TY - JOUR
T1 - Integrated T cell cytometry metrics for immune-monitoring applications in immunotherapy clinical trials
AU - Sidiropoulos, Dimitrios N.
AU - Stein-O'Brien, Genevieve L.
AU - Danilova, Ludmila
AU - Gross, Nicole E.
AU - Charmsaz, Soren
AU - Xavier, Stephanie
AU - Leatherman, James
AU - Wang, Hao
AU - Yarchoan, Mark
AU - Jaffee, Elizabeth M.
AU - Fertig, Elana J.
AU - Ho, Won Jin
N1 - Publisher Copyright:
Copyright: © 2022, Sidiropoulos et al. This is an open access article published under the terms of the Creative Commons Attribution 4.0 International License.
PY - 2022/10/10
Y1 - 2022/10/10
N2 - Mass cytometry, or cytometry by TOF (CyTOF), provides a robust means of determining protein-level measurements of more than 40 markers simultaneously. While the functional states of immune cells occur along continuous phenotypic transitions, cytometric studies surveying cell phenotypes often rely on static metrics, such as discrete cell-type abundances, based on canonical markers and/or restrictive gating strategies. To overcome this limitation, we applied single-cell trajectory inference and nonnegative matrix factorization methods to CyTOF data to trace the dynamics of T cell states. In the setting of cancer immunotherapy, we showed that patient-specific summaries of continuous phenotypic shifts in T cells could be inferred from peripheral blood-derived CyTOF mass cytometry data. We further illustrated that transfer learning enabled these T cell continuous metrics to be used to estimate patient-specific cell states in new sample cohorts from a reference patient data set. Our work establishes the utility of continuous metrics for CyTOF analysis as tools for translational discovery.
AB - Mass cytometry, or cytometry by TOF (CyTOF), provides a robust means of determining protein-level measurements of more than 40 markers simultaneously. While the functional states of immune cells occur along continuous phenotypic transitions, cytometric studies surveying cell phenotypes often rely on static metrics, such as discrete cell-type abundances, based on canonical markers and/or restrictive gating strategies. To overcome this limitation, we applied single-cell trajectory inference and nonnegative matrix factorization methods to CyTOF data to trace the dynamics of T cell states. In the setting of cancer immunotherapy, we showed that patient-specific summaries of continuous phenotypic shifts in T cells could be inferred from peripheral blood-derived CyTOF mass cytometry data. We further illustrated that transfer learning enabled these T cell continuous metrics to be used to estimate patient-specific cell states in new sample cohorts from a reference patient data set. Our work establishes the utility of continuous metrics for CyTOF analysis as tools for translational discovery.
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U2 - 10.1172/jci.insight.160398
DO - 10.1172/jci.insight.160398
M3 - Article
C2 - 36214223
AN - SCOPUS:85139425731
SN - 2379-3708
VL - 7
JO - JCI Insight
JF - JCI Insight
IS - 19
M1 - e160398
ER -