1. Introduction
Sickle cell disease (SCD) affects approximately 100,000 people in the United States and millions worldwide, with the highest prevalence of 70% of SCD being found in individuals of African ethnicity [
1,
2]. In Brazil, prevalence is discussed as a public health problem due to the prevalence of 2% to 8% in the population, and it is estimated that an average of 3500 children are born with SCD [
3,
4]. It is an autosomal recessive genetic disease caused by homozygosity of the beta-S allele (b
s), located on chromosome 11p15.5, which differs from the wild-type B allele by a single missense polymorphism, dbSNP rs334 (T; T), in which GTG is replaced by GAG in the sixth codon of the beta-globin gene. This leads to the replacement of the amino acid glutamic acid (Glu) by Valine (Val) in the sixth polypeptide chain, and the expression of mutated hemoglobin (Hb) HbS (alpha 2 beta S 2) in the red blood cells of individuals with SCD [
2,
5].
The pathophysiology of SCD is characterized by HbS polymerization, vessel occlusion, and hemolysis-mediated endothelial dysfunction, in addition to inflammation that leads to clinical disease, hemolytic anemia, and microvascular vaso-occlusion cycles leading to ischemia, target organ reperfusion, and infarction [
6]. Individuals with symptomatic SCD have chronic transfusion as a therapeutic measure, aiming at the replacement of erythrocyte concentration, hemoglobin, and blood volume. However, late reactions, such as alloimmunization, shorten the survival of transfused red blood cells due to the presence of alloantibodies, which adsorb around the red blood cells, destroying the cell membrane and causing a delayed hemolytic reaction (DHR). It is estimated that 1.6% to 11% of transfused patients with SCD develop overt transfusion reactions with increased fatigue, jaundice, dark urine, fever, and/or pain [
7,
8].
In Brazil, great racial miscegenation constitutes a major challenge for transfusion services regarding the availability of red blood cell concentrates with compatible erythrocyte antigens for multiple transfusion patients, such as in the case of sickle cell anemia. The risk of hemolytic transfusion reactions secondary to alloantibodies and the risk of iron overload and hyperhemolysis secondary to red blood cell transfusion are also weighed against the benefits of transfusion. Hyperhemolysis refers to the development of severe anemia in which the hemoglobin level after transfusion is lower than before, which may manifest immediately or later, being associated with a new alloantibody or a previous antibody that was not detected in the antibody screening. However, it may not be associated with an alloantibody [
9,
10].
The development of an alloantibody after transfusion may result in an alloimmunization reaction or a DHR. Epidemiological data from the American Blood Bank Association point to a risk of up to 70% of alloimmunization for blood group systems such as Rh, Kell, Kidd, Duffy, and MNS for patients with hemoglobinopathies, including SCD [
9]. Fever and anemia occurring days to weeks after transfusion of a red blood cell component characterize a delayed transfusion reaction, and the associated hemolysis is more prolonged than an acute hemolytic reaction and typically does not have the characteristic signs and symptoms, although some patients may develop jaundice and leukocytosis [
11]. In these cases, transfusion of phenotyped red blood cell concentrate to the main blood group systems Rh, Kell, Kidd, Duffy, and MNS is indicated, with the aim of preventing the alloimmunization reaction in polytransfused patients and facilitating the selection of blood components for those previously alloimmunized [
9,
12].
In the State of Amazonas, approximately 300 people live with SCD, and diagnosis and follow-up are provided by the Hospital Foundation of Hematology and Hemotherapy of Amazonas (HEMOAM), a reference unit for the diagnosis and treatment of blood diseases [
13]. Therefore, it is important to investigate the frequency of delayed alloimmunization and hemolysis reactions in patients with polytransfused SCD. The objective of this study was to characterize the immunohematological profile of DHR in patients with SCD who were polytransfused at HEMOAM.
2. Materials and Methods
2.1. Local Study
This study was carried out at the HEMOAM, which is a reference center for multidisciplinary follow-up of patients with sickle cell anemia, located in the city of Manaus, Amazonas, Brazil.
2.2. Ethical Aspects
This study was approved by the HEMOAM Research Ethics Committee through document 5.221.858 and Certificate of Presentation of Ethical Review 52069321.8.0000.0009, according to resolution 466/2012 of the National Health Council, which advocates the guidelines and Regulatory Norms for Research Involving Human Beings, including evidence that the research was conducted ethically in accordance with the World Medical Association’s Declaration of Helsinki. All participants signed the study consent form.
2.3. Study Participants
The participants were patients diagnosed with SCD expressing Hb SS with chronic transfusion of red blood cells (RBCs) as a therapeutic protocol, consisting of traditional and special blood components, as well as conjugated blood components such as filtered and irradiated red blood cell concentrate.
