Background
Haemolytic disease of the foetus and newborn (HDFN) is the most common aetiology of haemolytic anaemia in foetuses and hyperbilirubinaemia in neonates[
1]. As the widespread prophylactic use of anti-D immunoglobulin has greatly decreased the incidence of Rh(D) alloimmunization from 16 to 0.3% in Western countries[
2,
3], the incidence of HDFN caused by non-Rh(D) antibodies has increased to 2.8‰~3.3‰[
4‐
6]. However, the incidence of anti-D-related HDFN still contributes to the morbidity and mortality of foetuses and newborns in China[
7]. A total of 60.8% of haemolytic disease is caused by anti-D, followed by anti-E, anti-c and antibodies in the MNS system, during the neonatal period[
8,
9]. Thus far, the distribution of non-ABO antibodies that cause haemolytic disease of the foetus (HDF) in China is not well known. In addition, some women have multiple red cell antibodies, which might lead to a more complicated situation during pregnancy management than when a single red cell antibody is present. Some studies have found that foetuses affected by multiple antibodies need more interventions than those affected by only anti-D[
10]. Thus, the objective of our study was to characterize the distribution of antibodies that cause HDF and to evaluate the effects of different antibodies on the severity of HDF in a Chinese population.
Methods
Study population
This was a retrospective two-centre cohort study including pregnant women with non-ABO red cell alloimmunization and their foetuses in the First Affiliated Hospital and the Sixth Affiliated Hospital of Sun Yat-sen University from January 2005 to December 2019. All patients provided written informed consent for each medical intervention. The Guangzhou Blood Centre identified the antibodies responsible for red cell alloimmunization. We screened the alloantibodies in pregnant women based on the following criteria: (1) having Rh(D) negative phenotype; (2) having previous adverse pregnancy outcomes, including recurrent abortion, foetal demise, and hydrops fetalis; (3) identification of unexpected alloantibodies in ABO blood typing; and (4) having a previous history of blood transfusion. The commercial panel of reagent cells (Immucor, Norcross, GA, USA) with the saline tube test and an indirect antiglobulin test (IAT) with the DG Gel Coombs card (GRIFOLS, Barcelona, Spain) were used for antibody screening and identification. When immunoglobin M (IgM) alloantibody was detected, DTT (0.01 mol/L) was used to destroy the IgM antibody first and then IgG alloantibody was determined by IAT using the tube method. The titre of IgG was determined by the IAT method using the reagent cells in the DG Gel Coombs card (GRIFOLS, Barcelona, Spain) after incubation at 37 °C for 15 min. We included women with IgG red cell antibodies. For the women both had IgM and IgG, only the titre of IgG was recorded in this study. The antenatal diagnostic criteria for HDF were as follows: (1) the detection of non-ABO IgG antibodies in the maternal serum and corresponding maternal-foetal blood group incompatibility; (2) foetal anaemia confirmed by cordocentesis or an adverse pregnancy outcome, which included hydrops fetalis and foetal demise; and (3) a positive antibody elution test from foetal red blood cells (RBCs), which was direct evidence of causing haemolysis. In cases of missing values, treatment with intrauterine transfusion (IUT), hydrops fetalis and foetal demise were also considered as valid confirmation of clinically relevant HDF. We excluded women and their foetuses based on the following criteria: (1) the woman underwent termination of the pregnancy due to foetal structure or chromosome abnormalities; (2) a woman with alloimmunization had the same blood group phenotype as that of her foetus; (3) the woman had unknown antibodies; or (4) the woman was lost to follow-up. Stillbirth cases in this study did not include foetal death due to the discontinuation of treatment and induction of labour. Not all the data were available for each case.
Data collection
Data on the maternal obstetric history, blood transfusion history, type of alloimmunization, presence or absence of hydrops fetalis, and foetal sex were collected. For the anaemic foetuses, we further collected data on the gestational age at the time of diagnosis of HDF; foetal haemoglobin levels, haematocrit levels, reticulocyte counts, and reticulocyte percent before IUT; the number of IUTs; and foetal outcomes. Women who underwent antibody detection multiple times during the same pregnancy were included as a single entry, and the highest titre was recorded during the whole pregnancy. For the women with multiple antibodies, we recorded the titres of all types of antibodies and used the highest titre into analysis. Regarding the women who were pregnant more than once during the study period, each pregnancy was included in our report. To determine the effects of different alloimmunizations, the patients were classified into four groups according to their antibodies, namely, only anti-D (anti-D group), anti-D combined with other antibodies (anti-D combined with others group), other single-antibody (other single-antibody group) and other multiple antibodies (other multiple antibodies group).
Definition and treatment policy
A previously affected history was defined by the existence of a previous perinatal loss related to HDFN, a previous need for IUT, or a previous need for neonatal exchange transfusion[
11]. Foetal outcomes were defined as the survival of the foetuses and the gestational age at birth.
