Microchimerism in the transfused obstetric population

Prevalence of donor white blood cell survival (Transfusion-Associated Microchimerism) in a cohort of older Australians

OBJECTIVE

Donor leucocyte survival, known as transfusion-associated microchimerism (TAM), following red blood cell (RBC) transfusion has been detected in adult trauma patients. Analysis of TAM prevalence in other cohorts has not been extensively analysed. The study aims to assess TAM prevalence in participants of a large ongoing Australian health and ageing study.

MATERIAL AND METHODS

Participants from The Sax Institute's 45 and Up Study who had been identified as being transfused with at least one RBC unit using data linkage (n = 350) were approached between 8 February-8 December 2022 to provide blood samples for TAM analysis. Analysis of TAM was conducted using real-time PCR analysis with a panel of 12 biallelic insertion/deletion sequences.

RESULTS

Of the approached participants, 72 (55 males and 17 females) provided blood samples for analysis. The reason for RBC transfusion included trauma (n = 7), cancer treatment (n = 13), anaemia (n = 23) or surgery/other (n = 29). PCR results from 2 male and 9 female participants indicated potential TAM. Participants with potential TAM self-reported poor health (40.0 %) compared with those who did not have microchimerism detected (11.9 %). However, there were no significant differences in general practitioner visits, prescriptions filled or hospital admissions.

CONCLUSION

The prevalence of TAM in male participants in this small longitudinal cohort was lower compared to previous trauma studies. In female participants, 52.9 % indicated potential TAM, however naturally occurring sources of microchimerism remain possible. No direct long-term consequences related to potential TAM could be identified except poor self-reported health.

The incidence of donor white blood cell survival (transfusion-associated microchimerism) in Australian pediatric patients

INTRODUCTION

Donor leucocyte survival following red blood cell (RBC) transfusion, known as transfusion-associated microchimerism (TAM), can occur in some patients. In Australia, despite the introduction of leucocyte filtration (leucodepletion) during RBC manufacture, TAM has been detected in adult trauma patients. However, the incidence of TAM in Australian pediatric patients has not been analyzed.

METHODS

Patients aged 0-16 years were recruited across two cohorts. Retrospective participants had RBC transfusion between January 1, 2002 and November 15, 2017 and prospective participants received RBC transfusion between December 1, 2016 and November 25, 2020. Twelve bi-allelic insertion/deletion (InDel) polymorphisms were used to detect microchimerism amplification patterns using real-time PCR (RT-PCR) and droplet digital PCR (ddPCR).

RESULTS

Of the retrospective cohort (n = 40), six patients showed amplification of InDel sequences indicating potential microchimerism. For three patients, minor InDel sequences were detected using RT-PCR only, two patients had minor InDel amplification using ddPCR only, and one patient had minor InDel amplification that was confirmed using both techniques. Amplification of minor sequences occurred in three patients who had received a bone marrow transplant in addition to RBC transfusion. In the prospective cohort (n = 25), no InDel amplification indicating potential microchimerism was detected using RT-PCR.

DISCUSSION

Cell-based therapies had been administered in three patients where microchimerism amplification patterns were detected. Three patients have microchimerism that may be attributed to RBC transfusion. In prospective patients, who received leucodepleted and gamma-irradiated RBC units, no potential microchimerism amplification were detected. ddPCR may be a suitable technique for TAM analysis but requires further evaluation.

Lack of persistent microchimerism in contemporary transfused trauma patients

BACKGROUND

Following transfusion, donor white blood cells (WBCs) can persist long-term in the recipient, a phenomenon termed transfusion-associated microchimerism (TA-MC). Prior studies suggest TA-MC is limited to transfusion following traumatic injury, and is not prevented by leukoreduction.

STUDY DESIGN AND METHODS

We conducted a prospective cohort study at a major trauma center to evaluate TA-MC following injury. Index samples were collected upon arrival, prior to transfusion. Follow-up samples were collected at intervals up to one year, and beyond for those testing positive for TA-MC. TA-MC was detected by real-time quantitative allele-specific polymerase chain reaction assays at the HLA-DR locus and several polymorphic insertion deletion sites screening for non-recipient alleles.

RESULTS

A total of 378 trauma patients were enrolled (324 transfused cases and 54 non-transfused controls). Mean age was 42 ± 18 years, 74% were male, and 80% were injured by blunt mechanism. Mean Injury Severity Score was 20 ± 12. Among transfused patients, the median (interquartile range) number of red cell units transfused was 6 (3,12), and median time to first transfusion was 9 (0.8,45) hours. Only one case of long-term TA-MC was confirmed in our cohort. We detected short-term TA-MC in 6.5% of transfused subjects and 5.6% on non-transfused controls.

CONCLUSIONS

In contrast to earlier studies, persistent TA-MC was not observed in our cohort of trauma subjects. Short-term TA-MC was detected, but at a lower frequency than previously observed, and rates were not significantly different than what was observed in non-transfused controls. The reduction in TA-MC occurrence may be attributable to changes in leukoreduction or other blood processing methods.

Microchimerism in Ghanaian children recipients of whole blood transfusion for severe anaemia

BACKGROUND AND OBJECTIVES

Transfusion-acquired microchimerism (TA-Mc) has been reported in major trauma but not in young children despite relative immunodeficiency who, in sub-Saharan Africa, often suffer severe anaemia related to haemoglobinopathies or primary malaria infections. We examined the hypothesis that such massive red cell destructions might provide conditions favourable to TA-Mc, particularly when exposed to massive amounts of parasite antigens.

MATERIALS AND METHODS

Twenty-seven female children <5 years transfused with male whole blood for severe anaemia (13 with acute malaria and 14 with other causes) were retrospectively identified, and a blood sample was collected >6 months post-transfusion. Four whole blood samples from paediatric females transfused with blood from female donors and five secondary school female students never pregnant, never transfused were used as negative controls.

RESULTS

Nineteen patients (70%) carried male Mc with four (15%) having high levels of Mc (>100 genome equivalent of male cells/million of host cells) compared to three controls (37·5%). There was no difference in frequency or quantity of male Mc between paediatric patients with severe malaria and paediatric patients with other causes of severe anaemia. TA-Mc was not correlated with patient age, duration of whole blood storage or lymphocyte load transfused. After a median of 7 months post-transfusion, acute malaria did not increase the frequency of TA-Mc. One negative control appeared to carry low-level male cells.

CONCLUSION

Transfusion-acquired microchimerism appears frequent in young children transfused with whole blood for severe anaemia.