Data Efficient and Weakly Supervised Computational Pathology on Whole
Slide Images
- URL: http://arxiv.org/abs/2004.09666v2
- Date: Fri, 22 May 2020 02:03:49 GMT
- Title: Data Efficient and Weakly Supervised Computational Pathology on Whole
Slide Images
- Authors: Ming Y. Lu, Drew F. K. Williamson, Tiffany Y. Chen, Richard J. Chen,
Matteo Barbieri and Faisal Mahmood
- Abstract summary: computational pathology has the potential to enable objective diagnosis, therapeutic response prediction and identification of new morphological features of clinical relevance.
Deep learning-based computational pathology approaches either require manual annotation of gigapixel whole slide images (WSIs) in fully-supervised settings or thousands of WSIs with slide-level labels in a weakly-supervised setting.
Here we present CLAM - Clustering-constrained attention multiple instance learning.
- Score: 4.001273534300757
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The rapidly emerging field of computational pathology has the potential to
enable objective diagnosis, therapeutic response prediction and identification
of new morphological features of clinical relevance. However, deep
learning-based computational pathology approaches either require manual
annotation of gigapixel whole slide images (WSIs) in fully-supervised settings
or thousands of WSIs with slide-level labels in a weakly-supervised setting.
Moreover, whole slide level computational pathology methods also suffer from
domain adaptation and interpretability issues. These challenges have prevented
the broad adaptation of computational pathology for clinical and research
purposes. Here we present CLAM - Clustering-constrained attention multiple
instance learning, an easy-to-use, high-throughput, and interpretable WSI-level
processing and learning method that only requires slide-level labels while
being data efficient, adaptable and capable of handling multi-class subtyping
problems. CLAM is a deep-learning-based weakly-supervised method that uses
attention-based learning to automatically identify sub-regions of high
diagnostic value in order to accurately classify the whole slide, while also
utilizing instance-level clustering over the representative regions identified
to constrain and refine the feature space. In three separate analyses, we
demonstrate the data efficiency and adaptability of CLAM and its superior
performance over standard weakly-supervised classification. We demonstrate that
CLAM models are interpretable and can be used to identify well-known and new
morphological features. We further show that models trained using CLAM are
adaptable to independent test cohorts, cell phone microscopy images, and
biopsies. CLAM is a general-purpose and adaptable method that can be used for a
variety of different computational pathology tasks in both clinical and
research settings.
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