Chronic transfusion in study patients was indicated in cases of patient return after transfusion and verification of HB reduction to pre-transfusion levels, reticulopenia, an increase in spherocytes, a positive Direct Antiglobulin test, a reduction in haptoglobin, an increase in dehydrogenase lactic acid, an irregular positive antibody test, severe vaso-occlusive crises, and symptomatic anemia.
2.4. Inclusion and Exclusion Criteria
The inclusion criteria were patients with SCD of both sexes, who had received three or more units of RBC in a twelve-month period, and for whom data on the history of transfusions, previous and/or updated immunohematological, hematological, and biochemical data were available. Patients who did not comply with the transfusion schedule and those with incomplete records were excluded.
2.5. Participant Follow-Up
The initial approach to the patient was made at the time of waiting for the transfusion or at the time of the collection of pre-transfusion tests. After signing the informed consent form, a questionnaire was given to the participants with questions about sociodemographic data, transfusion history, and occurrence of previous transfusion reactions, which were later confirmed through the participants’ medical records. The patient’s identification number and the type of blood component received were also recorded.
Transfusions of a hemocomponent are completed within 4 h of the beginning of the transfusion, with a duration of 1–2 mL/min (60–120 mL/h). Patients with confirmed DHR status received a transfusion of 2 red blood cell concentrates within 24 h, according to the HEMOAM Transfusion Guide. If there are no clinical complaints 30 min after transfusion and if there are no clinical manifestations of transfusion reactions in subsequent routine visits, a new transfusion procedure will be scheduled for the participant. If there is an intercurrence reported by the patient, a medical investigation will be carried out by the blood center regarding the probable late transfusion reaction. Before the transfusion procedure, a new interview was conducted to verify the presence of complications reported by the patients, and when necessary, a new sample was collected for the comparison of pre- and post-transfusion parameters.
2.6. Phenotyping Procedures
Erythrocyte phenotyping: This was performed using the gel centrifugation technique (BioRad, Hercules, CA, USA), using antibodies to the main antigens of the Rh (D, C, c, E, e), Kell (K, k), Kidd (Jka, Jkb), Duffy (Fya, Fyb), and MNS (M, N, S, s) systems, as well as a sample of erythrocytes from the patient and donor, which was suspended in saline medium.
Detection and identification of unexpected antibodies: This was performed using plasma and screening red blood cells (BioRad) suspended in saline medium and incubated at different temperatures of 4 °C, Room Temperature (RT) (20–25 °C), and 37 °C, followed by an antiglobulin test. Tests at 4 °C and RT seek to detect all unexpected antibodies that act below 37 °C, which can cause a transfusion reaction in titers above 64. The 37 °C antiglobulin test seeks to detect potentially hemolytic antibodies. The identification of detected alloantibodies was performed by testing the patient’s plasma with a panel of 10 (BioRad) and 16 different vials of phenotyped red blood cells (Fresenius, Bad Homburg, Germany). When an antibody was detected, successive dilutions of the patient’s plasma were performed. The titers ranged from 1:2 to values greater than 1:1024, through the reading of the reaction intensity in crosses, which also allows the definition of scores that could differentiate concentrations of two alloantibodies with the same titer. Plasma treatment with Dithitreitol (DTT) was also performed to verify the class of the detected antibody, and an autocontrol test was performed to detect autoantibodies in addition to the alloantibody found. A direct antiglobulin test (DAT) was performed to detect the presence of antibodies and/or proteins of the complement system linked to the individual’s erythrocyte membrane, which may be allo- or autoantibodies originating from various immunological reaction processes. Cross-matching was performed using the indirect antiglobulin test (IAT) at 37 °C, using the patient’s plasma and the donor’s erythrocytes in order to detect potentially hemolytic antibodies.
Transfusional reactions definitions: An anamnesthetic response may be characterized by a negative IAT result on pretransfusion testing of the current transfusion; detection of alloantibodies within 30 days of the current transfusion; and observation of the presence of the same alloantibody detected in pre-transfusion tests from previous transfusions (confirmed by data recorded in Hemosys). Primary alloimmunization can be characterized by a negative IAT result in the pre-transfusion tests of the current transfusion; detection of alloantibodies within 30 days after the current transfusion; and observation of a negative IAT result in all pre-transfusion tests of previous transfusions (confirmed by the data recorded in Hemosys). For the analysis of the post-transfusion hemoglobin tests, the patients tested were distributed into the Confirmed, Possible, Probable, and Discarded DHR groups. Confirmed DHR occurs when a new antibody is identified between 24 h and 28 days after the transfusion and the transfusion carried out at the institution itself is the only possible cause for the appearance of irregular antibodies. Probable DHR occurs when the investigation has already been completed, or is still ongoing, presenting evidence (clinical/laboratory/temporal links) that indicates an association with transfusion; however, there are other causes that can explain the signs and symptoms. Possible DHR occurs when the investigation has already been completed, or is still ongoing, presenting evidence (clinical/laboratory/temporal links) that indicates the association of signs and symptoms to other causes; however, the association with the transfusion cannot be discarded. Discarded DHR occurs when the already completed investigation presents evidence (clinical/laboratory/temporal links) that clearly demonstrates the association of the adverse event to another cause(s) and not to the transfusion.
