BackgroundFlow‐cytometric minimal residual disease (FC‐MRD) monitoring is a well‐established risk‐stratification factor in B‐lymphoblastic leukemia/lymphoma (‐B‐ALL) and is being considered as a basis for deintensification or escalation in treatment protocols. However, currently practiced standard FC‐MRD has limited sensitivity (up to 0.01%) and higher false MRD‐negative rate. Hence, a highly sensitive, widely applicable, and easily reproducible FC‐MRD assay is needed, which can provide a reliable basis for therapeutic modifications.MethodsA 10‐color high‐event analysis FC‐MRD assay was studied for the evaluation of MRD status at postinduction, (PI; day‐35), postconsolidation, (PC; day‐78), and subsequent follow‐up time‐points (SFU) in bone marrow samples from pediatric B‐ALL.ResultsOne‐thousand MRD samples (PI‐62.2%; PC‐26.5%; and SFU‐11.3%) from 622 childhood B‐ALL patients were studied. High‐event analysis was performed with median 4,452,000 events (range, 839,000 to 8,866,000 events) and >4 million events in 71% samples. MRD was measurable in 43.2% of PI‐samples, in 29.4% PC‐samples, and in 32.7% SFU‐samples. To simulate comparison with standard FC‐MRD, we reanalyzed MRD results gating only first 500,000 and first 1000,000 events in 122 PI‐MRD positive samples with MRD levels <0.02%. Of these samples gated for 500,000 events and 1000,000 events, 32% and 21.3% were found to be falsely MRD‐negative, respectively.ConclusionsWe report an easily reproducible high‐sensitivity 10‐color FC‐MRD assay with the sensitivity of 2‐in‐106 (0.0002%). It allowed the detection of low‐level MRD in samples, which could have been reported negative using the standard FC‐MRD with limited event analysis. Thus, this high‐sensitivity MRD‐methodology can provide a reliable basis for therapeutic modifications in B‐ALL. © 2019 International Clinical Cytometry Society
CD73 and CD86 are the most relevant markers to incorporate in the routine MRD evaluation of BCPALL. © 2016 International Clinical Cytometry Society.
Abnormal DNA ploidy is a valuable prognostic factor in many neoplasms, especially in hematological neoplasms like B-cell acute lymphoblastic leukemia (B-ALL) and multiple myeloma (MM). Current methods of flow-cytometric (FC) DNA-ploidy evaluation are either technically difficult or limited to three-to four-color immunophenotyping and hence, challenging to evaluate DNA-ploidy in minute tumor population with background rich of its normal counterpart cells and other hematopoietic cells. We standardized a novel sensitive and easy method of simultaneous evaluation of six-to sevencolor immunophenotyping and DNA-ploidy using a dye-FxCycle Violet (FCV). Linearity, resolution, and coefficient of variation (CV) for FCV were studied using chicken erythrocyte nuclei. Ploidy results of FCV were compared with Propidium iodide (PI) in 20 samples and intra-assay variation for FCV was studied. Using this six-color immunophenotyping & FCV-protocol DNA-ploidy was determined in bone-marrow samples from 124 B-ALL & 50 MM patients. Dilution experiment was also conducted to determine the sensitivity in detection of aneuploidy in minute tumor population. FCV revealed high linearity and resolution in 450/50 channel. On comparison with PI, CV of Go/G1-peak with FCV (mean-CV 4.1%) was slightly higher than PI (mean-CV 2.9%) but had complete agreement in ploidy results. Dilution experiment showed that aneuploidy could be accurately detected up to the limit of 0.01% tumor cells. Intraassay variation was very low with CV of 0.005%. In B-ALL, hypodiploidy was noted in 4%, hyperdiploidy in 24%, near-hyperdiploidy in 13% and remaining 59% were diploid. In MM, hypodiploidy was in 2%, hyperdiploidy in 58%, near-hyperdiploidy in 8% and remaining 30% were diploid. FCV-based DNA-ploidy method is a sensitive and easy method for simultaneous evaluation of six-color immunophenotyping and DNA analysis. It is useful in DNA-ploidy evaluation of minute tumor population in cases like minimal residual disease and MM precursor conditions. V C 2015 International Society for Advancement of CytometryKey terms DNA ploidy; cell cycle; FxCycle-violet; simultaneous multicolor immunophenotyping FLOW cytometric (FC) DNA content (DNA ploidy) evaluation is widely used tool in the prognostication of many solid tumors as well as hematological malignancies (1-5). It is an easy and rapid method to study the DNA content in the cells and to estimate proportion of cells present in different phases of the cell cycle. FC DNA ploidy analysis includes estimation of DNA index (DI) calculated by ratio of mean fluorescence of "G0/G1" peak of tumor cells to normal lymphocytes that reveals change in amount of DNA content of tumor cells in relation to normal diploid cells and percentage "S" phase provides an objective estimation of cell growth and may
