Transfer learning with graph neural networks for improved molecular property prediction in the multi-fidelity setting

19 January 2024, Version 3
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

We investigate the potential of graph neural networks for transfer learning and improving molecular property prediction on sparse and expensive to acquire high-fidelity data by leveraging low-fidelity measurements as an inexpensive proxy for a targeted property of interest. This problem arises in discovery processes that rely on screening funnels for trading off the overall costs against throughput and accuracy. Typically, individual stages in these processes are loosely connected and each one generates data at different scale and fidelity. We consider this setup holistically and demonstrate empirically that existing transfer learning techniques for graph neural networks are generally unable to harness the information from multi-fidelity cascades. Here, we propose several effective transfer learning strategies and study them in transductive and inductive settings. Our analysis involves a novel collection of more than 28 million unique experimental protein-ligand interactions across 37 targets from drug discovery by high-throughput screening and 12 quantum properties from the dataset QMugs. The results indicate that transfer learning can improve the performance on sparse tasks by up to eight times while using an order of magnitude less high-fidelity training data. Moreover, the proposed methods consistently outperform existing transfer learning strategies for graph-structured data on drug discovery and quantum mechanics datasets.

Keywords

high-throughput screening
hts
single dose
single concentration
dose response
concentration response
primary
confirmatory
screen
assay
bioassay
pubchem
pharmaceutical
industry
molecule
compound
molecular
embedding
representation
chemical space
latent space
data modalities
integration
augmentation
deep learning
machine learning
artificial intelligence
ai
ml
computational
graph neural network
gnn
graph representation learning
neural network
transfer learning
multi-fidelity
lead optimization
public
private
shallow
random forest
support vector machine
svm
rf
vgae
variational
autoencoder
aggregator
fingerprint
quantum
quantum mechanics
qm
QM7
QMugs
materials
atomic
coordinates
3D
SchNet
DimeNet
drug discovery
adaptive
readout
pooling
attention

Supplementary materials

Title
Description
Actions
Title
Supplementary Information
Description
The materials include additional figures and tables, model hyperparameters, and details about the methodology and evaluation.
Actions

Supplementary weblinks

Comments

Comments are not moderated before they are posted, but they can be removed by the site moderators if they are found to be in contravention of our Commenting Policy [opens in a new tab] - please read this policy before you post. Comments should be used for scholarly discussion of the content in question. You can find more information about how to use the commenting feature here [opens in a new tab] .
This site is protected by reCAPTCHA and the Google Privacy Policy [opens in a new tab] and Terms of Service [opens in a new tab] apply.