Pixelated High-Q Metasurfaces for in Situ Biospectroscopy and Artificial Intelligence-Enabled Classification of Lipid Membrane Photoswitching Dynamics

Martin Barkey; Rebecca Büchner; Alwin Wester; Stefanie D. Pritzl; Maksim Makarenko; Qizhou Wang; Thomas Weber; Dirk Trauner; Stefan A. Maier; Andrea Fratalocchi; Theobald Lohmüller; Andreas Tittl

doi:10.1021/acsnano.3c09798

Pixelated High-Q Metasurfaces for in Situ Biospectroscopy and Artificial Intelligence-Enabled Classification of Lipid Membrane Photoswitching Dynamics

Martin Barkey
, Rebecca Büchner
, Alwin Wester
, Stefanie D. Pritzl
, Maksim Makarenko
, Qizhou Wang
, Thomas Weber
, Dirk Trauner
, Stefan A. Maier
, Andrea Fratalocchi
, Theobald Lohmüller
, Andreas Tittl^*

^*Corresponding author for this work

Sub Molecular Biophysics

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

Abstract

Nanophotonic devices excel at confining light into intense hot spots of electromagnetic near fields, creating exceptional opportunities for light-matter coupling and surface-enhanced sensing. Recently, all-dielectric metasurfaces with ultrasharp resonances enabled by photonic bound states in the continuum (BICs) have unlocked additional functionalities for surface-enhanced biospectroscopy by precisely targeting and reading out the molecular absorption signatures of diverse molecular systems. However, BIC-driven molecular spectroscopy has so far focused on end point measurements in dry conditions, neglecting the crucial interaction dynamics of biological systems. Here, we combine the advantages of pixelated all-dielectric metasurfaces with deep learning-enabled feature extraction and prediction to realize an integrated optofluidic platform for time-resolved in situ biospectroscopy. Our approach harnesses high-Q metasurfaces specifically designed for operation in a lossy aqueous environment together with advanced spectral sampling techniques to temporally resolve the dynamic behavior of photoswitchable lipid membranes. Enabled by a software convolutional neural network, we further demonstrate the real-time classification of the characteristic cis and trans membrane conformations with 98% accuracy. Our synergistic sensing platform incorporating metasurfaces, optofluidics, and deep learning reveals exciting possibilities for studying multimolecular biological systems, ranging from the behavior of transmembrane proteins to the dynamic processes associated with cellular communication.

Original language	English
Pages (from-to)	11644-11654
Number of pages	11
Journal	ACS Nano
Volume	18
Issue number	18
DOIs	https://doi.org/10.1021/acsnano.3c09798
Publication status	Published - 7 May 2024

Bibliographical note

Publisher Copyright:
© 2024 The Authors. Published by American Chemical Society.

Funding

This project was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant numbers EXC 2089/1-390776260 (Germany's Excellence Strategy), TI 1063/1 (Emmy Noether Program), and the Collaborative Research Center - SFB1032 (Project No. 201269156, project A8). We further acknowledge the Bavarian program Solar Technologies Go Hybrid (SolTech) and the Center for NanoScience (CeNS). Funded by the European Union (ERC, METANEXT, 101078018, and EIC, NEHO, 101046329). Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union, the European Research Council Executive Agency, or the SMEs Executive Agency (EISMEA). Neither the European Union nor the granting authority can be held responsible for them. S.A.M. additionally acknowledges the Lee-Lucas Chair in Physics and S.D.P acknowledges the European Research Council Consolidator Grant "ProForce".

Funders	Funder number
H2020 European Research Council	EXC 2089/1-390776260, TI 1063/1, SFB1032, 201269156
Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)
Bavarian program Solar Technologies Go Hybrid (SolTech)
Center for NanoScience (CeNS)	101078018, 101046329
European Union (ERC)
European Research Council Consolidator Grant "ProForce"

Keywords

biosensing
bound states in the continuum
deep learning
dielectric metasurfaces
surface-enhanced spectroscopy

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10.1021/acsnano.3c09798Licence: CC BY

barkey-et-al-2024-pixelated-high-q-metasurfaces-for-in-situ-biospectroscopy-and-artificial-intelligence-enabledFinal published version, 4.18 MBLicence: CC BY

Cite this

Barkey, M., Büchner, R., Wester, A., Pritzl, S. D., Makarenko, M., Wang, Q., Weber, T., Trauner, D., Maier, S. A., Fratalocchi, A., Lohmüller, T., & Tittl, A. (2024). Pixelated High-Q Metasurfaces for in Situ Biospectroscopy and Artificial Intelligence-Enabled Classification of Lipid Membrane Photoswitching Dynamics. ACS Nano, 18(18), 11644-11654. https://doi.org/10.1021/acsnano.3c09798