Detection of measurable residual disease (MRD) by mutation specific techniques has prognostic relevance in NPM1 mutated AML (NPM1mut AML). However, the clinical utility of next generation sequencing (NGS) to detect MRD in AML remains unproven. We analysed the clinical significance of monitoring MRD using ultradeep NGS (NGS-MRD) and flow cytometry (FCM-MRD) in 137 samples obtained from 83 patients of NPM1mut AML at the end of induction (PI) and consolidation (PC). We could monitor 12 different types of NPM1 mutations at a sensitivity of 0.001% using NGS-MRD. We demonstrated a significant correlation between NGS-MRD and real time quantitative PCR (RQ-PCR). Based upon a one log reduction between PI and PC time points we could classify patients as NGS-MRD positive (<1log reduction) or negative (>1log reduction). NGS-MRD, FCM-MRD as well as DNMT3A mutations were predictive of inferior overall survival (OS) and relapse free survival (RFS). On a multivariate analysis NGS-MRD emerged as an independent, most important prognostic factor predictive of inferior OS (hazard ratio, 3.64; 95% confidence interval [CI] 1.58 to 8.37) and RFS (hazard ratio, 4.8; 95% CI:2.24 to 10.28). We establish that DNA based NPM1 NGS MRD is a highly useful test for prediction of relapse and survival in NPM1mut AML.
Measurable/minimal residual disease (MRD) status has been suggested as a powerful indicator of clinical-outcome in T-cell lymphoblastic leukemia/lymphoma (T-ALL). Multicolor flow cytometric (MFC)-based T-ALL MRD reports are limited and traditionally based on the utilization of markers-of-immaturity like TdT and CD99. Moreover, studies demonstrating the multicolor flow cytometric (MFC) approach for the assessment of T-ALL MRD are sparse. Herein, we describe an 11-marker, 10-color MFC-based T-ALL MRD method using an "approach of exclusion." Methods: The study included 269 childhood T-ALL patients treated with a modified-MCP841 protocol. An 11-marker, 10-color MFC-based MRD was performed in bone marrow (BM) samples at the end-of-induction (EOI) and end-of-consolidation (EOC) time-points using Kaluza-version-1.3 software.Results: We studied EOI-MRD in 269 and EOC-MRD in 105 childhood T-ALL patients. EOI-MRD was detectable in 125 (46.5%) samples (median, 0.3%; range, 0.0007-66.3%), and EOC-MRD was detectable in 34/105 (32.4%) samples (median, 0.055%; range, 0.0008-27.6%). Leukemia-associated immunophenotypes (LAIPs) found useful for MRD assessment were dual-negative CD4/CD8 (40.9%), dualpositive CD4/CD8 (23.3%) and only CD4 or CD8 expression (35.8%); dim/subset/ dim-negative surface-CD3 (39%), dim/subset/dim-negative/negative CD5 (28.3%), dim/dim-negative/negative/heterogeneous CD45 (44.7%) and co-expression of CD5/CD56 (7.5%). EOI-MRD-positive status was found to be the most-relevant independent factor in the prediction of inferior relapse-free and overall survival. Conclusion:We described an 11-marker 10-color MFC-based highly sensitive MRD
BackgroundMeasurable residual disease (MRD) assessment using multicolor flow cytometry (MFC) has become the center point of pediatric B‐cell precursor acute lymphoblastic leukemia (BCP‐ALL) risk stratification and therapeutic management. The addition of new markers can improve the accuracy and applicability of MFC‐based MRD assay further. Herein, we evaluated the utility of a new marker, CD304/neuropilin‐1, in the assessment of MFC‐based MRD.MethodsExpression patterns of CD304 were studied in leukemic blasts from BCP‐ALL patients and in normal precursor B cells (NPBC) from uninvolved non‐BCP‐ALL bone marrow samples using 10‐color MFC. MRD was monitored at end‐of‐induction (EOI; Days 35–40) and end‐of‐consolidation (Day 78–80) time points.ResultsWe studied CD304 expression in 300 pediatric BCP‐ALL patients and found it positive in BCP‐ALL blasts in 41.7% of diagnostic samples. It was significantly associated with ETV6‐RUNX1 (p < .001) as well as BCR‐ABL1 (p = .019) and inversely associated with TCF3‐PBX1 fusion gene (p = .0012). It was found clearly negative in NPBC. EOI‐MRD was detectable in 152/300 (50.7%; ≥0.01% in 35.33% and <0.01% in 15.33%) samples, in which CD304 was positive in 72/152 (47.4%) diagnostic and 63/152 (41.4%) MRD samples. It was positive in 45.7% (21/46) of low‐level (<0.01%) MRD samples. In comparison with diagnostic samples, its expression was retained in 68.06% (49/72), lost in 31.94% (23/72), and gained in 14/80 (17.5%) of EOI‐MRD samples.ConclusionsCD304 is commonly expressed in leukemic blasts of BCP‐ALL. It is very useful in distinguishing residual disease from hematogones and is a fairly dependable marker. Hence, it is a valuable addition for enhancing the sensitivity and applicability of MFC‐based MRD assay in BCP‐ALL.
