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Autores principales: Yu, Yemin, Hayir, Emre, Tenenholtz, Neil, Mackey, Lester, Wei, Ying, Alvarez-Melis, David, Amini, Ava P., Lu, Alex X.
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2504.09544
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author Yu, Yemin
Hayir, Emre
Tenenholtz, Neil
Mackey, Lester
Wei, Ying
Alvarez-Melis, David
Amini, Ava P.
Lu, Alex X.
author_facet Yu, Yemin
Hayir, Emre
Tenenholtz, Neil
Mackey, Lester
Wei, Ying
Alvarez-Melis, David
Amini, Ava P.
Lu, Alex X.
contents Recent advances in self-supervised deep learning have improved our ability to quantify cellular morphological changes in high-throughput microscopy screens, a process known as morphological profiling. However, most current methods only learn from images, despite many screens being inherently multimodal, as they involve both a chemical or genetic perturbation as well as an image-based readout. We hypothesized that incorporating chemical compound structures during self-supervised pre-training could improve learned representations of images from high-throughput microscopy screens. We introduce a representation learning framework, MICON (Molecular-Image Contrastive Learning), that models chemical compounds as treatments that induce transformations of cell phenotypes. MICON significantly outperforms classical hand-crafted features such as CellProfiler and existing deep-learning-based representation learning methods in challenging evaluation settings where models must identify reproducible effects of drugs across independent replicates and data-generating centers. We demonstrate that incorporating chemical compound information into the learning process provides small, but consistent improvements in performance and that modeling compounds specifically as treatments outperforms approaches that directly align images and compounds in a single representation space. Our findings point to a new direction for representation learning in morphological profiling, suggesting that methods should explicitly account for the multimodal nature of microscopy screening data.
format Preprint
id arxiv_https___arxiv_org_abs_2504_09544
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Integrating chemical structures as treatments improves representations of microscopy images for morphological profiling
Yu, Yemin
Hayir, Emre
Tenenholtz, Neil
Mackey, Lester
Wei, Ying
Alvarez-Melis, David
Amini, Ava P.
Lu, Alex X.
Machine Learning
Computational Engineering, Finance, and Science
Computer Vision and Pattern Recognition
Recent advances in self-supervised deep learning have improved our ability to quantify cellular morphological changes in high-throughput microscopy screens, a process known as morphological profiling. However, most current methods only learn from images, despite many screens being inherently multimodal, as they involve both a chemical or genetic perturbation as well as an image-based readout. We hypothesized that incorporating chemical compound structures during self-supervised pre-training could improve learned representations of images from high-throughput microscopy screens. We introduce a representation learning framework, MICON (Molecular-Image Contrastive Learning), that models chemical compounds as treatments that induce transformations of cell phenotypes. MICON significantly outperforms classical hand-crafted features such as CellProfiler and existing deep-learning-based representation learning methods in challenging evaluation settings where models must identify reproducible effects of drugs across independent replicates and data-generating centers. We demonstrate that incorporating chemical compound information into the learning process provides small, but consistent improvements in performance and that modeling compounds specifically as treatments outperforms approaches that directly align images and compounds in a single representation space. Our findings point to a new direction for representation learning in morphological profiling, suggesting that methods should explicitly account for the multimodal nature of microscopy screening data.
title Integrating chemical structures as treatments improves representations of microscopy images for morphological profiling
topic Machine Learning
Computational Engineering, Finance, and Science
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2504.09544