Abstract
Standardization, data mining techniques, and comparison to normality are changing the landscape of multiparameter flow cytometry in clinical hematology. On the basis of these principles, a strategy was developed for measurable residual disease (MRD) assessment. Herein, suspicious cell clusters are first identified at diagnosis using a clustering algorithm. Subsequently, automated multidimensional spaces, named “Clouds”, are created around these clusters on the basis of density calculations. This step identifies the immunophenotypic pattern of the suspicious cell clusters. Thereafter, using reference samples, the “Abnormality Ratio” (AR) of each Cloud is calculated, and major malignant Clouds are retained, known as “Leukemic Clouds” (L-Clouds). In follow-up samples, MRD is identified when more cells fall into a patient’s L-Cloud compared to reference samples (AR concept). This workflow was applied on simulated data and real-life leukemia flow cytometry data. On simulated data, strong patient-dependent positive correlation (R2 = 1) was observed between the AR and spiked-in leukemia cells. On real patient data, AR kinetics was in line with the clinical evolution for five out of six patients. In conclusion, we present a convenient flow cytometry data analysis approach for the follow-up of hematological malignancies. Further evaluation and validation on more patient samples and different flow cytometry panels is required before implementation in clinical practice.
Highlights
Multiparameter flow cytometry (MFC) is a powerful technology for cell phenotyping, capable of analyzing multiple parameters on millions of single cells in a short period of time [1]. This technique is helpful for the diagnosis of hematological malignancies, and its use for disease monitoring has gained a large amount of interest in the last decades through the evaluation of minimal/measurable residual disease (MRD)
In the Infinicyt software, clustering is based on cell density and a k-nearest neighbor (KNN)-based algorithm using the Euclidean distances of transformed raw data
The number of cells retrieved into the patient-specific L-Cloud for the control group and each MRD simulation were determined, and Abnormality Ratio (AR) was calculated for the MRD simulations
Summary
Multiparameter flow cytometry (MFC) is a powerful technology for cell phenotyping, capable of analyzing multiple parameters on millions of single cells in a short period of time [1]. This technique is helpful for the diagnosis of hematological malignancies, and its use for disease monitoring has gained a large amount of interest in the last decades through the evaluation of minimal/measurable residual disease (MRD). The immunophenotypic follow-up of acute myeloid leukemia (AML) is a difficult topic, mainly given the important heterogeneity of the disease [6,7,8] Multiple approaches such as the follow-up of leukemia-associated immunophenotypes (LAIP) and “different from normal” (DfN) strategies have been proposed [9,10]. The European LeukemiaNet (ELN) working party published a consensus document on AML MRD combining the two strategies into a “LAIP-based DfN approach” [11]
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