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title = "Pixelated High-Q Metasurfaces for in Situ Biospectroscopy and Artificial Intelligence-Enabled Classification of Lipid Membrane Photoswitching Dynamics",

abstract = "Nanophotonic devices excel at confining light into intense hot spots of electromagnetic near fields, creating exceptional opportunities for light-matter coupling and surface-enhanced sensing. Recently, all-dielectric metasurfaces with ultrasharp resonances enabled by photonic bound states in the continuum (BICs) have unlocked additional functionalities for surface-enhanced biospectroscopy by precisely targeting and reading out the molecular absorption signatures of diverse molecular systems. However, BIC-driven molecular spectroscopy has so far focused on end point measurements in dry conditions, neglecting the crucial interaction dynamics of biological systems. Here, we combine the advantages of pixelated all-dielectric metasurfaces with deep learning-enabled feature extraction and prediction to realize an integrated optofluidic platform for time-resolved in situ biospectroscopy. Our approach harnesses high-Q metasurfaces specifically designed for operation in a lossy aqueous environment together with advanced spectral sampling techniques to temporally resolve the dynamic behavior of photoswitchable lipid membranes. Enabled by a software convolutional neural network, we further demonstrate the real-time classification of the characteristic cis and trans membrane conformations with 98\% accuracy. Our synergistic sensing platform incorporating metasurfaces, optofluidics, and deep learning reveals exciting possibilities for studying multimolecular biological systems, ranging from the behavior of transmembrane proteins to the dynamic processes associated with cellular communication.",

keywords = "biosensing, bound states in the continuum, deep learning, dielectric metasurfaces, surface-enhanced spectroscopy",

author = "Martin Barkey and Rebecca B{\"u}chner and Alwin Wester and Pritzl, \{Stefanie D.\} and Maksim Makarenko and Qizhou Wang and Thomas Weber and Dirk Trauner and Maier, \{Stefan A.\} and Andrea Fratalocchi and Theobald Lohm{\"u}ller and Andreas Tittl",

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year = "2024",

month = may,

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doi = "10.1021/acsnano.3c09798",

language = "English",

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Barkey, M, Büchner, R, Wester, A, Pritzl, SD, Makarenko, M, Wang, Q, Weber, T, Trauner, D, Maier, SA, Fratalocchi, A, Lohmüller, T & Tittl, A 2024, 'Pixelated High-Q Metasurfaces for in Situ Biospectroscopy and Artificial Intelligence-Enabled Classification of Lipid Membrane Photoswitching Dynamics', ACS Nano, vol. 18, no. 18, pp. 11644-11654. https://doi.org/10.1021/acsnano.3c09798

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AU - Barkey, Martin

AU - Büchner, Rebecca

AU - Wester, Alwin

AU - Pritzl, Stefanie D.

AU - Makarenko, Maksim

AU - Wang, Qizhou

AU - Weber, Thomas

AU - Trauner, Dirk

AU - Maier, Stefan A.

AU - Fratalocchi, Andrea

AU - Lohmüller, Theobald

AU - Tittl, Andreas

PY - 2024/5/7

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N2 - Nanophotonic devices excel at confining light into intense hot spots of electromagnetic near fields, creating exceptional opportunities for light-matter coupling and surface-enhanced sensing. Recently, all-dielectric metasurfaces with ultrasharp resonances enabled by photonic bound states in the continuum (BICs) have unlocked additional functionalities for surface-enhanced biospectroscopy by precisely targeting and reading out the molecular absorption signatures of diverse molecular systems. However, BIC-driven molecular spectroscopy has so far focused on end point measurements in dry conditions, neglecting the crucial interaction dynamics of biological systems. Here, we combine the advantages of pixelated all-dielectric metasurfaces with deep learning-enabled feature extraction and prediction to realize an integrated optofluidic platform for time-resolved in situ biospectroscopy. Our approach harnesses high-Q metasurfaces specifically designed for operation in a lossy aqueous environment together with advanced spectral sampling techniques to temporally resolve the dynamic behavior of photoswitchable lipid membranes. Enabled by a software convolutional neural network, we further demonstrate the real-time classification of the characteristic cis and trans membrane conformations with 98% accuracy. Our synergistic sensing platform incorporating metasurfaces, optofluidics, and deep learning reveals exciting possibilities for studying multimolecular biological systems, ranging from the behavior of transmembrane proteins to the dynamic processes associated with cellular communication.

AB - Nanophotonic devices excel at confining light into intense hot spots of electromagnetic near fields, creating exceptional opportunities for light-matter coupling and surface-enhanced sensing. Recently, all-dielectric metasurfaces with ultrasharp resonances enabled by photonic bound states in the continuum (BICs) have unlocked additional functionalities for surface-enhanced biospectroscopy by precisely targeting and reading out the molecular absorption signatures of diverse molecular systems. However, BIC-driven molecular spectroscopy has so far focused on end point measurements in dry conditions, neglecting the crucial interaction dynamics of biological systems. Here, we combine the advantages of pixelated all-dielectric metasurfaces with deep learning-enabled feature extraction and prediction to realize an integrated optofluidic platform for time-resolved in situ biospectroscopy. Our approach harnesses high-Q metasurfaces specifically designed for operation in a lossy aqueous environment together with advanced spectral sampling techniques to temporally resolve the dynamic behavior of photoswitchable lipid membranes. Enabled by a software convolutional neural network, we further demonstrate the real-time classification of the characteristic cis and trans membrane conformations with 98% accuracy. Our synergistic sensing platform incorporating metasurfaces, optofluidics, and deep learning reveals exciting possibilities for studying multimolecular biological systems, ranging from the behavior of transmembrane proteins to the dynamic processes associated with cellular communication.

KW - biosensing

KW - bound states in the continuum

KW - deep learning

KW - dielectric metasurfaces

KW - surface-enhanced spectroscopy

UR - https://www.scopus.com/pages/publications/85191942937

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IS - 18

ER -

Pixelated High-Q Metasurfaces for in Situ Biospectroscopy and Artificial Intelligence-Enabled Classification of Lipid Membrane Photoswitching Dynamics

Abstract

Bibliographical note

Funding

Keywords

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