Foetal anaemia was confirmed by cordocentesis, and the severity of foetal anaemia was categorized based on the haemoglobin concentration expressed as a multiple of the median (MoM) for gestational age as follows: mild (0.83 − 0.65 MoM), moderate (0.64 − 0.55 MoM), and severe (< 0.55 MoM)[
12]. The indication for an IUT was a foetal haematocrit less than 30% [
11].
Primary and secondary outcomes
The primary outcome was the occurrence of severe HDF, which was defined as severe foetal anaemia, hydrops foetalis, stillbirth, or the need for IUT due to maternal alloimmunization[
1]. The secondary outcomes were the number of IUTs, the severity of foetal anaemia and the outcomes of the foetuses.
Statistics analysis
Statistical analysis was performed using SPSS 22.0 statistical software. Quantitative variables are expressed as the medians with the 25th and 75th quartiles or the means with their standard deviations. Chi-square tests or Fisher’s exact tests were used for distribution-based comparisons between groups. The t-test was used when the values were normally distributed, while the Mann-Whitney U test was applied when the values were nonnormally distributed. The potential risk factors for HDF in foetuses with maternal alloimmunization, including previously affected pregnancies per woman, maternal transfusion history, maternal antibody titre, maternal-foetal major ABO incompatibility and the types of maternal antibodies were analysed by logistic regression analysis. The potential risk factors for severe HDF in foetuses with Rh(D) alloimmunization, including foetal sex, maternal antibody titre, gestational age at diagnosis, reticulocyte count and combination of maternal anti-D with other antibodies, were also included in the multiple variable analysis. The results are presented as p values, and a two-sided p value < 0.05 was regarded as statistically significant. The odds ratios (ORs) with 95% confidence intervals (95% CIs) are also presented in regression analysis. The Kaplan-Meier survival analysis of the survival time free from severe HDF is presented. To determine the short-term differences in this interval between groups, the Breslow method was used. The survival curve was generated by GraphPad Prism 5.0.
Discussion
The distribution of maternal alloimmunization and HDFN varies in different countries and populations[
7,
13]. Thus far, the distribution of HDF antibodies in the Chinese population has not been reported. In Guangdong Province of China, the percentage of pregnant women with red cell alloimmunization was 0.27%~1.05%[
14]. In our study, we analysed 268 pregnant women with red cell alloimmunization and their foetuses, including 122 foetuses with haemolytic disease, to characterize the antibody distribution of HDF in a Chinese population. Anti-D was still the most common cause of HDF (67.2%, 82/122). However, in our study, no case of HDF due to isolated anti-c was found, which is the secondary cause of severe HDF after anti-D in the Caucasian population[
15]. The difference might be due to the significantly lower frequency of the c antigen in the Chinese population than in the Caucasian population[
16]. Similarly, there was no case of anti-K HDF detected in our study, nor were there any women who were positive for the anti-K antibody. Due to the extremely low frequency of the K antigen in the Kell blood group system in the Chinese population, anti-K antibody positivity is extremely rare[
7], and anti-K-related HDN has rarely been reported[
17]. Therefore, the distribution of HDF-associated antibodies in the Chinese population is different from that in the Caucasian population.
Moreover, we found that anti-M was the most common non-Rh(D) antibody, accounting for 55.5% of the incidence of HDF (10/18). Very few reports have causally linked anti-M antibody positivity with HDFN in a Caucasian population[
18]. Over the past two decades, anti-M-related HDFN has mostly been reported in Asian ethnic groups, especially in Japanese[
19] and Chinese populations[
20,
21], and it has been reported to result in severe foetal anaemia, hydrops fetalis, stillbirth and neonatal death. A previous study found that 88.6% of anti-M-related HDFN cases occurred in Asian populations[
21], indicating the high pathogenicity of IgG anti-M in Chinese people. Even though our tertiary prenatal centre provided a relatively higher incidence of HDF due to anti-M, our results suggested that the risk of anti-M-associated severe HDFN in the Chinese population might be high, with 60.0% (6/10) receiving IUTs and 2 cases of intrauterine demise due to the lack of timely treatment. In addition, the antibody titre of anti-M was significantly lower than that of anti-D, indicating that anti-M can cause severe HDF even at low titres. The lower reticulocyte count indicated incompatible erythropoiesis with severe anaemia [
21], which was also found in neonatal cases[
19]. These results might be explained by the suppression of red cell development from erythroid precursor cells [
22,
23]. As a consequence, anti-M-related HDFN can have a negative result of direct anti-human globulin test (direct Coombs test) [
19], making the diagnosis of anti-M-related HDFN difficultly and often missed.
