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Main Authors: Yao, Michael S., Bastani, Osbert, Andersson, Alma, Biancalani, Tommaso, Bentaieb, Aïcha, Iriondo, Claudia
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.20975
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author Yao, Michael S.
Bastani, Osbert
Andersson, Alma
Biancalani, Tommaso
Bentaieb, Aïcha
Iriondo, Claudia
author_facet Yao, Michael S.
Bastani, Osbert
Andersson, Alma
Biancalani, Tommaso
Bentaieb, Aïcha
Iriondo, Claudia
contents The goal of personalized medicine is to discover a treatment regimen that optimizes a patient's clinical outcome based on their personal genetic and environmental factors. However, candidate treatments cannot be arbitrarily administered to the patient to assess their efficacy; we often instead have access to an in silico surrogate model that approximates the true fitness of a proposed treatment. Unfortunately, such surrogate models have been shown to fail to generalize to previously unseen patient-treatment combinations. We hypothesize that domain-specific prior knowledge - such as medical textbooks and biomedical knowledge graphs - can provide a meaningful alternative signal of the fitness of proposed treatments. To this end, we introduce LLM-based Entropy-guided Optimization with kNowledgeable priors (LEON), a mathematically principled approach to leverage large language models (LLMs) as black-box optimizers without any task-specific fine-tuning, taking advantage of their ability to contextualize unstructured domain knowledge to propose personalized treatment plans in natural language. In practice, we implement LEON via 'optimization by prompting,' which uses LLMs as stochastic engines for proposing treatment designs. Experiments on real-world optimization tasks show LEON outperforms both traditional and LLM-based methods in proposing individualized treatments for patients.
format Preprint
id arxiv_https___arxiv_org_abs_2509_20975
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Knowledgeable Language Models as Black-Box Optimizers for Personalized Medicine
Yao, Michael S.
Bastani, Osbert
Andersson, Alma
Biancalani, Tommaso
Bentaieb, Aïcha
Iriondo, Claudia
Machine Learning
Artificial Intelligence
The goal of personalized medicine is to discover a treatment regimen that optimizes a patient's clinical outcome based on their personal genetic and environmental factors. However, candidate treatments cannot be arbitrarily administered to the patient to assess their efficacy; we often instead have access to an in silico surrogate model that approximates the true fitness of a proposed treatment. Unfortunately, such surrogate models have been shown to fail to generalize to previously unseen patient-treatment combinations. We hypothesize that domain-specific prior knowledge - such as medical textbooks and biomedical knowledge graphs - can provide a meaningful alternative signal of the fitness of proposed treatments. To this end, we introduce LLM-based Entropy-guided Optimization with kNowledgeable priors (LEON), a mathematically principled approach to leverage large language models (LLMs) as black-box optimizers without any task-specific fine-tuning, taking advantage of their ability to contextualize unstructured domain knowledge to propose personalized treatment plans in natural language. In practice, we implement LEON via 'optimization by prompting,' which uses LLMs as stochastic engines for proposing treatment designs. Experiments on real-world optimization tasks show LEON outperforms both traditional and LLM-based methods in proposing individualized treatments for patients.
title Knowledgeable Language Models as Black-Box Optimizers for Personalized Medicine
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2509.20975