Introduction
A miscarriage is a pregnancy that ends spontaneously before the fetus reaches a gestational age that enables it to be viable1. The incidence of spontaneous miscarriages is estimated to be between 10-20% of all clinically recognized pregnancies1,2. However, the real incidence is very difficult to establish since those that occur very early generally go unnoticed1,2.
It has been estimated that 85% of spontaneous miscarriages occur in the first trimester2,3. Early pregnancy loss that occurs in the first twelve weeks of gestation is defined as a nonviable intrauterine pregnancy, and clear sonographic criteria have been established for such a diagnosis in both symptomatic and asymptomatic women3,4.
The exact reason why miscarriage occurs is still a matter of debate and in many cases a single cause for this outcome remains unidentified. Some authors state that one third of miscarriages are due to chromosomal abnormalities and that two thirds of pregnancy failures are due to improper implantation of the embryo5. However, in very early pregnancy, chromosomal abnormalities are much more frequent6.
Threatened abortion is one of the most frequent clinical situations in Gynecology and Obstetrics emergency services, occurring in approximately 20-30% of pregnancies2. Clinically speaking, threatened abortion is characterized by genital bleeding or hemorrhage of variable intensity from the uterine cavity, which may or may not be associated with mild-moderate pain in a woman with amenorrhea and a positive pregnancy test, with live or potentially alive fetus/embryo7. First trimester bleeding may be a marker of incorrect embryo implantation and incorrect placental development7.
Management of this clinical situation currently involves several medical visits before establishing the definitive diagnosis and prognosis, and this process entails a substantial consumption of health resources1. Currently, a correct clinical history, physical examination, transvaginal ultrasound and, if necessary, single or serial assays of β-hCG in blood are performed4. The β-hCG duplication test requires two clinical visits in a very specific time window; in addition, this test has a limited sensitivity of 62% - 78% and a false positive rate of 26 to 40%8-11
A variant form of hCG is the so-called hyperglycosylated hCG (hCG-H), which differs from hCG in terms of its site of synthesis, molecular structure, and function12-17. Hyperglycosylated hCG originates from placental extravillous cytotrophoblast cells in an autocrine manner18,19and has a more complex structure than hCG20,21.
Hyperglycosylated hCG is the predominant isoform in the first weeks of gestation. It represents 80% of the hCG produced in the first week after implantation, it makes up 92% of the total hCG at three weeks of gestation and is gradually replaced by other isoforms22,23. The presence of hCG-H in early pregnancy is related to the process of implantation and invasiveness of trophoblast cells24,25. Hyperglycosylated hCG has been shown to antagonize receptor II of TGF beta, blocking cellular regulation, reducing apoptosis in cytotrophoblastic cells, promoting growth and invasion of cells in the cytotrophoblast26,27. An imbalance in hCG-H values may be the cause of pregnancy failure, since some studies have shown that excessively low proportions of hCG-H are observed in miscarriages28. However, evidence about the role of hCG-H in predicting pregnancy outcomes in first-trimester threatened abortion is still scanty.
In this study we hypothesized that hCG-H can predict pregnancy outcomes in first-trimester threatened abortion viable pregnancies. We therefore set out to investigate the value of a single determination of hCG-H for predicting the clinical outcome of patients with threatened abortion in the first trimester of pregnancy.
Methods
The study was prospective. The individuals selected as eligible for the research process were women with a diagnosis of threatened abortion in the first trimester of pregnancy (4-12 weeks) who attended the Emergency Room (ER) of the Clinica Universidad de Navarra (CUN) or the Complejo Hospitalario de Navarra (CHN) from June 2016 to March 2018. STROBE guidelines were followed.
Inclusion criteria were as follows: 1) patients with a positive urine pregnancy test at home with gestational amenorrhea ≤ 12 weeks and with knowledge of the date of the last menstrual period; 2) spontaneous pregnancy; 3) viable pregnancies from detection of embryo heart activity, crump-rump length < 7 mm, visible heart activity was not required3,4; 4) clinically stable patients at the time of initial diagnosis without exacerbations at the clinic that forced us to perform urgent clinical interventions; 5) written informed consent provided.
