1.
Is microchimerism a sign of imminent disease recurrence after allogeneic hematopoietic stem cell transplantation? A systematic review of the literature
Haugaard, A. K., Kofoed, J., Masmas, T. N., Madsen, H. O., Marquart, H. V., Heilmann, C., Muller, K. G., Ifversen, M.
Blood reviews. 2020;:100673
Abstract
Chimerism analysis following hematopoietic stem cell transplantation (HSCT) for leukemia is routinely applied in parallel with quantification of minimal residual disease (MRD) to identify imminent relapse. In the past decades, new methods with a lower limit of detection compared to standard methods have been developed, so-called microchimerism analysis. Microchimerism analysis is fast, simple, applicable across pre-HSCT disease-type and can be applied on peripheral blood allowing frequent testing during follow-up. Monitoring of microchimerism in blood could replace repeated bone marrow analysis for MRD and allow earlier detection of imminent relapse or graft failure. Clinical studies in single center cohorts have shown conflicting but promising results. There is currently no consensus on the interpretation of microchimerism analysis and heterogeneity of studies remains a major obstacle for inter-study comparisons and meta-analysis in this field. We have conducted a systematic review of studies investigating associations between microchimerism and relapse of leukemia post-HSCT. We summarize current evidence and provide suggestions for future research.
2.
Highly sensitive chimerism detection in blood is associated with increased risk of relapse after allogeneic hematopoietic cell transplantation in childhood leukemia
Haugaard, A. K., Madsen, H. O., Marquart, H. V., Rosthoj, S., Masmas, T. N., Heilmann, C., Muller, K. G., Ifversen, M.
Pediatric transplantation. 2019;:e13549
Abstract
Analysis of chimerism in blood post-HCT using STR-PCR is routinely applied in parallel with quantification of MRD to predict relapse of leukemia. RQ-PCR chimerism is 10- to 100-fold more sensitive, but clinical studies in children are sparse. We analyzed IMC in blood samples following transplantation for acute lymphoblastic or myeloid leukemia in 56 children. IMC was defined as a minimum increase of (a) 0.1% or (b) 0.05% recipient DNA between two samples. The risk of relapse was higher in children with IMC of both 0.1% and 0.05% compared to children without IMC (HR 12.8 [95% CI: 3.9-41.4; P < .0001] and 7.6 [95% CI: 2.2-26.9; P < .01], respectively). The first IMC was detected at a median of 208 days prior to relapse. The 5-year cumulative incidence of relapse for children with a single IMC was 45.5% (CI 12.3-74.4) and 41.0% (14.2-66.6) for IMC above 0.1% and 0.05%, respectively. However, in 47 and 38 children never attaining IMC > 0.1% and >0.05%, 10 and 8 children relapsed, respectively. In a landmark analysis, no association was found between IMC prior to 90 days post-HCT and subsequent relapse by either classification of IMC and AUC for RQ-PCR chimerism was 54.2% (95 CI 27.7- 84.8). Although limited by a retrospective design, these results indicate that monitoring of RQ-PCR chimerism in peripheral blood may have a role in early detection of relapse in acute childhood leukemia.