Superhuman Cell Death Detection with Biomarker-optimized Neural Networks

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2021 Dec 8

PMID 34878844

Citations 4

Authors

Jeremy W Linsley

Drew A Linsley

Josh Lamstein

Gennadi Ryan

Kevan Shah

Nicholas A Castello

Viral Oza

Jaslin Kalra

Shijie Wang

Zachary Tokuno

Ashkan Javaherian

Thomas Serre

Steven Finkbeiner

Affiliations

Soon will be listed here.

Abstract

Cellular events underlying neurodegenerative disease may be captured by longitudinal live microscopy of neurons. While the advent of robot-assisted microscopy has helped scale such efforts to high-throughput regimes with the statistical power to detect transient events, time-intensive human annotation is required. We addressed this fundamental limitation with biomarker-optimized convolutional neural networks (BO-CNNs): interpretable computer vision models trained directly on biosensor activity. We demonstrate the ability of BO-CNNs to detect cell death, which is typically measured by trained annotators. BO-CNNs detected cell death with superhuman accuracy and speed by learning to identify subcellular morphology associated with cell vitality, despite receiving no explicit supervision to rely on these features. These models also revealed an intranuclear morphology signal that is difficult to spot by eye and had not previously been linked to cell death, but that reliably indicates death. BO-CNNs are broadly useful for analyzing live microscopy and essential for interpreting high-throughput experiments.

Citing Articles

Investigation of mitochondrial phenotypes in motor neurons derived by direct conversion of fibroblasts from familial ALS subjects.

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Deceptive learning in histopathology.

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Harmonizing the object recognition strategies of deep neural networks with humans.

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Fluorescently labeled nuclear morphology is highly informative of neurotoxicity.

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