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A novel spectral barcoding and classification approach for complex biological samples using multiexcitation Raman spectroscopy (MX-Raman)

A novel spectral barcoding and classification approach for complex biological samples using multiexcitation Raman spectroscopy (MX-Raman)
A novel spectral barcoding and classification approach for complex biological samples using multiexcitation Raman spectroscopy (MX-Raman)
We report the development and application of a novel spectral barcoding approach that exploits our multiexcitation (MX) Raman spectroscopy-based methodology for improved label-free detection and classification of complex biological samples. To develop our improved MX-Raman methodology, we utilized post-mortem brain tissue from several neurodegenerative diseases (NDDs) that have considerable clinical overlap. For improving our methodology we used three sources of spectral information arising from distinct physical phenomena to assess which was most important for NDD classification. Spectral measurements utilized combinations of data from multiple, distinct excitation laser wavelengths and polarization states to differentially probe molecular vibrations and autofluorescence signals. We demonstrate that the more informative MX-Raman (532 nm–785 nm) spectra are classified with 96.7% accuracy on average, compared to conventional single-excitation Raman spectroscopy that resulted in 78.5% accuracy (532 nm) or 85.6% accuracy (785 nm) using linear discriminant analysis (LDA) on 5 NDD classes. By combining information from distinct laser polarizations we observed a nonsignificant increase in classification accuracy without the need of a second laser (785 nm–785 nm polarized), whereas combining Raman spectra with autofluorescence signals did not increase classification accuracy. Finally, by filtering out spectral features that were redundant for classification or not descriptive of disease class, we engineered spectral barcodes consisting of a minimal subset of highly disease-specific MX-Raman features that improved the unsupervised and cross-validated clustering of MX-Raman spectra. The results demonstrate that increasing spectral information content using our optical MX-Raman methodology enables enhanced identification and distinction of complex biological samples but only when that information is independent and descriptive of class. The future translation of such technology to biofluids could support diagnosis and stratification of patients living with dementia and potentially other clinical conditions such as cancer and infectious disease.
0003-2700
12189-12197
Devitt, George
088c46c0-9dcf-4c83-acfd-16c6c9d0ca88
Hanrahan, Niall
df8a0edc-a5bd-4979-aa6f-0ea1bff159c3
Ramirez Moreno, Miguel
22b64166-df15-46e0-b5a5-2e99ea81d0da
Mudher, Amritpal
ce0ccb35-ac49-4b6c-92b4-8dd5e78ac119
Mahajan, Sumeet
b131f40a-479e-4432-b662-19d60d4069e9
Devitt, George
088c46c0-9dcf-4c83-acfd-16c6c9d0ca88
Hanrahan, Niall
df8a0edc-a5bd-4979-aa6f-0ea1bff159c3
Ramirez Moreno, Miguel
22b64166-df15-46e0-b5a5-2e99ea81d0da
Mudher, Amritpal
ce0ccb35-ac49-4b6c-92b4-8dd5e78ac119
Mahajan, Sumeet
b131f40a-479e-4432-b662-19d60d4069e9

Devitt, George, Hanrahan, Niall, Ramirez Moreno, Miguel, Mudher, Amritpal and Mahajan, Sumeet (2025) A novel spectral barcoding and classification approach for complex biological samples using multiexcitation Raman spectroscopy (MX-Raman). Analytical Chemistry, 97 (23), 12189-12197. (doi:10.1021/acs.analchem.5c00776).

Record type: Article

Abstract

We report the development and application of a novel spectral barcoding approach that exploits our multiexcitation (MX) Raman spectroscopy-based methodology for improved label-free detection and classification of complex biological samples. To develop our improved MX-Raman methodology, we utilized post-mortem brain tissue from several neurodegenerative diseases (NDDs) that have considerable clinical overlap. For improving our methodology we used three sources of spectral information arising from distinct physical phenomena to assess which was most important for NDD classification. Spectral measurements utilized combinations of data from multiple, distinct excitation laser wavelengths and polarization states to differentially probe molecular vibrations and autofluorescence signals. We demonstrate that the more informative MX-Raman (532 nm–785 nm) spectra are classified with 96.7% accuracy on average, compared to conventional single-excitation Raman spectroscopy that resulted in 78.5% accuracy (532 nm) or 85.6% accuracy (785 nm) using linear discriminant analysis (LDA) on 5 NDD classes. By combining information from distinct laser polarizations we observed a nonsignificant increase in classification accuracy without the need of a second laser (785 nm–785 nm polarized), whereas combining Raman spectra with autofluorescence signals did not increase classification accuracy. Finally, by filtering out spectral features that were redundant for classification or not descriptive of disease class, we engineered spectral barcodes consisting of a minimal subset of highly disease-specific MX-Raman features that improved the unsupervised and cross-validated clustering of MX-Raman spectra. The results demonstrate that increasing spectral information content using our optical MX-Raman methodology enables enhanced identification and distinction of complex biological samples but only when that information is independent and descriptive of class. The future translation of such technology to biofluids could support diagnosis and stratification of patients living with dementia and potentially other clinical conditions such as cancer and infectious disease.

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Accepted/In Press date: 28 May 2025
Published date: 3 June 2025
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Identifiers

Local EPrints ID: 502981
URI: http://eprints.soton.ac.uk/id/eprint/502981
DOI: doi:10.1021/acs.analchem.5c00776
ISSN: 0003-2700
PURE UUID: feba5869-2541-49bf-9e62-3d27aaba2bb4
ORCID for George Devitt: ORCID iD orcid.org/0000-0001-7179-4459
ORCID for Niall Hanrahan: ORCID iD orcid.org/0000-0002-3596-7049
ORCID for Miguel Ramirez Moreno: ORCID iD orcid.org/0000-0003-1559-8976
ORCID for Sumeet Mahajan: ORCID iD orcid.org/0000-0001-8923-6666

Catalogue record

Date deposited: 15 Jul 2025 16:52
Last modified: 22 Aug 2025 02:37

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Contributors

Author: George Devitt ORCID iD
Author: Niall Hanrahan ORCID iD
Author: Miguel Ramirez Moreno ORCID iD
Author: Amritpal Mudher
Author: Sumeet Mahajan ORCID iD

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