Integration, exploration, and analysis of high‐dimensional single‐cell cytometry data using Spectre

As the size and complexity of high‐dimensional (HD) cytometry data continue to expand, comprehensive, scalable, and methodical computational analysis approaches are essential. Yet, contemporary clustering and dimensionality reduction tools alone are insufficient to analyze or reproduce analyses acro...

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Bibliographic Details
Published in:Cytometry. Part A 2022-03, Vol.101 (3), p.237-253
Main Authors: Ashhurst, Thomas Myles, Marsh‐Wakefield, Felix, Putri, Givanna Haryono, Spiteri, Alanna Gabrielle, Shinko, Diana, Read, Mark Norman, Smith, Adrian Lloyd, King, Nicholas Jonathan Cole
Format: Article
Language:English
Subjects:
Algorithms
Cluster Analysis
Clustering
computational analysis
Computer applications
Data integration
Data structures
Dimensional analysis
dimensionality reduction
Experiments
Flow cytometry
Flow Cytometry - methods
FlowSOM
Gene sequencing
high‐dimensional cytometry
Integration
Labeling
Learning algorithms
Machine learning
mass cytometry
Modular design
Reduction
Single-Cell Analysis
Software
spectral cytometry
Statistical analysis
Statistical methods
Toolkits
t‐SNE
UMAP
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Summary:As the size and complexity of high‐dimensional (HD) cytometry data continue to expand, comprehensive, scalable, and methodical computational analysis approaches are essential. Yet, contemporary clustering and dimensionality reduction tools alone are insufficient to analyze or reproduce analyses across large numbers of samples, batches, or experiments. Moreover, approaches that allow for the integration of data across batches or experiments are not well incorporated into computational toolkits to allow for streamlined workflows. Here we present Spectre, an R package that enables comprehensive end‐to‐end integration and analysis of HD cytometry data from different batches or experiments. Spectre streamlines the analytical stages of raw data pre‐processing, batch alignment, data integration, clustering, dimensionality reduction, visualization, and population labelling, as well as quantitative and statistical analysis. Critically, the fundamental data structures used within Spectre, along with the implementation of machine learning classifiers, allow for the scalable analysis of very large HD datasets, generated by flow cytometry, mass cytometry, or spectral cytometry. Using open and flexible data structures, Spectre can also be used to analyze data generated by single‐cell RNA sequencing or HD imaging technologies, such as Imaging Mass Cytometry. The simple, clear, and modular design of analysis workflows allow these tools to be used by bioinformaticians and laboratory scientists alike. Spectre is available as an R package or Docker container. R code is available on Github (https://github.com/immunedynamics/spectre).
ISSN:1552-4922
1552-4930
DOI:10.1002/cyto.a.24350