Exclusion criteria were as follows: 1) patients who were diagnosed on the first ultrasound evaluation with a gestation of undetermined location or an ectopic gestation; 2) multiple gestation at diagnosis or detected at follow-up scan; 3) gestational trophoblastic disease; 4) diagnosis of aneuploidy; 5) assisted reproductive technique used as a conception method; 6) patients with a personal history of hypertension or diabetes mellitus.
The main outcome sought in the analysis was the occurrence of miscarriage before the twentieth week of gestation (yes/no).
All patients recruited were centralized at CUN, where the first assessment was carried out in the first 12-24 hours after diagnosis in the ER. The following variables were collected: patients’ age (years), body mass index (BMI, kg/m2), gestational age at presentation (days) according to last menstrual date, and previous pregnancies, deliveries and abortions. A single blood sample was drawn (10 ml of blood to obtain four aliquots) and stored at -80ºC at the Department of Biochemistry of the CUN, which kept the samples until the deferred determination of HCG and hCG-H (mUI/mL). This determination was made once all the patients had been recruited. Total hCG levels along with the β subunit were analyzed in all serum samples using an automated electrochemiluminescence immunoassay (Cobas 8000, Roche) and hCG-H using a commercial ELISA (MybioSource). For this analysis, the guidelines provided by the manufacturing laboratory were followed.
In addition, a first transvaginal ultrasound evaluation was performed, using two ultrasound machines equipped with a 5-9 MHz vaginal probe (Voluson E10 and E8, General Electric Healthcare, Milwaukee, WI, USA). The uterus and adnexa were examined and measured. Gestational sac diameters and volume were measured. The presence or absence of the yolk sac and/or embryo was determined. If the embryo was present, the crown-rump length (CRL) was measured and heartbeat was noted. If heartbeat was present or the embryo had a CRL < 7mm but the heartbeat was not observed the patient was included. If the embryo’s CRL was ≥ 7mm and heartbeat was negative, miscarriage was confirmed and the patient was excluded. The gestational sac volume was estimated using the Volume Organ Computer Aided analysis (VOCALTM) method using the 4D-View software (General Electric Healthcare, Zipf, Austria) as per a previously described technique29. The same examiner (AS) performed all ultrasound examinations, measurements and volume calculations.
During this first visit, the patient received verbal and written information regarding all the pertinent aspects of the study. If she decided to enter the study, she had to sign an informed consent. Institutional Review Board approval was obtained before starting the study from both participating institutions (CUN and CHN).
The patients were reassessed clinically within two weeks after the diagnosis of threatened abortion. If the patient presented with heavy bleeding beforehand, she was reassessed earlier. In all cases, an ultrasound scan was performed to confirm the viability of pregnancy. From then on a weekly follow-up by telephone was also carried out until the twentieth week of gestation.
The patients were clinically managed by the relevant center (CUN or CHN) as per the local protocol. Clinicians managing the patients did not have information about the hCG- levels.
The clinical, laboratory and ultrasound data obtained from the patients were included in a database designed for this purpose. The Kolmogorov-Smirnov test was used to assess normal distribution of continuous data. Data are expressed as mean with standard deviation (SD) or median with interquartile range (IQR) depending on data distribution. The categorical variables were presented as absolute number and percentage.
Continuous variables were compared using the t-test or the Mann-Whitney test depending on the distribution. Categorical variables were compared using the chi-squared test. The rho (r) Spearman correlation coefficient was used to analyze the correlation between hCG-H and total hCG and patient’s age, gestational age and sac volume.
We carried out linear and quadratic regression analysis to establish the ratio of hCG-H and total hCG with gestational age in normal outcome. The best curve to fit was chosen according to the highest R2, all coefficients that were different from zero, and the least residuals. We then compared the data from patients with normal outcome and patients whose pregnancies ended in miscarriage with an analysis of covariance, taking into account the gestational age as a co-variable. We used logarithmic transformation of absolute values of hCG-H and total hCG.
Receiver operating characteristics (ROC) curves were plotted to determine the best total hCG and hCG-H cut-off for predicting pregnancy outcome. The corresponding area under the curve (AUC) of the ROC curve was estimated and compared using Hanley’s method. We set out to determine whether the ratio of hCG-H/total hCG is a better predictor than a single H-hCG determination, as a number of authors have proposed12. Therefore, the ROC curve for hCG-H/total hCG was also plotted and the AUC was estimated. A sub-analysis was performed, comparing the area under the curve of the ROC curve of total hCG, hCG-H and hCG-H/total hCG ratio in the women who had a living embryo with threatened abortion at the time of presentation.