The presence of multiple antibodies seemed to increase the risk of HDF-associated morbidity without influencing the severity of foetal anaemia. The incidence of severe HDF was significantly higher when the pregnant women had anti-D combined with other antibodies, which was consistent with previous studies [
24‐
26]. However, after the logistic regression analysis, anti-D combined with other antibodies was not an independent risk factor for HDF. Moreover, among the anaemic foetuses, no significant difference was found in the foetal haemoglobin concentration or gestational age at diagnosis between the anti-D group and the anti-D combined with other antibodies group. The similar reticulocyte counts and percentages between these two groups indicated similar haematopoietic conditions. Some studies reported that neither the foetal anaemia severity nor the gestational age at first IUT was influenced by anti-D with other antibodies[
10,
27]. In the logistic regression analysis of anaemic foetuses affected by Rh(D) alloimmunization, anti-D combined with other antibodies was not a risk factor for severe HDF in either univariate analysis or multivariate analysis. These results indicated that the high incidence of HDF in the anti-D combined with other antibodies group was affected by other confounding factors. Furthermore, we also found that women with multiple antibodies had a higher rate of previous HDFN and more affected pregnancies than those with only anti-D. These results might suggest that the more often an Rh(D)-negative woman is exposed to an Rh(D)-incompatible foetus, the higher chances of generating additional antibodies are, leading to a more aggressive immune response and cumulative effect and increasing the risk of haemolysis and the chance of developing severe HDF. For the foetuses affected by maternal multiple antigens, 68.2% of the foetuses, those who identified other Rh blood group phenotypes, had cognate antigens. The additional antibody of the remaining cases might occur from previously affected pregnancy or the stimulation from nature. These further indicated as anti-D still played a dominant role in haemolysis, the severity of HDF was not significantly different regardless of whether anti-D was present alone or in combination with other antibodies. Therefore, when a pregnant woman has multiple antibodies and a history of multiple HDFN affected pregnancies, her foetus might have a higher risk of developing severe HDF and should be closely monitored during the antenatal period.
In the regression analysis, we found that a high maternal antibody titre, more previously affected pregnancies, and other single-antibody were independent risk factors for the occurrence of HDF. Even though in some alloimmunizations, a low antibody titre can cause severe HDFN[
28], a high titre suggests a more active immune response, increasing the risk of HDF. Moreover, a history of multiple affected pregnancies might result in the generation of a larger amount and longer duration of antibodies [
29], which can cross the placenta to cause the disease in the foetal period. In Rh(D) alloimmunization, once foetal anaemia occurred, the antibody titre could not predict the risk of severe HDF. A higher reticulocyte count was an independent risk factor for severe HDF. The more severe the anaemia and the more active the erythropoiesis were, the more severe the disease, indicating the need for intrauterine intervention. In the multivariable analysis, we also found that a transfusion history in the mother might be associated with HDF. According to the Technical Specifications of Clinical Blood Transfusion in China, no blood types other than ABO and Rh(D) are regularly detected before blood transfusion. Due to the scarcity of Rh(D) negative blood in China, Rh(D) negative individuals might receive Rh(D) positive red blood cells in some medical emergencies. As the volume of the blood transfusion is larger than the volume of foetomaternal haemorrhage and is enough to sensitize the individual[
29], sensitized women would develop more aggressive alloimmunization during pregnancy. Therefore, women with a previous blood transfusion history might have a higher risk of having a foetus with HDF.
The Kaplan-Meier analysis was conducted to determine the severe HDF-free interval and compare the intervals among groups with different antibodies, and the results provided a clinical reference to support the estimation of the gestational age at the onset of severe HDF and the appropriate time for clinical intervention. The significant difference in the median survival time among the groups indicated that the onset time of severe HDF varied based on the types of antibodies. The other single-antibody group had a significantly shorter survival time, providing evidence that foetuses affected by other single-antibody group, mainly anti-M, might develop severe HDF earlier than those affected by anti-D alone. This can be explained by the earlier development of antigens in the MNS system than in the Rh system during foetal development and erythropoiesis[
30].
There were still some limitations of our study. Our centre is a tertiary prenatal care centre, and the patients therein might have a higher risk for HDFN, more severe HDFN, and more severe associated complications. Therefore, the morbidity and mortality rates might be higher among patients in this study than among individuals throughout the country. Because of the insufficient sample size for specific non-anti-D antibodies, we could not compare the differences between specific antibodies, especially in terms of multiple other antibodies. As the inadequate realization of the maternal alloimmunization with multiple antibodies in the early stage of our centre, not all the foetuses were identified the non-Rh(D) blood phenotype, and gave a limited analysis for multiple maternal antibodies and foetal cognate antigens. What’s more, the survival curves between the anti-D and anti-D combined with other antibodies groups intersected, indicating that confounding factors might have affected the statistical results. As the period free from severe HDF can be influenced by the frequency of foetal investigations, gestational age at the time of prenatal consultation, and awareness of the disease, which varied over the 15-year period, the results of the Kaplan-Meier analysis may not be accurate for all antibody patterns. More prospective studies are needed for further accurate investigation on different alloimmunizations.
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