Analysis of 3D pathology samples using weakly supervised AI

Andrew H. Song; Mane Williams; Drew F.K. Williamson; Sarah S.L. Chow; Guillaume Jaume; Gan Gao; Andrew Zhang; Bowen Chen; Alexander S. Baras; Robert Serafin; Richard Colling; Michelle R. Downes; Xavier Farré; Peter Humphrey; Clare Verrill; Lawrence D. True; Anil V. Parwani; Jonathan T.C. Liu; Faisal Mahmood

doi:10.1016/j.cell.2024.03.035

Analysis of 3D pathology samples using weakly supervised AI

Andrew H. Song
, Mane Williams
, Drew F.K. Williamson
, Sarah S.L. Chow
, Guillaume Jaume
, Gan Gao
, Andrew Zhang
, Bowen Chen
, Alexander S. Baras
, Robert Serafin
, Richard Colling
, Michelle R. Downes
, Xavier Farré
, Peter Humphrey
, Clare Verrill
, Lawrence D. True
, Anil V. Parwani
, Jonathan T.C. Liu^*
, Faisal Mahmood^*

^*Corresponding author for this work

Harvard University
Broad Institute
Dana-Farber Cancer Institute
University of Washington
Massachusetts Institute of Technology
Johns Hopkins University
University of Oxford
Department of Cellular Pathology
John Radcliffe Hospital
University of Toronto and Sunnybrook Health Sciences Centre
Public Health Agency of Catalonia
Yale University
NIHR Oxford Biomedical Research Centre
Ohio State University

Research output: Contribution to journal › Article › peer-review

Abstract

Human tissue, which is inherently three-dimensional (3D), is traditionally examined through standard-of-care histopathology as limited two-dimensional (2D) cross-sections that can insufficiently represent the tissue due to sampling bias. To holistically characterize histomorphology, 3D imaging modalities have been developed, but clinical translation is hampered by complex manual evaluation and lack of computational platforms to distill clinical insights from large, high-resolution datasets. We present TriPath, a deep-learning platform for processing tissue volumes and efficiently predicting clinical outcomes based on 3D morphological features. Recurrence risk-stratification models were trained on prostate cancer specimens imaged with open-top light-sheet microscopy or microcomputed tomography. By comprehensively capturing 3D morphologies, 3D volume-based prognostication achieves superior performance to traditional 2D slice-based approaches, including clinical/histopathological baselines from six certified genitourinary pathologists. Incorporating greater tissue volume improves prognostic performance and mitigates risk prediction variability from sampling bias, further emphasizing the value of capturing larger extents of heterogeneous morphology.

Original language	English
Pages (from-to)	2502-2520.e17
Journal	Cell
Volume	187
Issue number	10
DOIs	https://doi.org/10.1016/j.cell.2024.03.035
Publication status	Published - 9 May 2024
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

ASJC Scopus subject areas

General Biochemistry,Genetics and Molecular Biology

Keywords

3D deep learning
3D microscopy
3D pathology
computational pathology
deep learning
intratumoral heterogeneity
microCT
patient prognosis
slide-free microscopy

Access to Document

10.1016/j.cell.2024.03.035

Cite this

Song, A. H., Williams, M., Williamson, D. F. K., Chow, S. S. L., Jaume, G., Gao, G., Zhang, A., Chen, B., Baras, A. S., Serafin, R., Colling, R., Downes, M. R., Farré, X., Humphrey, P., Verrill, C., True, L. D., Parwani, A. V., Liu, J. T. C., & Mahmood, F. (2024). Analysis of 3D pathology samples using weakly supervised AI. Cell, 187(10), 2502-2520.e17. https://doi.org/10.1016/j.cell.2024.03.035

@article{0848b0d057094b9db2ee2c586c18c6d5,

title = "Analysis of 3D pathology samples using weakly supervised AI",

abstract = "Human tissue, which is inherently three-dimensional (3D), is traditionally examined through standard-of-care histopathology as limited two-dimensional (2D) cross-sections that can insufficiently represent the tissue due to sampling bias. To holistically characterize histomorphology, 3D imaging modalities have been developed, but clinical translation is hampered by complex manual evaluation and lack of computational platforms to distill clinical insights from large, high-resolution datasets. We present TriPath, a deep-learning platform for processing tissue volumes and efficiently predicting clinical outcomes based on 3D morphological features. Recurrence risk-stratification models were trained on prostate cancer specimens imaged with open-top light-sheet microscopy or microcomputed tomography. By comprehensively capturing 3D morphologies, 3D volume-based prognostication achieves superior performance to traditional 2D slice-based approaches, including clinical/histopathological baselines from six certified genitourinary pathologists. Incorporating greater tissue volume improves prognostic performance and mitigates risk prediction variability from sampling bias, further emphasizing the value of capturing larger extents of heterogeneous morphology.",

keywords = "3D deep learning, 3D microscopy, 3D pathology, computational pathology, deep learning, intratumoral heterogeneity, microCT, patient prognosis, slide-free microscopy",

