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Automated multi-scale computational pathotyping (AMSCP) of inflamed synovial tissue

Author

Listed:
  • Richard D. Bell

    (Hospital for Special Surgery
    Weill Cornell Medical College)

  • Matthew Brendel

    (Weill Cornell Medical College)

  • Maxwell A. Konnaris

    (State College
    Hospital for Special Surgery)

  • Justin Xiang

    (Horace Greely High School)

  • Miguel Otero

    (Weill Cornell Medical College
    Hospital for Special Surgery)

  • Mark A. Fontana

    (Hospital for Special Surgery
    Weill Cornell Medical College)

  • Zilong Bai

    (Weill Cornell Medical College)

  • Daria M. Krenitsky

    (University of Rochester Medical Center)

  • Nida Meednu

    (University of Rochester Medical Center)

  • Javier Rangel-Moreno

    (University of Rochester Medical Center)

  • Dagmar Scheel-Toellner

    (Queen Elizabeth Hospital)

  • Hayley Carr

    (Queen Elizabeth Hospital)

  • Saba Nayar

    (Queen Elizabeth Hospital)

  • Jack McMurray

    (Queen Elizabeth Hospital)

  • Edward DiCarlo

    (Hospital for Special Surgery)

  • Jennifer H. Anolik

    (University of Rochester Medical Center
    University of Rochester Medical Center)

  • Laura T. Donlin

    (Hospital for Special Surgery)

  • Dana E. Orange

    (Hospital for Special Surgery
    The Rockefeller University)

  • H. Mark Kenney

    (University of Rochester Medical Center)

  • Edward M. Schwarz

    (University of Rochester Medical Center)

  • Andrew Filer

    (Queen Elizabeth Hospital)

  • Lionel B. Ivashkiv

    (Hospital for Special Surgery
    Weill Cornell Medical College)

  • Fei Wang

    (Weill Cornell Medical College)

Abstract

Rheumatoid arthritis (RA) is a complex immune-mediated inflammatory disorder in which patients suffer from inflammatory-erosive arthritis. Recent advances on histopathology heterogeneity of RA synovial tissue revealed three distinct phenotypes based on cellular composition (pauci-immune, diffuse and lymphoid), suggesting that distinct etiologies warrant specific targeted therapy which motivates a need for cost effective phenotyping tools in preclinical and clinical settings. To this end, we developed an automated multi-scale computational pathotyping (AMSCP) pipeline for both human and mouse synovial tissue with two distinct components that can be leveraged together or independently: (1) segmentation of different tissue types to characterize tissue-level changes, and (2) cell type classification within each tissue compartment that assesses change across disease states. Here, we demonstrate the efficacy, efficiency, and robustness of the AMSCP pipeline as well as the ability to discover novel phenotypes. Taken together, we find AMSCP to be a valuable cost-effective method for both pre-clinical and clinical research.

Suggested Citation

  • Richard D. Bell & Matthew Brendel & Maxwell A. Konnaris & Justin Xiang & Miguel Otero & Mark A. Fontana & Zilong Bai & Daria M. Krenitsky & Nida Meednu & Javier Rangel-Moreno & Dagmar Scheel-Toellner , 2024. "Automated multi-scale computational pathotyping (AMSCP) of inflamed synovial tissue," Nature Communications, Nature, vol. 15(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-51012-6
    DOI: 10.1038/s41467-024-51012-6
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