Compatibility Percentage Test: Compatibility was calculated through a test developed and validated for this study, which involved the offer of a bag with the same negative (compatible) antigens that the patient had, i.e., Rh (D, C, c, E, e); Kell (K, k); Kidd (Jka, Jkb); Duffy (Fya, Fyb); and MNS (M, N, S, s), comprising a total of 15 antigens. This test evaluates the percentage chance of the patient developing a delayed reaction to immunization from the moment he received any of these antigens that did not have them in the phenotyping. To calculate the percentage, the following formula was used: percentage of compatibility (%) = (number of negative antigens in the bag * 100)/number of negative antigens in the patient.
2.7. Data Analysis
Laboratory data and the clinical characteristics of the individuals in the study were recorded in spreadsheets prepared with Microsoft Excel 2020 (Microsoft Corporation) software. Statistical analysis was performed using the GraphPad Prism software (v.5.0). Numerical variables were expressed as mean ± standard deviation or median (confidence interval) due to the absence of normal distribution. Categorical variables were expressed as absolute value (n) and relative frequency (%). Statistical analysis between independent groups, qualitative variables, and continuous quantitative variables was performed using descriptive statistics.
4. Discussion
This study is the first to describe the immunohematological profile of delayed transfusion reactions in patients with SCD who received multiple transfusions at HEMOAM. It is important to note that all patients with sickle cell anemia treated at HEMOAM are phenotyped before the first transfusion for the Rh, Kell, Kidd, Duffy, and MNS systems. It turns out that we do not always have a donor phenotype available that is 100% identical to that of the patient, in addition to the need for extremely urgent transfusions.
In all 44 patients, Rh and Kell phenotyping was respected in the transfusions performed; however, three cases of alloimmunization with Rh system antibodies were observed, one being partial anti-RhD in a
RH variant patient, one being anti-E in a
RHCE variant patient with anti-e, and an anti-E in an anamnestic response in a patient who was urgently transfused in a city emergency room that did not have RBC phenotyped for transfusion compatible with the Rh system. An anti-K alloimmunization was also observed in an anamnestic response with the same situation mentioned above. Interestingly,
Figure 1 demonstrates that there was no statistical significance (
p > 0.05) between the confirmation of a delayed transfusion reaction and the percentage of compatibility, especially for antigens from the Kidd, Duffy, and MNS systems, clearly demonstrating their immunogenic capacity. However, we also observed two alloantibodies and three autoantibodies that could not be identified, and their specificities may be directed to antigens that were not within the scope of our phenotype panels or drug-induced antibodies.
The immunohematological characterization of SCD patients who presented delayed reactions can contribute to better pre-transfusion management, suggesting, for example, the profile of antigens that must be respected when using blood, when necessary. In this survey, it was possible to verify the complexity of the phenotypic frequency of the Rh system in this group of patients in the State of Amazonas, revealing that 26.6% of individuals have the RZRZ phenotype (DCE/DCE). It is known that there is great difficulty in performing compatible transfusions in the Rh system in these patients, since the state of Amazonas has a high frequency of blood donors with positive ‘e’ antigens (94.53%) and positive ‘c’ antigens (79.1%), according to the HEMOAM data center. In another study carried out in Brazil, it was found that among polytransfused sickle cell patients, the most frequent phenotype was R1r and R0R (41.0 and 20.8%, respectively), with 0% of RZRZ individuals [
16], suggesting that this profile may be characteristic of sickle cell patients from the Brazilian Amazon.