The clinical use of flow cytometric DNA ploidy assay has been extended towards stratifying the risk of diseases, such as monoclonal gammopathies or B cell acute lymphoblastic leukemia, and to detect circulating tumor cells, both of which require detection of minute cell populations. This unit describes a protocol for determining DNA ploidy in fixed samples with simultaneous surface immunophenotyping. It is an easy method for simultaneous 6- to 8-color immunophenotyping and DNA content analysis using FxCycle Violet (FCV; DAPI) dye. This protocol is a one-step modification of routine multicolor immunophenotyping that includes surface staining followed by fixation and then DNA staining with FCV. It utilizes mature lymphocytes from the sample as an internal control for determination of DNA index. It is a sensitive method that allows DNA-ploidy determination and cell cycle analysis in a rare tumor population as low as 100 events, as well as DNA ploidy determination in various subsets of hematopoietic cells in the same sample based on their immunophenotype. © 2017 by John Wiley & Sons, Inc.
Background: Measurable/minimal residual disease (MRD) status is suggested as a powerful indicator of clinical-outcome in T-cell lymphoblastic leukemia/lymphoma (T-ALL). Contrary to B-cell ALL, reports on TALL MRD are limited and mostly based on molecular methods, mainly from developed countries. Multicolor flow cytometry (MFC)-based TALL studies are very few. Clinically relevant cutoff levels and ideal time-point for MRD assessment are still inconclusive. In view of lack of TALL MRD data from the developing world, we evaluated the prognostic value of MFC-based post-induction (PI)-MRD assessment in TALL in the context of standard practice. Methods: We included 256 childhood-TALL patients (age < 15 years) treated with a modified-MCP841 protocol, which uses high-dose cytarabine during consolidation, as a part of standard hospital practice. MRD was studied using 10-color 11-antibody MFC with any level of detectable disease being considered positive. Post-induction (PI)-MRD was available in all patients, and post-consolidation (PC) MRD was available mostly in PI-MRD-positive patients (n = 88). Results: Three years cumulative-incidence-of-relapse (3years-CIR) in PI-MRD-positive patients was inferior to negative patients (46.3% vs. 18.4%). The median relapse-free-survival (RFS), event-free-survival (EFS) and overall-survival (OS) with hazard ratio (HR) of PI-MRD-positive patients were 21.4 months vs not reached (p < 0.0001, HR-4.7), 21.6 months vs. not-reached (p = 0.0003, HR-2.01) and 37.3 months vs. not reached (p = 0.026, HR-1.64) respectively. RFS, EFS and OS of patients with PI-MRD<0.01% (n = 17) were as inferior as PI-MRD ≥ 0.01% in comparison Tembhare et al. Post-induction MRD & WBC Count in TALL with MRD-negative patients with HR of 4.7 (p < 0.0001), 2.45 (p = 0.0003), and 2.5 (p = 0.029), respectively. Three-years-CIR of patients with hyperleukocytosis (≥100 × 109/L) was also higher (50.5 vs. 27.6%) with inferior RFS, EFS, and OS. Among PI-MRDpositive patients, 3years-CIR, RFS, EFS, and OS of PC-MRD-positive were also inferior to that of negative patients. On multivariate analysis any-level detectable PI-MRD and hyperleukocytosis remained independently associated with inferior RFS, EFS, and OS. A combination of PI-MRD-positive status and hyperleukocytosis identified the patients with the worst clinical outcomes. Conclusion: Detectable PI-MRD using MFC was found to be the strong predictive factor of inferior clinical outcome in TALL patients. The combination of PI-MRD status and hyperleukocytosis provides the most influential tool for the management of TALL in resource constrained settings from developing world.
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