age was 268.2±22.3 days. Values of mean birth and placental weights were 3,051.5±657.0 and 551.7±104.8 grams respectively. The percentage of macrosomia (>4,000 g) and low birth weight (<2,500 g) neonates at delivery were 2.5 and 14.6% respectively. The delivery mode was normal vaginal (NVD) in 121 women (59%) and cesarean in 84 cases (41%). Baby Apgar score of less than 3, 3 to 7 and greater than 7 were observed in 4 (2%), 19 (9.3%) and 182 (88.7%) newborns respectively.
Ultrasonographic measures of placental thickness in second and third trimester and changes between them were 21.6±4.5 (range: 14.9-35 mm), 36.2±6.4 (range: 20-79 mm) and 14.67±5.67 mm respectively. There was a significant positive correlation between placental thickness and birth weight in the second and third trimesters (r=0.15, p=0.03; r=0.14, p=0.04 correspondingly) (Figures 1 and 2). However, no correlation was observed with placental thickness change (p=0.7). Placental weight did not correlate with both second and third trimester's placental thickness (r=0.005, p=0.9; r=0.003, p=0.9 respectively).
On the other hand, placental thickness change was related to mother's age, weight and height (r=0.2, p=0.003; r=0.16, p=0.02; r=0.14, p=0.04 respectively). As it can be observed in the Table 2, mothers with gestational age less than 36 weeks, age greater than 40 years, history of diabetes or thyroid disease and suffering from ITP or preeclampsia had thicker placenta in the third trimester. This pattern was also observed for second trimester placental thickness but not for mother age. Placental thickness of second trimester were classified into 3 sub-groups of <17, 17 - 27 and >27 mm (based on ROC-curve). Evaluation of birth weight in these sub-groups shows a significant lower birth weight in the thickest sub-group (3,100.1±565.6 g in thickness of <17 mm, 3,176.6±626.1 gr in thickness of 17 - 27 mm and 2,714.2±919.6 gr in thickness of >27 mm [p=0.005]). Also, this pattern was observed in placental thickness of third trimester (2,966.9±845.6 g in thickness of <30 mm, 3,195.8±410.5 gr in thickness of 30 - 40 mm and 2,828.5±580.9 g in thickness of >40 mm [p= 0.001]).
Discussion
Several parameters were used to assess fetal growth in order to quantify intrauterine environmental adequacy and fetal well-being13-15. Normal placental function and structure is a necessary factor for the formation of a healthy fetus and consequently normal birth weight16. Early detection of any pathology in the placental bed and villi helps obstetrician to consider prenatal care precisely17. The rate of placental growth appears to be an important determinant of birth weight, with the rate between 17 and 20 weeks gestation being a predictor of fetal abdominal and head circumference, femoral length and biparietal diameter; weaker associations are observed for placental growth earlier in pregnancy18. Several aspects of placental growth including volume, weight, and plate area were investigated in different researches in order to find their correlation with fetal anthropometry2. For example, Clapp et al.9 evaluated placental growth of forty singleton pregnant women. They showed a significant correlation (r>0.79) between second-trimester placental growth rate and birth weight9. In study of Kinare et al.10, mid-pregnancy placental volume was related to birth weight. Correlation of placental thickness with gestational age and fetal growth was also reported in a research by Karthikeyan et al.19. Sonographic measurement of placental thickness is a relative simple and clinical useful way to detect 'early warning signs' which could be done in any unequipped obstetrician center20. Cooley et al.21 suggested that antenatal ultrasound of the placenta may aid detection of placental disease. They showed the placental thickness in the second trimester was less in pregnant women complicated by chorioamnionitis21. Unfortunately, even sonologists make limited attention to placental thickness in their routine evaluation of pregnancy20. In a research held in Nigeria, significant positive correlation were found between placental thickness and estimated fetal weight in the second and third trimesters (r=0.61 and r=0.57 respectively)22.
In contrary to some other researches, our study evaluates both second and third trimester's placental thickness and their relationship with birth weight in a prospective longitudinal model. A weak but positive correlation between placental thickness and birth weight in the second as well as third trimesters was observed accordingly.
Many pathological conditions could induce placentomegaly a result of inflammation, edema, or compensatory hypertrophy6. This subject was observed in our cases, as mothers with gestational age less than 36 weeks, history of diabetes or thyroid disease and suffering from ITP or preeclampsia had thicker mean placenta in both trimesters. In a study by Elchalal et al.6 a linear increase of placental thickness was found to correlate with gestational age throughout pregnancy. They also showed a higher percentage of thick placenta in birth weight at term above 4,000 g or less than 2,500 g. However, they did not find any difference between patients with thick placenta and control group in terms of diabetes and hypertension. The authors insisted that increased placental thickness is not diagnostic of any specific disorder but may contribute to the management of a fetus at risk6. As it was shown in our study, patients with ITP or preeclampsia had thicker placenta in comparison with normal pregnant women. This observation was similar to the reports of previous studies23,24. Raio et al.25 stated that abnormally thick placentas have been correlated with adverse pregnancy outcome. Also, more frequent thick placentas in cases with absent end-diastolic umbilical arterial flow were found. It seems that intervillous perfused more slowly when the villous tree is too complex or too dense26. Recently, investigators are trying to increase detection rate of early sign for impaired placentation by combination of ultrasound findings with placental hormones such as human chorionic gonadotrophin (hCG), progesterone and pregnancy associated placenta protein A (PAPP-A)1. Ultrastructural study of Macara et al.27 of placenta indicates that thickening of the basal lamina and increased deposition of collagen and laminin together with congestion of the capillaries by erythrocytes is the cause of limited oxygen transfer from the intervillous space to the growth retarded fetus. In a recent study, investigators proposed that sonographic increment of placental thickness during second trimester is due to over-inflation of the intervillous space by maternal blood rather than by adaptive formation of functional placental tissue28.
Definition of placentomegaly was different in various reports on the basis of gestational age, measurement technique and feto-maternal condition during pregnancy. Elchalal et al.6 defined a thick placenta (above 90th percentile) as thicker than 35 mm, when measured between 20 and 22 gestational weeks, and as thicker than 51 mm between 32 and 34 gestational weeks6. Dombrowski et al.24 used cut off at least 4 cm to diagnose thick placenta in a representative portion perpendicular to the chorionic plate. Habib16 used placental thickness of less than 2 cm at 36 weeks' gestation as a sensitive cut-off point for detecting low birth weight infants. A placental thickness more than 40 mm at term is associated with gestational diabetes, intrauterine infections and hydrops fetalis29. La Torre et al.30 opined that at no stage of pregnancy placental thickness exceeded 40 mm indirectly, thus indicating the cut off value for the upper limit. According to the present study, mother with placental thickness of more than 27 mm in second trimester and more than 37 mm in third trimester bear smaller babies. On the basis of the findings of this longitudinal research, it seems that using cut points for placental thickness can help obstetrician to predict newborn birth weight and identify the fetus in danger of being low birth weight. However, we realize that the study could have some weaknesses. The main bias is that the study has low number of patients. Hence, we recommend evaluation of these parameters with more subjects to find this cut point with more power.
Received 06/18/2013
Accepted with modifications 07/12/2013
Conflict of interests: none.