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Impact of ABO mismatching on the outcomes of allogeneic BMT: IPD based meta-analysis

Impact of ABO mismatching on the outcomes of allogeneic BMT: IPD based meta-analysis. Elianna Saidenberg November 2009. A brief introduction to HSCT. What is bone marrow? What are hematopoietic stem cells? What is the purpose of transplantation? Solid organ transplantation

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Impact of ABO mismatching on the outcomes of allogeneic BMT: IPD based meta-analysis

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  1. Impact of ABO mismatching on the outcomes of allogeneic BMT: IPD based meta-analysis Elianna Saidenberg November 2009

  2. A brief introduction to HSCT • What is bone marrow? • What are hematopoietic stem cells? • What is the purpose of transplantation? • Solid organ transplantation • For treatment of organ dysfunction or failure • Hematopoietic stem cell transplantation • High dose chemotherapy +/- radiation eradicate the malignant clone or abnormal marrow but also results in bone marrow ablation. Transplanted marrow repopulates the marrow with normal cells.

  3. Do these tissues match? • Major Histocompatibility Complex (MHC) and Human Leukocyte Antigens (HLA) • MHC genes (on chromosome 6) encode human leukocyte antigens and a variety of cell surface markers, antigen-presenting molecules, and other proteins which allow immune recognition of self and non-self • MHC genes are inherited as a group (haplotype), one from each parent. Thus, a heterozygous human inherits one paternal and one maternal haplotype, each containing three class-I (B, C and A) and three class II (DP, DQ and DR) loci

  4. Engraftment • Resumption of function by the transplanted organ or tissue • Rejection • A problem in solid organ transplant (rarely in BMT) • Host’s immune system recognizes transplanted organ as foreign and attacks it • “Host-versus-graft disease” • Graft-versus-host disease (GVHD) • A problem in BMT, never in SOT • Donor immune system recognizes all host tissues as foreign and attacks them • The closer the HLA match the less the risk of rejection and GVHD • Graft-versus-tumour effect • Donor immune system recognizes host’s tumour cells as foreign and removes them too

  5. You mean there is more than one kind of bone marrow transplant? • Syngeneic- From an identical twin • Allogeneic- From an HLA matched donor • MRD- Matched related donor • MUD- Matched unrelated donor • Autologous- Patients own stem cells are harvested before high dose chemotherapy and are later re-infused. • Not a curative therapy • Reduced intensity transplantation • Recipient bone marrow not completely ablated before transplantation of donor marrow • Relies on GVT effect

  6. You mean there are even more kinds of BMT? • Bone marrow source • HSC are harvested from a large bone of the donor, through a large needle that reaches the center of the bone, performed under general anesthesia • PBSCT • Donor stem cells harvested by apheresis procedure after G-CSF therapy to boost levels of peripheral blood stem cells • Umbilical cord blood • Cord blood has a higher concentration of HSC than is normally found in adult blood. Stem cells are harvested at time of delivery • Dose of stem cells low, adult cord blood BMTs usually requires 2 cords • Lesser degree of HLA matching possible compared to other sources of stem cells

  7. Causes of mortality and morbidity in BMT • Treatment related morbidity/mortality (TRM) • Chemotherapy/ radiation toxicities • Includes secondary malignancies • Complications related to cytopenias (infection, bleeding, anemia) • Veno-occlusive disease causing severe liver dysfunction • GVHD • AcuteGVHD occurs in the first 3 months after transplantation and may involve the skin, intestine, or the liver, and is often fatal. • Chronic GVHD is the major source of late treatment-related complication. Can lead to the development of fibrosis causing functional disability • High-dose corticosteroids are the mainstay of treatment but increase risk of infection • Drug side effects • Drugs needed to prevent GVHD include cyclosporine, MMF • All have serious side effects (ie HTN, ARF. TTP) • Disease relapse

  8. ABO incompatibility in BMT • Genes for ABO groups and for HLA are inherited independently • ABO incompatibility may occur in 20-40% of HLA-matched allogeneic SCT • ABO incompatibility between donor and recipient is NOT considered a contraindication to transplantation