All statistical analyses were carried out with the Statistical Package for the Social Sciences (SPSS) program, version 20.0. (SPSS Inc.; Chicago, IL). A p value < 0.05 as statistically significant was used in all tests.
Results
Eighty-six patients were recruited during the study period, all with a diagnosis of threatened first trimester miscarriage and potentially viable or viable pregnancy. The outcome was obtained in all cases.
Forty-three women (50%) had an ongoing normal pregnancy at the twentieth week of gestation and forty-three (50%) ended in miscarriage before the twentieth week of gestation. Figure 1 shows the patients’ flow chart.
The mean age of the patients was 34 years (SD: 4.71), which was slightly higher in patients whose pregnancies ended in miscarriage (Table 1). The mean values of BMI, gestational age, number of previous gestations and previous abortions were similar between both groups of patients. Patients whose pregnancies ended in miscarriage had had less previous deliveries.
Characteristics | Global | Normal outcome | Miscarriage | p |
---|---|---|---|---|
Age (years) | 34 (4.71) | 33.0 (4.1) | 35.1 (5-1) | 0.046 |
BMI (kg/m2) | 22.9 (4.3) | 22.9 (4.0) | 23.1 (4.5) | 0.786 |
Gestational age (days) | 50.3 (11.2) | 52.3 (11.9) | 48.3 (10.3) | 0.103 |
Number of previous pregnancies | 2.53 (1.73) | 2.51 (1.9) | 2.6 (1.6) | 0.902 |
Number of previous deliveries* | 0.47 (0.84) | 0.7 (1.0) | 0.3 (0.5) | 0.037 |
Number of pevious abortions | 0.88 1.15) | 0.7 (0.9) | 1.0 (1.3) | 0.135 |
All characteristics were expressed as mean (SD) except *: median (IQR). All p-values were obtained from t-test except †: Mann Whitney U.
Median hCG-H and total hCG from the pregnancies with a normal outcome was significantly higher than the ones that ended in miscarriage (Table 2, Fig. 2).
Data | Normal Outcome | Miscarriage | p |
---|---|---|---|
Total hCH (UI/nL) | 62,929 (65,498) | 2,850 (13,576) | < 0.001 |
hCG-H (UI/mL) | 5,489.4 (5,008.1) | 1,889.2 (1,207.9) | < 0.001 |
Ratio hCG-H/hCG | 8.9 (2.6) | 7.8 (4.1) | < 0.001 |
All data were expressed as median (IQR); all p-values were obtained from Mann Whitney U test.
We observed a significant correlation between gestational age and hCG-H (r = 0.58, p <0.001) and total hCG (r = 0.62, p < 0.001). We also observed a very high correlation between hCG-H and total hCG (r = 0.91, p < 0.001). We also found a significant correlation between gestational sac volume and hCG-H (r = 0.69, p <0.001) and total hCG (r = 0.78, p <0.001). However, we saw that there was no relationship between patient’s age and hCG-H (r = -0.28, p = 0.72) or total hCG (r = -0.13, p = 0.42).
ROC curve analysis showed that the best cut-off of hCG-H and total hCG for predicting pregnancy outcome were 2,698 mIU/mL and 28,880 mIU/mL, respectively. The AUCs for both parameters were very similar (AUC = 0.90, 95%CI: 0.84-0.97 vs. AUC = 0.89, 95%CI: 0.81-0.96; p=0.891). The hCG-H/total hCG ratio was a poor predictor for pregnancy outcome (AUC = 0.64, 95%CI: 0-52-0.76) (Fig. 3A).
When we considered only women who had a living embryo when they presented with threatened abortion, we observed that AUC for hCG-H (0.88, 95%CI: 0.78 to 0.98) and total hCG (0.85, 95%CI: 0.73 to 0.97) were similar (Fig. 3B). Therefore, both parameters were predictors for pregnancy outcome with similar accuracy. The ratio hCG-H/total hCG was a poor predictor (AUC = 0.52, 95%CI: 0.36 to 0.68).
Discussion
In this study, we investigated the predictive value of a single hCG-H serum determination in patients with first-trimester threatened abortion and viable pregnancy at the time of presentation. We have found that hCG-H may be useful in predicting a pregnancy outcome. However, we observed that hCG-H was not a better predictor than hCG. The patient’s age was also related to the pregnancy outcome.
