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Bibliographic Details
Main Authors: Weinstein, Eli N., Slabodkin, Andrei, Gollub, Mattia G., Wood, Elizabeth B.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.16612
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author Weinstein, Eli N.
Slabodkin, Andrei
Gollub, Mattia G.
Wood, Elizabeth B.
author_facet Weinstein, Eli N.
Slabodkin, Andrei
Gollub, Mattia G.
Wood, Elizabeth B.
contents Biological machine learning is often bottlenecked by a lack of scaled data. One promising route to relieving data bottlenecks is through high throughput screens, which can experimentally test the activity of $10^6-10^{12}$ protein sequences in parallel. In this article, we introduce algorithms to optimize high throughput screens for data creation and model training. We focus on the large scale regime, where dataset sizes are limited by the cost of measurement and sequencing. We show that when active sequences are rare, we maximize information gain if we only collect positive examples of active sequences, i.e. $x$ with $y>0$. We can correct for the missing negative examples using a generative model of the library, producing a consistent and efficient estimate of the true $p(y | x)$. We demonstrate this approach in simulation and on a large scale screen of antibodies. Overall, co-design of experiments and inference lets us accelerate learning dramatically.
format Preprint
id arxiv_https___arxiv_org_abs_2510_16612
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Accelerated Learning on Large Scale Screens using Generative Library Models
Weinstein, Eli N.
Slabodkin, Andrei
Gollub, Mattia G.
Wood, Elizabeth B.
Machine Learning
Biomolecules
Biological machine learning is often bottlenecked by a lack of scaled data. One promising route to relieving data bottlenecks is through high throughput screens, which can experimentally test the activity of $10^6-10^{12}$ protein sequences in parallel. In this article, we introduce algorithms to optimize high throughput screens for data creation and model training. We focus on the large scale regime, where dataset sizes are limited by the cost of measurement and sequencing. We show that when active sequences are rare, we maximize information gain if we only collect positive examples of active sequences, i.e. $x$ with $y>0$. We can correct for the missing negative examples using a generative model of the library, producing a consistent and efficient estimate of the true $p(y | x)$. We demonstrate this approach in simulation and on a large scale screen of antibodies. Overall, co-design of experiments and inference lets us accelerate learning dramatically.
title Accelerated Learning on Large Scale Screens using Generative Library Models
topic Machine Learning
Biomolecules
url https://arxiv.org/abs/2510.16612