  9. Major ABO Incompatibility • DonorABO antigens are not compatible with recipient’s immune system • Example: Donor is group A, recipient is group B or group O and hence has anti-A in his or her serum • Can have acute hemolysis due to lysis of incompatible RBCs contained in the graft • Purge grafts of RBCs • Plasmapheresis may be effective in reducing the anti-donor hemagglutinin in the recipient plasma with a goal to reduce the titer to 1:16 or lower • Known complications • Pure red cell aplasia • Delayed donor RBC engraftment • Anti-A and anti-B remain demonstrable in the recipient’s plasma for some months

  10. Minor ABO Incompatibility • Recipient ABO antigens are not compatible with donor’s immune system • Hence, the donor’s B cells capable of making antibodies directed at recipient’s RBCs • Hemolysis may develop 1-2 weeks after transplant • Due to lysis of ABO-incompatible recipient cells as the donor lymphocytes engraft • Reactions are most common and most severe when the donor is group O and the recipient group A

  11. Bidirectional Incompatibility • Recipient isohemagglutinins directed against donor RBCs and contrariwise • Occurs in 3-5% of alloSCT • Example: Donor is group A, recipient is group B • Potential complications • Hemolysis of RBCs in graft • Hemolysis of recipient RBCs by passively transfused antibody, • Hemolysis of RBCs produced by graft • PRCA

  12. Special considerations in ABO incompatible transplant: • During preparatory regimen transfused blood should be compatible with both donor and recipient • In bidirectional incompatibility (major-minor) only group O cells should be transfused • It may be prudent to give plasma reduced platelet transfusions • IVIg should be avoided during the post-transplant period as it contains variable titres of red cell antibodies (esp anti-A)

  13. The Trial • Individual patient data (IPD) meta-analysis of 6 published and one unpublished cohort of donor-recipient ABO mismatched allogeneic stem cell transplants • Primary end-point: Overall survival • OS compared among transplants with major, minor and bi-directional mismatch • Other end-points: • TRM • GVHD-related mortality • Engraftment or reticulocytes, neutrophils and platelets

  14. Study Selection • Inclusion criteria: • Original articles published in English after 1995 • Study endpoints included difference in OS between ABO matched and mismatched transplants • Exclusion criteria • ≤80 subjects • Median follow up <6 months

  15. 11 articles eligible  Authors contacted  6 authors agreed  Kyoto University (study centre) provided previously unanalysed SCT database

  16. Data Collection • IPD exclusion criteria: • Patients who did not meet minimum data requirements • SCT for conditions other than hematologic malignancies • Cord blood grafts, combined PB and BM grafts • Known previous SCT or no info re prior SCT history  Excluded patients enrolled in other pooled cohort studies

  17. Data Collection -2 Defined required variables (age, sex, diagnosis, stem cell source, MRD or MUD, survival status, # days survival post-BMT, donor-recipient blood types) and additional variables (HLA matching, conditioning regimen, GVHD prophylaxis regimen, cause of death, disease status at SCT, #days to engraftment of all blood cells)  Asked authors to complete data collection forms  Ambiguous results discussed and resolved

  18. Patients 1424 patients  133 did not meet minimum data requirements or had SCT for diseases other than heme malignancies  28 received cord blood grafts or both PB and BM grafts  6 enrolled in other pooled studies  49 prior SCT or SCT history not known  1208 transplants 697 ABO-matched 202 major ABO mismatch 228 minor ABO mismatch 81 bidirectional ABO mismatch

  19. Patients-2 • Western centres • 709 MRD • 184 MUD • Asian centres • 214 MRD • 101 MUD • No significant differences between matched and mis-matched groups for any category except type of donors and centres of transplantation • More MRD than MUD • Among MUD fewer HLA-mismatched

  20. Results- Overall Survival • Unadjusted probability of survival at 5 years: • ABO-matched: 48% • Major mismatch: 48% • Minor mismatch: 45% • Bidirectional mismatch: 37%

