Cytometry masked autoencoder: An accurate and interpretable automated immunophenotyper.

IF 11.7 1区医学 Q1 CELL BIOLOGY Cell Reports Medicine Pub Date : 2024-11-04 DOI:10.1016/j.xcrm.2024.101808

Jaesik Kim, Matei Ionita, Matthew Lee, Michelle L McKeague, Ajinkya Pattekar, Mark M Painter, Joost Wagenaar, Van Truong, Dylan T Norton, Divij Mathew, Yonghyun Nam, Sokratis A Apostolidis, Cynthia Clendenin, Patryk Orzechowski, Sang-Hyuk Jung, Jakob Woerner, Caroline A G Ittner, Alexandra P Turner, Mika Esperanza, Thomas G Dunn, Nilam S Mangalmurti, John P Reilly, Nuala J Meyer, Carolyn S Calfee, Kathleen D Liu, Michael A Matthy, Lamorna Brown Swigart, Ellen L Burnham, Jeffrey McKeehan, Sheetal Gandotra, Derek W Russel, Kevin W Gibbs, Karl W Thomas, Harsh Barot, Allison R Greenplate, E John Wherry, Dokyoon Kim

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Abstract

Single-cell cytometry data are crucial for understanding the role of the immune system in diseases and responses to treatment. However, traditional methods for annotating cytometry data face challenges in scalability, robustness, and accuracy. We propose a cytometry masked autoencoder (cyMAE), which automates immunophenotyping tasks including cell type annotation. The model upholds user-defined cell type definitions, facilitating interpretability and cross-study comparisons. The training of cyMAE has a self-supervised phase, which leverages large amounts of unlabeled data, followed by fine-tuning on specialized tasks using smaller amounts of annotated data. The cost of training a new model is amortized over repeated inferences on new datasets using the same panel. Through validation across multiple studies using the same panel, we demonstrate that cyMAE delivers accurate and interpretable cellular immunophenotyping and improves the prediction of subject-level metadata. This proof of concept marks a significant step forward for large-scale immunology studies.

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细胞计量遮蔽自动编码器：准确、可解释的自动免疫分型器

单细胞细胞测量数据对于了解免疫系统在疾病中的作用和对治疗的反应至关重要。然而，注释细胞测量数据的传统方法在可扩展性、稳健性和准确性方面面临挑战。我们提出了一种细胞测量掩码自动编码器（cyMAE），它能自动完成包括细胞类型注释在内的免疫分型任务。该模型支持用户定义的细胞类型定义，便于解释和跨研究比较。cyMAE 的训练有一个自我监督阶段，利用大量未标注的数据，然后使用较少量的标注数据对专门任务进行微调。在使用相同面板对新数据集进行重复推断时，训练新模型的成本会被摊销。通过在使用相同面板的多项研究中进行验证，我们证明 cyMAE 能提供准确、可解释的细胞免疫分型，并能改进受试者级别元数据的预测。这一概念验证标志着大规模免疫学研究向前迈出了重要一步。

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来源期刊

Cell Reports Medicine Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)

CiteScore

15.00

自引率

1.40%

发文量

231

审稿时长

40 days

期刊介绍： Cell Reports Medicine is an esteemed open-access journal by Cell Press that publishes groundbreaking research in translational and clinical biomedical sciences, influencing human health and medicine. Our journal ensures wide visibility and accessibility, reaching scientists and clinicians across various medical disciplines. We publish original research that spans from intriguing human biology concepts to all aspects of clinical work. We encourage submissions that introduce innovative ideas, forging new paths in clinical research and practice. We also welcome studies that provide vital information, enhancing our understanding of current standards of care in diagnosis, treatment, and prognosis. This encompasses translational studies, clinical trials (including long-term follow-ups), genomics, biomarker discovery, and technological advancements that contribute to diagnostics, treatment, and healthcare. Additionally, studies based on vertebrate model organisms are within the scope of the journal, as long as they directly relate to human health and disease.