DENSE SENSE: A novel approach utilizing an electron density augmented machine learning paradigm to understand a complex odour landscape

Pinaki Saha; Mrityunjay  Sharma; Sarabeshwar Balaji; Aryan Amit Barsainyan; Ritesh Kumar; Volker Steuber; Michael Schmuker

doi:10.1039/D5DD00224A

DENSE SENSE: A novel approach utilizing an electron density augmented machine learning paradigm to understand a complex odour landscape

Pinaki Saha
, Mrityunjay Sharma
, Sarabeshwar Balaji
, Aryan Amit Barsainyan
, Ritesh Kumar
, Volker Steuber
, Michael Schmuker

Research output: Contribution to journal › Article › peer-review

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Abstract

Olfaction is a complex process where multiple nasal receptors interact to detect specific odorant molecules. Elucidating structure–activity-relationships for odorants and their receptors remains difficult since crystallization of the odor receptors is an extremely difficult process. Therefore, ligand-based approaches that leverage machine learning remain the state of the art for predicting odorant properties for molecules, such as the graph neural network approach used by Lee et al. In this paper we explored how information from quantum mechanics (QM) could synergistically improve the results obtained with the graph neural network. Our findings underscore the possibility of this methodology in predicting odor perception directly from QM data, offering a novel approach in the machine learning space to understand olfaction.

Original language	English
Pages (from-to)	3339-3350
Number of pages	12
Journal	Digital Discovery
Volume	4
Issue number	11
DOIs	https://doi.org/10.1039/D5DD00224A
Publication status	Published - 8 Oct 2025

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title = "DENSE SENSE: A novel approach utilizing an electron density augmented machine learning paradigm to understand a complex odour landscape",

abstract = "Olfaction is a complex process where multiple nasal receptors interact to detect specific odorant molecules. Elucidating structure–activity-relationships for odorants and their receptors remains difficult since crystallization of the odor receptors is an extremely difficult process. Therefore, ligand-based approaches that leverage machine learning remain the state of the art for predicting odorant properties for molecules, such as the graph neural network approach used by Lee et al. In this paper we explored how information from quantum mechanics (QM) could synergistically improve the results obtained with the graph neural network. Our findings underscore the possibility of this methodology in predicting odor perception directly from QM data, offering a novel approach in the machine learning space to understand olfaction.",

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AU - Barsainyan, Aryan Amit

AU - Kumar, Ritesh

AU - Steuber, Volker

AU - Schmuker, Michael

N1 - © 2025 The Author(s). Published by the Royal Society of Chemistry. Open Access Article. This article is licensed under a Creative Commons 3.0 Unported License. https://creativecommons.org/licenses/by/3.0/

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AB - Olfaction is a complex process where multiple nasal receptors interact to detect specific odorant molecules. Elucidating structure–activity-relationships for odorants and their receptors remains difficult since crystallization of the odor receptors is an extremely difficult process. Therefore, ligand-based approaches that leverage machine learning remain the state of the art for predicting odorant properties for molecules, such as the graph neural network approach used by Lee et al. In this paper we explored how information from quantum mechanics (QM) could synergistically improve the results obtained with the graph neural network. Our findings underscore the possibility of this methodology in predicting odor perception directly from QM data, offering a novel approach in the machine learning space to understand olfaction.

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DENSE SENSE: A novel approach utilizing an electron density augmented machine learning paradigm to understand a complex odour landscape

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