author = "Song, \{Andrew H.\} and Mane Williams and Williamson, \{Drew F.K.\} and Chow, \{Sarah S.L.\} and Guillaume Jaume and Gan Gao and Andrew Zhang and Bowen Chen and Baras, \{Alexander S.\} and Robert Serafin and Richard Colling and Downes, \{Michelle R.\} and Xavier Farr{\'e} and Peter Humphrey and Clare Verrill and True, \{Lawrence D.\} and Parwani, \{Anil V.\} and Liu, \{Jonathan T.C.\} and Faisal Mahmood",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Inc.",

year = "2024",

month = may,

day = "9",

doi = "10.1016/j.cell.2024.03.035",

language = "English",

volume = "187",

pages = "2502--2520.e17",

journal = "Cell",

issn = "0092-8674",

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Song, AH, Williams, M, Williamson, DFK, Chow, SSL, Jaume, G, Gao, G, Zhang, A, Chen, B, Baras, AS, Serafin, R, Colling, R, Downes, MR, Farré, X, Humphrey, P, Verrill, C, True, LD, Parwani, AV, Liu, JTC & Mahmood, F 2024, 'Analysis of 3D pathology samples using weakly supervised AI', Cell, vol. 187, no. 10, pp. 2502-2520.e17. https://doi.org/10.1016/j.cell.2024.03.035

TY - JOUR

T1 - Analysis of 3D pathology samples using weakly supervised AI

AU - Song, Andrew H.

AU - Williams, Mane

AU - Williamson, Drew F.K.

AU - Chow, Sarah S.L.

AU - Jaume, Guillaume

AU - Gao, Gan

AU - Zhang, Andrew

AU - Chen, Bowen

AU - Baras, Alexander S.

AU - Serafin, Robert

AU - Colling, Richard

AU - Downes, Michelle R.

AU - Farré, Xavier

AU - Humphrey, Peter

AU - Verrill, Clare

AU - True, Lawrence D.

AU - Parwani, Anil V.

AU - Liu, Jonathan T.C.

AU - Mahmood, Faisal

PY - 2024/5/9

Y1 - 2024/5/9

N2 - Human tissue, which is inherently three-dimensional (3D), is traditionally examined through standard-of-care histopathology as limited two-dimensional (2D) cross-sections that can insufficiently represent the tissue due to sampling bias. To holistically characterize histomorphology, 3D imaging modalities have been developed, but clinical translation is hampered by complex manual evaluation and lack of computational platforms to distill clinical insights from large, high-resolution datasets. We present TriPath, a deep-learning platform for processing tissue volumes and efficiently predicting clinical outcomes based on 3D morphological features. Recurrence risk-stratification models were trained on prostate cancer specimens imaged with open-top light-sheet microscopy or microcomputed tomography. By comprehensively capturing 3D morphologies, 3D volume-based prognostication achieves superior performance to traditional 2D slice-based approaches, including clinical/histopathological baselines from six certified genitourinary pathologists. Incorporating greater tissue volume improves prognostic performance and mitigates risk prediction variability from sampling bias, further emphasizing the value of capturing larger extents of heterogeneous morphology.

AB - Human tissue, which is inherently three-dimensional (3D), is traditionally examined through standard-of-care histopathology as limited two-dimensional (2D) cross-sections that can insufficiently represent the tissue due to sampling bias. To holistically characterize histomorphology, 3D imaging modalities have been developed, but clinical translation is hampered by complex manual evaluation and lack of computational platforms to distill clinical insights from large, high-resolution datasets. We present TriPath, a deep-learning platform for processing tissue volumes and efficiently predicting clinical outcomes based on 3D morphological features. Recurrence risk-stratification models were trained on prostate cancer specimens imaged with open-top light-sheet microscopy or microcomputed tomography. By comprehensively capturing 3D morphologies, 3D volume-based prognostication achieves superior performance to traditional 2D slice-based approaches, including clinical/histopathological baselines from six certified genitourinary pathologists. Incorporating greater tissue volume improves prognostic performance and mitigates risk prediction variability from sampling bias, further emphasizing the value of capturing larger extents of heterogeneous morphology.

KW - 3D deep learning

KW - 3D microscopy

KW - 3D pathology

KW - computational pathology

KW - deep learning

KW - intratumoral heterogeneity

KW - microCT

KW - patient prognosis

KW - slide-free microscopy

UR - https://www.scopus.com/pages/publications/85192149734

U2 - 10.1016/j.cell.2024.03.035

DO - 10.1016/j.cell.2024.03.035

M3 - Article

C2 - 38729110

AN - SCOPUS:85192149734

SN - 0092-8674

VL - 187

SP - 2502-2520.e17

JO - Cell

JF - Cell

IS - 10

ER -

Analysis of 3D pathology samples using weakly supervised AI

Abstract

UN SDGs

ASJC Scopus subject areas

Keywords

Access to Document

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