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Main Authors: Chen, Chi-Jane, Yi, Haidong, Stanley, Natalie
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.08638
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author Chen, Chi-Jane
Yi, Haidong
Stanley, Natalie
author_facet Chen, Chi-Jane
Yi, Haidong
Stanley, Natalie
contents Single-cell technologies enable comprehensive profiling of diverse immune cell-types through the measurement of multiple genes or proteins per individual cell. In order to translate immune signatures assayed from blood or tissue into powerful diagnostics, machine learning approaches are often employed to compute immunological summaries or per-sample featurizations, which can be used as inputs to models for outcomes of interest. Current supervised learning approaches for computing per-sample representations are trained only to accurately predict a single outcome and do not take into account relevant additional clinical features or covariates that are likely to also be measured for each sample. Here, we introduce a novel approach for incorporating measured covariates in optimizing model parameters to ultimately specify per-sample encodings that accurately affect both immune signatures and additional clinical information. Our introduced method CytoCoSet is a set-based encoding method for learning per-sample featurizations, which formulates a loss function with an additional triplet term penalizing samples with similar covariates from having disparate embedding results in per-sample representations. Overall, incorporating clinical covariates enables the learning of encodings for each individual sample that ultimately improve prediction of clinical outcome.
format Preprint
id arxiv_https___arxiv_org_abs_2406_08638
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Conditional Similarity Triplets Enable Covariate-Informed Representations of Single-Cell Data
Chen, Chi-Jane
Yi, Haidong
Stanley, Natalie
Machine Learning
Single-cell technologies enable comprehensive profiling of diverse immune cell-types through the measurement of multiple genes or proteins per individual cell. In order to translate immune signatures assayed from blood or tissue into powerful diagnostics, machine learning approaches are often employed to compute immunological summaries or per-sample featurizations, which can be used as inputs to models for outcomes of interest. Current supervised learning approaches for computing per-sample representations are trained only to accurately predict a single outcome and do not take into account relevant additional clinical features or covariates that are likely to also be measured for each sample. Here, we introduce a novel approach for incorporating measured covariates in optimizing model parameters to ultimately specify per-sample encodings that accurately affect both immune signatures and additional clinical information. Our introduced method CytoCoSet is a set-based encoding method for learning per-sample featurizations, which formulates a loss function with an additional triplet term penalizing samples with similar covariates from having disparate embedding results in per-sample representations. Overall, incorporating clinical covariates enables the learning of encodings for each individual sample that ultimately improve prediction of clinical outcome.
title Conditional Similarity Triplets Enable Covariate-Informed Representations of Single-Cell Data
topic Machine Learning
url https://arxiv.org/abs/2406.08638