MetFinder: A Tool for Automated Quantitation of Metastatic Burden in Histological Sections From Preclinical Models
- PMID: 39254030
- PMCID: PMC11948878
- DOI: 10.1111/pcmr.13195
MetFinder: A Tool for Automated Quantitation of Metastatic Burden in Histological Sections From Preclinical Models
Abstract
As efforts to study the mechanisms of melanoma metastasis and novel therapeutic approaches multiply, researchers need accurate, high-throughput methods to evaluate the effects on tumor burden resulting from specific interventions. We show that automated quantification of tumor content from whole slide images is a compelling solution to assess in vivo experiments. In order to increase the outflow of data collection from preclinical studies, we assembled a large dataset with annotations and trained a deep neural network for the quantitative analysis of melanoma tumor content on histopathological sections of murine models. After assessing its performance in segmenting these images, the tool obtained consistent results with an orthogonal method (bioluminescence) of measuring metastasis in an experimental setting. This AI-based algorithm, made freely available to academic laboratories through a web-interface called MetFinder, promises to become an asset for melanoma researchers and pathologists interested in accurate, quantitative assessment of metastasis burden.
Keywords: deep learning; histopathology; metastatic burden; murine models; preclinical studies; quantification; whole slide images.
© 2024 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.
Conflict of interest statement
COMPETING INTERESTS STATEMENT
The authors declare no conflict of interest.
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