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Autori principali: Zhang, Na, Wang, Ziyang, Wang, Xielin, Vázquez-Lizardi, Gabriel A., Varela, Paula Piñeiro, de Aberasturi, Dorleta Jimenez, Sanchez, David E., Perea-Lopez, Nestor, Lin, Samuel, Ricker, Ryeanne, Dimitrov, Edgar, Sredenschek, Alexander J., Halanayake, Kalana D., Yeh, Yin-Ting, Mintz, Julian A., Ye, Jiarong, Huang, Sharon Xiaolei, Lu, Huaguang, Ghedin, Elodie, Hickey, Danielle Reifsnyder, Liz-Marzán, Luis M., Huang, Shengxi, Terrones, Mauricio
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2509.09851
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author Zhang, Na
Wang, Ziyang
Wang, Xielin
Vázquez-Lizardi, Gabriel A.
Varela, Paula Piñeiro
de Aberasturi, Dorleta Jimenez
Sanchez, David E.
Perea-Lopez, Nestor
Lin, Samuel
Ricker, Ryeanne
Dimitrov, Edgar
Sredenschek, Alexander J.
Halanayake, Kalana D.
Yeh, Yin-Ting
Mintz, Julian A.
Ye, Jiarong
Huang, Sharon Xiaolei
Lu, Huaguang
Ghedin, Elodie
Hickey, Danielle Reifsnyder
Liz-Marzán, Luis M.
Huang, Shengxi
Terrones, Mauricio
author_facet Zhang, Na
Wang, Ziyang
Wang, Xielin
Vázquez-Lizardi, Gabriel A.
Varela, Paula Piñeiro
de Aberasturi, Dorleta Jimenez
Sanchez, David E.
Perea-Lopez, Nestor
Lin, Samuel
Ricker, Ryeanne
Dimitrov, Edgar
Sredenschek, Alexander J.
Halanayake, Kalana D.
Yeh, Yin-Ting
Mintz, Julian A.
Ye, Jiarong
Huang, Sharon Xiaolei
Lu, Huaguang
Ghedin, Elodie
Hickey, Danielle Reifsnyder
Liz-Marzán, Luis M.
Huang, Shengxi
Terrones, Mauricio
contents Strain-level identification of viruses is critical for effective public health responses to potential outbreaks, yet current diagnostic methods often lack the necessary speed or sensitivity. Surface-enhanced Raman spectroscopy (SERS) offers great potential for fast and precise virus clarification through unique vibrational fingerprints of biological components. However, existing protocols typically operate outside of the tissue's transparent near-infrared (NIR) window, and are further limited by the intrinsic complexity of clinical viral samples, which complicates spectral analysis and recognition. Here, we report an artificial intelligence (AI)-empowered NIR-SERS platform that integrates machine learning with a rationally designed hybrid substrate: gold nanostars (AuNSt) coupled with gold-coated carbon nanotube arrays (AuCNT). This architecture generates highly localized plasmonic hot spots resonant tuned to NIR excitation, as confirmed by electron energy-loss spectroscopy (EELS), enabling effective signal amplification from viral components. Our system and protocols provide accurate classification of respiratory viruses, including influenza viruses and coronaviruses, not only at the type and subtype levels, but also the more challenging strain level. This approach overcomes the plasmonic mismatch in conventional SERS and the lack of generalizability in AI-driven diagnostics. It shows promise for enhancing rapid virus detection and identification of novel strains and outbreak response capabilities, thus potentially addressing critical challenges in global public health preparedness.
format Preprint
id arxiv_https___arxiv_org_abs_2509_09851
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine Learning Integrated Near-Infrared Surface-Enhanced Raman Spectroscopy for Accurate Strain-Level Virus Identification
Zhang, Na
Wang, Ziyang
Wang, Xielin
Vázquez-Lizardi, Gabriel A.
Varela, Paula Piñeiro
de Aberasturi, Dorleta Jimenez
Sanchez, David E.
Perea-Lopez, Nestor
Lin, Samuel
Ricker, Ryeanne
Dimitrov, Edgar
Sredenschek, Alexander J.
Halanayake, Kalana D.
Yeh, Yin-Ting
Mintz, Julian A.
Ye, Jiarong
Huang, Sharon Xiaolei
Lu, Huaguang
Ghedin, Elodie
Hickey, Danielle Reifsnyder
Liz-Marzán, Luis M.
Huang, Shengxi
Terrones, Mauricio
Chemical Physics
Strain-level identification of viruses is critical for effective public health responses to potential outbreaks, yet current diagnostic methods often lack the necessary speed or sensitivity. Surface-enhanced Raman spectroscopy (SERS) offers great potential for fast and precise virus clarification through unique vibrational fingerprints of biological components. However, existing protocols typically operate outside of the tissue's transparent near-infrared (NIR) window, and are further limited by the intrinsic complexity of clinical viral samples, which complicates spectral analysis and recognition. Here, we report an artificial intelligence (AI)-empowered NIR-SERS platform that integrates machine learning with a rationally designed hybrid substrate: gold nanostars (AuNSt) coupled with gold-coated carbon nanotube arrays (AuCNT). This architecture generates highly localized plasmonic hot spots resonant tuned to NIR excitation, as confirmed by electron energy-loss spectroscopy (EELS), enabling effective signal amplification from viral components. Our system and protocols provide accurate classification of respiratory viruses, including influenza viruses and coronaviruses, not only at the type and subtype levels, but also the more challenging strain level. This approach overcomes the plasmonic mismatch in conventional SERS and the lack of generalizability in AI-driven diagnostics. It shows promise for enhancing rapid virus detection and identification of novel strains and outbreak response capabilities, thus potentially addressing critical challenges in global public health preparedness.
title Machine Learning Integrated Near-Infrared Surface-Enhanced Raman Spectroscopy for Accurate Strain-Level Virus Identification
topic Chemical Physics
url https://arxiv.org/abs/2509.09851