Furthermore, two patients (4.5%) were found with variants of
RHD and
RHCE, the first of which had partial anti-RhD, proven through the presence of anti-RhD in his plasma, although it has not been molecularly characterized to date. The second was identified with the variant
RHCE* Ce/
RhCE* ce genotype (733G), presenting auto-anti-e and anti-E and anti-Di
a alloantibodies. The second case demonstrates a special difficulty for transfusion since the patient presented anti-e and anti-E, with physicians recommending the transfusion of R1R1 red blood cells, opting for incompatibility with auto-anti-e and compatibility with the anti-E alloantibody and observing effective medical management as it was possible to observe a better use of the transfused red blood cells. Fasano et al. (2019), in a cohort study with 403 sickle cell patients, found RH1(D), 20.8% RH2(C), and 3.5% RH5(e), with the following respective frequencies of alloimmunization: 17.6% RhD variants, 14.3% C-variants, and 7.1% e-variants [
17]. In Ghana, research on 154 sickle cell patients aiming to find
RHD and
RHCE variants obtained results from three patients with multiple antibodies against Rh system antigens, such as anti-RhD, partial anti-RhD, anti-C, partial anti-C, and auto anti-e; these patients had positive RhD with
RHD and
RHCE deletion genotyping [
18].
In this study, the frequency of alloimmunization was 20.4% in the patients studied, with anti-E, anti-RhD variant, anti-K, anti-Jk
b, anti-N, anti-S, and anti-Di
a antibodies. In the study by Silvy et al. (2014), 33.5% of alloimmunization against the Rh system was described in 198 polytransfused patients [
19]. Boateng et al. (2019)’s study, conducted with 150 patients with SCD from Ghana, found a 25% frequency of alloimmunization of anti-RhD, anti-C, anti-E, and partial antibodies, detected through serological tests and confirmed through genotyping tests [
18]. In a study carried out in São Paulo, the presence of alloantibodies was detected in 22.6% of phenotyped sickle cell patients (N = 53), with Anti-K, Anti-C, and Anti-Di
a being the most common antibodies [
16]. In another study that evaluated alloimmunization in sickle cell patients in a hospital in the Federal District, the frequency of alloimmunization was 36.4% (28/77), with the main alloantibodies being reported against Rh (“C” and “E”) antigens and Kell antigens [
20]. In a cohort study performed with pediatric patients in sub-Saharan Africa, 16% presented positive irregular antibodies directed against the Rhesus (30.76%) and Kell (69.24%) blood group systems [
21]
In this study, 4/9 patients (44.4%) had anamnestic responses, i.e., they had previously identified alloantibody records, but these were not detected during pre-transfusion tests due to a drop in titration as the transfusions of packed red blood cells were negative for the antigen for which the patient had the antibody. These patients presented the previously recorded antibody again after transfusion within the follow-up of this study, characterizing an anamnestic response (ID-31 with anti-K, ID-74 with anti-RhD, ID-91 with anti-JKb, and ID-93 with anti-E). This happened due to an emergency transfusion outside of the coordinating blood center, in emergency services in the capital, demonstrating the need to implement a computerized system with information on previous transfusions to be verified in all transfusion services in the city with mandatory consultation of the patient’s history, i.e., whether they have an alloantibody and whether they have already had transfusion reactions so that a special, phenotyped, or even irradiated or filtered blood component can be provided. A total of 4/9 patients (44.4%) had their autoantibodies detected in addition to the identified allo antibodies, but three were not identified.
Fasano et al. (2019) confirmed this type of anamnestic reaction, describing that throughout some transfusions with negative antigens, this alloantibody remains without stimulation, reducing the titer to thresholds below the sensitivity of the antiglobulin reagent; thus, the unexpected antibody becomes undetectable [
17]. Andrade et al. (2022), in a study with 3178 patients treated at a blood center in Northeast Brazil, also described the presence of anti-Jkb (5%), anti-S (14%), and anti-Dia (29%) in anamnestic responses [
22].
Regarding the occurrence of delayed hemolytic reactions, in addition to immunohematological evidence, laboratory parameters were also evaluated. A frequency of 13.6% of DHR was identified in sickle cell patients, with a low increase in Hb in 54.5% of patients and high rates of LDH results in 31.8%, showing signs of extravascular hemolysis. These findings corroborate the results found by Gerritsma et al. (2021), who followed 664 patients with SCD in the Netherlands and found that 60% of patients fulfilled at least one of the criteria for DHR (Hb increase < 1.5 g/dL post-transfusion or Hb less than pre-transfusion, dark urine, altered LDH results, and recurrence of vaso-occlusive crises) during transfusion follow-up [
15].
One of the patients who had DHR and was followed up in the study had variant
RHCE, alloimmunization with auto anti-e and, later, anti-E and anti-Di
a, presenting intense pallor, dizziness, headache, and two episodes of dark urine 14 days after transfusion. A study conducted by Pirenne et al. (2018) described similar symptoms in DHR, such as fever, dizziness, vomiting, headache, jaundice of the skin and mucous membrane, and in severe cases, dark urine and convulsion [
23].