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Auteurs principaux: Martinez-Serra, Alberto, Marchetti, Gionni, D'Amico, Francesco, Fenoglio, Ivana, Rossi, Barbara, Monopoli, Marco P., Franzese, Giancarlo
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2505.06466
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author Martinez-Serra, Alberto
Marchetti, Gionni
D'Amico, Francesco
Fenoglio, Ivana
Rossi, Barbara
Monopoli, Marco P.
Franzese, Giancarlo
author_facet Martinez-Serra, Alberto
Marchetti, Gionni
D'Amico, Francesco
Fenoglio, Ivana
Rossi, Barbara
Monopoli, Marco P.
Franzese, Giancarlo
contents When nanoparticles (NPs) are introduced into a biological solution, layers of biomolecules form on their surface, creating a corona. Understanding how the structure of the protein evolves into the corona is essential for evaluating the safety and toxicity of nanotechnology. However, the influence of NP properties on protein conformation is not well understood. In this study, we propose a new method that addresses this issue by analyzing multi-component spectral data using Machine Learning (ML). We apply the method to fibrinogen, a crucial protein in human blood plasma, at physiological concentrations while interacting with hydrophobic carbon or hydrophilic silicon dioxide NPs, revealing striking differences in the temperature dependence of the protein structure between the two cases. Our unsupervised ML method a) does not suffer from the challenges associated with the curse of dimensionality, and b) simultaneously handles spectral data from various sources. The method offers a quantitative analysis of protein structural changes upon adsorption and enhances the understanding of the correlation between protein structure and NP interactions, which could support the development of nanomedical tools to treat various conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2505_06466
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Machine Learning Tool to Analyse Spectroscopic Changes in High-Dimensional Data
Martinez-Serra, Alberto
Marchetti, Gionni
D'Amico, Francesco
Fenoglio, Ivana
Rossi, Barbara
Monopoli, Marco P.
Franzese, Giancarlo
Statistical Mechanics
Quantitative Methods
When nanoparticles (NPs) are introduced into a biological solution, layers of biomolecules form on their surface, creating a corona. Understanding how the structure of the protein evolves into the corona is essential for evaluating the safety and toxicity of nanotechnology. However, the influence of NP properties on protein conformation is not well understood. In this study, we propose a new method that addresses this issue by analyzing multi-component spectral data using Machine Learning (ML). We apply the method to fibrinogen, a crucial protein in human blood plasma, at physiological concentrations while interacting with hydrophobic carbon or hydrophilic silicon dioxide NPs, revealing striking differences in the temperature dependence of the protein structure between the two cases. Our unsupervised ML method a) does not suffer from the challenges associated with the curse of dimensionality, and b) simultaneously handles spectral data from various sources. The method offers a quantitative analysis of protein structural changes upon adsorption and enhances the understanding of the correlation between protein structure and NP interactions, which could support the development of nanomedical tools to treat various conditions.
title A Machine Learning Tool to Analyse Spectroscopic Changes in High-Dimensional Data
topic Statistical Mechanics
Quantitative Methods
url https://arxiv.org/abs/2505.06466