  21. Results- Overall SurvivalThe Subgroups • MRD • No difference in OS between ABO-matched and mismatched groups • Consistent across each stratified group • MUD • Minor and bi-directional mismatch associated with poorer OS when adjusted for age and sex • Strongly observed in some stratified categories: acute leukemia, SCT after 1998, Asian centres

  22. Results- Secondary Endpoints • TRM • Cumulative incidences of overall TRM was not significantly different between ABO matched and unmatched groups • Engraftment • No impact of ABO matching on engraftment in any cell line among patients who had MRD grafts • Marginally significant impact of minor and bi-directional mismatch on MUD grafts on delayed reticulocyte engraftment as compared to matched grafts

  23. The Authors’ Conclusion • “Our IPD-based meta-analysis demonstrated no adverse association between any type of ABO mismatching and survival in allogeneic SCTs for hematologic malignancies, although the possible association of minor or bi-directional ABO mismatching with lower OS was observed among recipients of unrelated SCTs”

  24. Intro to IPD • A Systematic Review and meta-analysis based on Individual Patient Data (IPD) involves collecting original individual patient data from trials included in the systematic review, and using this data to undertake meta-analysis. • http://www.liv.ac.uk/medstats/ipd.htm • As of 2005 IPD represented <5% of total meta-analysis literature

  25. Conventional vs IPD meta-analysis • Conventional meta-analysis extracts aggregated data • Analysis requires calculating a weighted average for effect across trials • Limitations: • Risk of publication bias • Heterogeneity in trial results • Inability to perform intention-to-treat analyses when relevant data are excluded/ missing • Limited methodological quality of source studies • Sub-group analysis generally not possible • Subgroup or meta-regression analysis using study level covariates can lead to questionable conclusions

  26. Differences between conventional and IPD meta-analysis • Advantages: • Enables detailed statistical analysis including time-to-event and subgroup analysis with adjustment for important baseline differences among patients • Enables intention-to-treat analysis • A necessary prerequisite for this is that all randomized patients, including those excluded from trialists’ analyses, must be included • Can use common definitions, coding and cutpoints • May be able to address questions not addressed in original publication • Can assess adequacy of randomization • Can check data, update data and check analyses

  27. Limitations • Biased pooling of data • If IPD investigators do not include ALL databases or explain why some studies were not included • IPD investigators should also indicate how missing data was handled • Presently no standardized method for IPD data analysis • A review of 44 IPD analyses found that clear reporting of statistical methods was rare and little reporting on why particular methods were chosen (Simmonds et al Clinical Trials 2005)

  28. Why would someone ever want to do this? • According to the Cochrane Collaboration, IPD analysis is desirable when: • Reporting of trials is selective, inadequate or ambiguous • Long term or time-to-event outcomes are considered • More detailed analyses are planned • Subgroup effects are of primary interest

  29. Some helpful tips from Sud and Douketis (EBM August 2009) • Analysis should occur as per an a priori statistical plan that accounts for across study and within study variation • “Prespecifying hypotheses and analytic methods is essential to prevent data dredging” • Important details to ascertain when looking at IPD analyses: • Any missing studies? • Do missing studies differ from those included in the IPD? • Any missing patients? Were statistical methods used that account for missing patient data and variability of patient characteristics

  30. How did our trial do? No pre-specification of sub-group analyses Missing data  Publications in languages other than English not considered  Databases other than PubMed not checked  Only 6 of 11 possible studies used  Inclusion of 1 previously unanalysed data set Insufficient detail on choice of statistical methods • Missing patients Ex: Data on (i) primary cause of death available for only 85% of patients, (ii) engraftment available for 24-55% of patients

  31. Does IPD have a role in transfusion medicine? • According to the Cochrane Collaboration, IPD analysis is desirable when: • Reporting of trials is selective, inadequate or ambiguous • Off label use of rFVIIa and thrombo-embolic complications • Long term outcomes are considered • ESAs- and risk of cancer relapse/ metastasis • Time-to-event outcomes are considered • Red cell to plasma ratios in massive transfusion • More detailed analyses are planned • Effect of platelet transfusion dose • Subgroup effects are of primary interest • ICU and perio-operative transfusion triggers in special groups (ie cardiac patients)

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