Conference paper
Zachary Fox, Nolan English, Belinda Akpa
NeurIPS 2023 Generative AI and Biology (GenBio) Workshop, 2023 Dec
NeurIPS 2023 Generative AI and Biology (GenBio) Workshop, 2023 Dec
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Cite
APA
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Fox, Z., English, N., & Akpa, B. (2023). Targeting tissues via dynamic human systems modeling in generative design. In NeurIPS 2023 Generative AI and Biology (GenBio) Workshop.
Chicago/Turabian
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Fox, Zachary, Nolan English, and Belinda Akpa. “Targeting Tissues via Dynamic Human Systems Modeling in Generative Design.” In NeurIPS 2023 Generative AI and Biology (GenBio) Workshop, 2023.
MLA
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Fox, Zachary, et al. “Targeting Tissues via Dynamic Human Systems Modeling in Generative Design.” NeurIPS 2023 Generative AI and Biology (GenBio) Workshop, 2023.
BibTeX Click to copy
@inproceedings{fox2023a,
title = {Targeting tissues via dynamic human systems modeling in generative design},
year = {2023},
month = dec,
author = {Fox, Zachary and English, Nolan and Akpa, Belinda},
booktitle = {NeurIPS 2023 Generative AI and Biology (GenBio) Workshop},
month_numeric = {12}
}
Abstract
Drug discovery is a complex, costly process with high failure rates. A successful drug should bind to a target, be deliverable to an intended site of activity, and promote a desired pharmacological effect without causing toxicity. Typically, these factors are evaluated in series over the course of a pipeline where the number of candidates is reduced from a large initial pool. One promise of AI-driven discovery is the opportunity to evaluate multiple facets of drug performance in parallel. However, despite ML-driven advancements, current models for pharmacological property prediction are exclusively trained to predict molecular properties, ignoring important, dynamic biodistribution and bioactivity effects.
Here, we present our progress towards incorporating quantitative systems physiology models into an ML-based molecular generation pipeline. Within a genetic algorithm, we include human-relevant physiologically based pharmacokinetic (PBPK) models. These PBPK models leverage properties that are predicted by a fine-tuned molecular language model. Together, these models will aid in capturing the mapping between molecules and therapeutic outcomes that is necessary to accelerate the drug discovery process.