The main strength of our study is that, to the best of our knowledge, this is the first attempt to assess the role of hCG-H for predicting a pregnancy outcome in women with first-trimester threatened abortion and viable or potentially viable pregnancy. Some studies have reported on the role of hCG-H in predicting pregnancy outcome in early pregnancy, but not in the clinical scenario of threatened abortion.
Sutton-Riley et al published a study investigating whether hCG-H may predict gestation failure10. They assessed blood and urine samples from women in the first nine weeks of pregnancy and compared total hCG and hCG-H levels in normal and failing gestations (miscarriage and ectopic pregnancy). They found that hCG-H (threshold level of 13 µg/L) concentration in blood samples had a sensitivity of 73% with a false positive rate of 2.9% for detecting failing pregnancies. Sensitivity for hCG, using the same false positive rate, was 42%. For urine tests (using the same threshold level of 13 µg/L), these figures had a sensitivity of 75% with a false positive rate of 15% for detecting failing pregnancies for hCG-H, whereas sensitivity for hCG, using the same false positive rate (15%), was 43%. They concluded that a single hCG-H determination in early pregnancy was more accurate, simpler, and faster than standard hCG tests to predict a pregnancy outcome.
Cole reported on a series of 127 early pregnancies (81 normal term pregnancies, 18 miscarriages, and 28 biochemical pregnancies) who underwent urine hCG-H testing12. They found that hCG-H urine levels were significantly lower in failing pregnancies when compared to ongoing pregnancies.
Sasaki et al assessed whether the proportion of H-hCG produced at the time of implantation could predict pregnancy success in naturally conceived gestations22. They recruited 110 women who were attempting to achieve spontaneous pregnancy. Sixty-two women became pregnant (42 of them achieved full-term gestation and 20 were not evolutionary gestations). They observed that the ratio of hCG-H/total hCG in urine on the day of implantation (the day with hCG > 1 mUI/mL) was associated with the pregnancy outcome. This ratio was > 50% in all 42 pregnancies that came to term, but only in 35% of pregnancies that ended in miscarriage. They concluded that proportions of H-hCG/total hCG > 50% are required for the correct growth and invasion of cytotrophoblast at the time of implantation and a low proportion of H-hCG at the time of implantation may predict pregnancy failure.
More recently, Brady et al reported on a series of 115 women who became pregnant after IFV with blastocyst transfer23. They measured serum hCG-H measurement at eleven days after transfer, in order to assess whether hCG-H could predict the pregnancy outcome. Eighty-five pregnancies continued and thirty were failed pregnancies. These authors found that mean hCG-H and its ratio to total hCG were significantly higher in ongoing pregnancies as compared to failed pregnancies. However, hCG-H was not a better predictor than total hCG.
Our results match these studies inasmuch as hCG-H can predict pregnancy outcomes. However, we observed that the hCG-H/total hCG ratio is not a good predictor. This latter finding might be explained by the fact that we focused on women with first-trimester threatened abortion and viable pregnancy at the time of presentation, in naturally conceived pregnancies.
An interesting question to consider is whether these findings could be related to the fact that an actual miscarriage has already happened. However, in our sub-analysis that included only cases with living embryos at the time of clinical presentation, we observe similar results to those for the whole series. This certainly means that early placentas from living embryos in cases of threatened abortion that end in miscarriage release significantly lower amounts of both total hCG and hCG-H, indicating a potential maldevelopment of early sincytotrophoblast that could explain pregnancy outcome.
We think our data might be clinically valuable since we provide new information related to a specific clinical setting. However, we acknowledge that our study has several limitations.
Such limitations include a small sample size. This means that our results should be regarded as preliminary in nature. On the other hand, we observed a miscarriage rate in women with a living embryo as high as 35% (20 cases out of 57), which is substantially higher than expected. Therefore, a potential bias might exist in our study. In addition, we did not perform sample size calculation, so we do not know the statistical power of our findings.
A single hCG-H determination is helpful in predicting pregnancy outcomes in women with first-trimester threatened abortion and viable or potentially viable pregnancy at the time of presentation. hCG-H is not a better predictor than total hCG. However, as we consider our data to be preliminary, further studies are needed to confirm these findings.