Per-Event Uncertainty Quantification for Flow Cytometry Using Calibration Beads

IF 2.1 4区生物学 Q3 BIOCHEMICAL RESEARCH METHODS

Cytometry Part A Pub Date : 2025-08-29 DOI:10.1002/cyto.a.24954

Prajakta Bedekar, Megan A. Catterton, Matthew DiSalvo, Gregory A. Cooksey, Anthony J. Kearsley, Paul N. Patrone

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引用次数: 0

Abstract

Flow cytometry measurements are widely used in diagnostics and medical decision making. Incomplete understanding of sources of measurement uncertainty can make it difficult to distinguish autofluorescence and background sources from signals of interest. Moreover, established methods for modeling uncertainty overlook the fact that the apparent distribution of measurements is a convolution of the inherent population variability (e.g., associated with calibration beads or cells) and instrument-induced effects. Such issues make it difficult, for example, to identify signals from small objects such as extracellular vesicles. To overcome such limitations, we formulate an explicit probabilistic measurement model that accounts for volume and labeling variation, background signals, and fluorescence shot noise. Using raw data from routine per-event calibration measurements, we use this model to separate the aforementioned sources of uncertainty and demonstrate how such information can be used to facilitate decision making and instrument characterization.

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流式细胞术中使用校准珠的每事件不确定度定量。

流式细胞术测量广泛应用于诊断和医疗决策。对测量不确定度来源的不完全了解会使从感兴趣的信号中区分自身荧光和背景源变得困难。此外，建立的不确定性建模方法忽略了这样一个事实，即测量的表观分布是固有的总体变异性（例如，与校准珠或细胞有关）和仪器引起的影响的卷积。例如，这些问题使识别细胞外囊泡等小物体发出的信号变得困难。为了克服这些限制，我们制定了一个明确的概率测量模型，该模型考虑了体积和标记变化、背景信号和荧光射击噪声。使用来自常规事件校准测量的原始数据，我们使用该模型来分离上述不确定性来源，并演示如何使用这些信息来促进决策和仪器表征。

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来源期刊

Cytometry Part A 生物-生化研究方法

CiteScore

8.10

自引率

13.50%

发文量

183

审稿时长

4-8 weeks

期刊介绍： Cytometry Part A, the journal of quantitative single-cell analysis, features original research reports and reviews of innovative scientific studies employing quantitative single-cell measurement, separation, manipulation, and modeling techniques, as well as original articles on mechanisms of molecular and cellular functions obtained by cytometry techniques. The journal welcomes submissions from multiple research fields that fully embrace the study of the cytome: Biomedical Instrumentation Engineering Biophotonics Bioinformatics Cell Biology Computational Biology Data Science Immunology Parasitology Microbiology Neuroscience Cancer Stem Cells Tissue Regeneration.