Multi-excitation Raman spectroscopy for label-free, strain-level characterization of bacterial pathogens in artificial sputum media
Multi-excitation Raman spectroscopy for label-free, strain-level characterization of bacterial pathogens in artificial sputum media
The current methods for diagnosis of acute and chronic infections are complex and skill-intensive. For complex clinical biofilm infections, it can take days from collecting and processing a patient’s sample to achieving a result. These aspects place a significant burden on healthcare providers, delay treatment, and can lead to adverse patient outcomes. We report the development and application of a novel multi-excitation Raman spectroscopy-based methodology for the label-free and non-invasive detection of microbial pathogens that can be used with unprocessed clinical samples directly and provide rapid data to inform diagnosis by a medical professional. The method relies on the differential excitation of non-resonant and resonant molecular components in bacterial cells to enhance the molecular finger-printing capability to obtain strain-level distinction in bacterial species. Here, we use this strategy to detect and characterize the respiratory pathogens Pseudomonas aeruginosa and Staphylococcus aureus as typical infectious agents associated with cystic fibrosis. Planktonic specimens were analyzed both in isolation and in artificial sputum media. The resonance Raman components, excited at different wavelengths, were characterized as carotenoids and porphyrins. By combining the more informative multi-excitation Raman spectra with multivariate analysis (support vector machine) the accuracy was found to be 99.75% for both species (across all strains), including 100% accuracy for drug-sensitive and drug-resistant S. aureus. The results demonstrate that our methodology based on multi-excitation Raman spectroscopy can underpin the development of a powerful platform for the rapid and reagentless detection of clinical pathogens to support diagnosis by a medical expert, in this case relevant to cystic fibrosis. Such a platform could provide translatable diagnostic solutions in a variety of disease areas and also be utilized for the rapid detection of anti-microbial resistance.
669-677
Webb, Jeremy
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Lister, Adam
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Highmore, Callum
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Hanrahan, Niall
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Read, James, Arthur
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Munro, Alasdair, Peter Stuart
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Tan, Samuel
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Allan, Raymond
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Faust, Saul
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Mahajan, Sumeet
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3 January 2022
Webb, Jeremy
ec0a5c4e-86cc-4ae9-b390-7298f5d65f8d
Lister, Adam
7a3153da-d63b-4cb9-9048-38f372dd26c7
Highmore, Callum
04809bd8-7cad-4dcf-b67d-264697f893b9
Hanrahan, Niall
df8a0edc-a5bd-4979-aa6f-0ea1bff159c3
Read, James, Arthur
d2fef987-7772-42d1-a05f-aba7f32c2871
Munro, Alasdair, Peter Stuart
9150e088-1921-4b12-9b98-289e91fa0b2b
Tan, Samuel
4333c2cc-65f5-4abc-a4b0-eefb9b4f1e4e
Allan, Raymond
390a7d0a-38e1-410a-8dfe-c8ef8408f5e1
Faust, Saul
f97df780-9f9b-418e-b349-7adf63e150c1
Mahajan, Sumeet
b131f40a-479e-4432-b662-19d60d4069e9
Webb, Jeremy, Lister, Adam, Highmore, Callum, Hanrahan, Niall, Read, James, Arthur, Munro, Alasdair, Peter Stuart, Tan, Samuel, Allan, Raymond, Faust, Saul and Mahajan, Sumeet
(2022)
Multi-excitation Raman spectroscopy for label-free, strain-level characterization of bacterial pathogens in artificial sputum media.
Analytical Chemistry, 94 (2), .
(doi:10.1021/acs.analchem.1c02501).
Abstract
The current methods for diagnosis of acute and chronic infections are complex and skill-intensive. For complex clinical biofilm infections, it can take days from collecting and processing a patient’s sample to achieving a result. These aspects place a significant burden on healthcare providers, delay treatment, and can lead to adverse patient outcomes. We report the development and application of a novel multi-excitation Raman spectroscopy-based methodology for the label-free and non-invasive detection of microbial pathogens that can be used with unprocessed clinical samples directly and provide rapid data to inform diagnosis by a medical professional. The method relies on the differential excitation of non-resonant and resonant molecular components in bacterial cells to enhance the molecular finger-printing capability to obtain strain-level distinction in bacterial species. Here, we use this strategy to detect and characterize the respiratory pathogens Pseudomonas aeruginosa and Staphylococcus aureus as typical infectious agents associated with cystic fibrosis. Planktonic specimens were analyzed both in isolation and in artificial sputum media. The resonance Raman components, excited at different wavelengths, were characterized as carotenoids and porphyrins. By combining the more informative multi-excitation Raman spectra with multivariate analysis (support vector machine) the accuracy was found to be 99.75% for both species (across all strains), including 100% accuracy for drug-sensitive and drug-resistant S. aureus. The results demonstrate that our methodology based on multi-excitation Raman spectroscopy can underpin the development of a powerful platform for the rapid and reagentless detection of clinical pathogens to support diagnosis by a medical expert, in this case relevant to cystic fibrosis. Such a platform could provide translatable diagnostic solutions in a variety of disease areas and also be utilized for the rapid detection of anti-microbial resistance.
Text
20211119 - Multi-excitation paper_revised_final
- Accepted Manuscript
Text
20211119 - Multi-excitation paper_SI_revised_final
- Accepted Manuscript
More information
Accepted/In Press date: 7 December 2021
e-pub ahead of print date: 3 January 2022
Published date: 3 January 2022
Additional Information:
Funding Information:
The authors would like to acknowledge the industrial CASE studentship funding to A.P.L. by the EPSRC (EP/P510646/1) and the United Kingdom Ministry of Defence under contract DSTLX-10000110975. We also acknowledge funding by the BRC-NAMRIP University of Southampton and the NIHR Southampton Antimicrobial Resistance Laboratory. S.M. acknowledges EPSRC grant EP/T020997/1 and ERC NanoChemBioVision (638258). J.S.W. and C.J.H. acknowledge funding from the BBSRC and Innovate UK, IKC National Biofilms Innovation Centre BB/R012415/1. S.N.F. is an NIHR Senior Investigator.
Publisher Copyright:
© 2022 American Chemical Society
Identifiers
Local EPrints ID: 454598
URI: http://eprints.soton.ac.uk/id/eprint/454598
ISSN: 0003-2700
PURE UUID: 23faaff2-f950-4415-ab51-08b8ee5fd6a0
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Date deposited: 17 Feb 2022 17:31
Last modified: 17 Mar 2024 07:02
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Contributors
Author:
Adam Lister
Author:
Niall Hanrahan
Author:
James, Arthur Read
Author:
Alasdair, Peter Stuart Munro
Author:
Samuel Tan
Author:
Raymond Allan
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