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Auteurs principaux: Hagerman, David, Johnning, Anna, Naeem, Roman, Kahl, Fredrik, Kristiansson, Erik, Svensson, Lennart
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2502.14919
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author Hagerman, David
Johnning, Anna
Naeem, Roman
Kahl, Fredrik
Kristiansson, Erik
Svensson, Lennart
author_facet Hagerman, David
Johnning, Anna
Naeem, Roman
Kahl, Fredrik
Kristiansson, Erik
Svensson, Lennart
contents Antibiotic Resistance (AR) is a critical global health challenge that necessitates the development of cost-effective, efficient, and accurate diagnostic tools. Given the genetic basis of AR, techniques such as Polymerase Chain Reaction (PCR) that target specific resistance genes offer a promising approach for predictive diagnostics using a limited set of key genes. This study introduces GenoARM, a novel framework that integrates reinforcement learning (RL) with transformer-based models to optimize the selection of PCR gene tests and improve AR predictions, leveraging observed metadata for improved accuracy. In our evaluation, we developed several high-performing baselines and compared them using publicly available datasets derived from real-world bacterial samples representing multiple clinically relevant pathogens. The results show that all evaluated methods achieve strong and reliable performance when metadata is not utilized. When metadata is introduced and the number of selected genes increases, GenoARM demonstrates superior performance due to its capacity to approximate rewards for unseen and sparse combinations. Overall, our framework represents a major advancement in optimizing diagnostic tools for AR in clinical settings.
format Preprint
id arxiv_https___arxiv_org_abs_2502_14919
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Optimizing Gene-Based Testing for Antibiotic Resistance Prediction
Hagerman, David
Johnning, Anna
Naeem, Roman
Kahl, Fredrik
Kristiansson, Erik
Svensson, Lennart
Quantitative Methods
Machine Learning
Antibiotic Resistance (AR) is a critical global health challenge that necessitates the development of cost-effective, efficient, and accurate diagnostic tools. Given the genetic basis of AR, techniques such as Polymerase Chain Reaction (PCR) that target specific resistance genes offer a promising approach for predictive diagnostics using a limited set of key genes. This study introduces GenoARM, a novel framework that integrates reinforcement learning (RL) with transformer-based models to optimize the selection of PCR gene tests and improve AR predictions, leveraging observed metadata for improved accuracy. In our evaluation, we developed several high-performing baselines and compared them using publicly available datasets derived from real-world bacterial samples representing multiple clinically relevant pathogens. The results show that all evaluated methods achieve strong and reliable performance when metadata is not utilized. When metadata is introduced and the number of selected genes increases, GenoARM demonstrates superior performance due to its capacity to approximate rewards for unseen and sparse combinations. Overall, our framework represents a major advancement in optimizing diagnostic tools for AR in clinical settings.
title Optimizing Gene-Based Testing for Antibiotic Resistance Prediction
topic Quantitative Methods
Machine Learning
url https://arxiv.org/abs/2502.14919