Holistic vibrational spectromics assessment of human cartilage for osteoarthritis diagnosis
Holistic vibrational spectromics assessment of human cartilage for osteoarthritis diagnosis
Osteoarthritis (OA) is the most common degenerative joint disease, presented as wearing down of articular cartilage and resulting in pain and limited mobility for 1 in 10 adults in the UK [Osteoarthr. Cartil. 28(6), 792 (2020) [CrossRef] ]. There is an unmet need for patient friendly paradigms for clinical assessment that do not use ionizing radiation (CT), exogenous contrast enhancing dyes (MRI), and biopsy. Hence, techniques that use non-destructive, near- and shortwave infrared light (NIR, SWIR) may be ideal for providing label-free, deep tissue interrogation. This study demonstrates multimodal “spectromics”, low-level abstraction data fusion of non-destructive NIR Raman scattering spectroscopy and NIR-SWIR absorption spectroscopy, providing an enhanced, interpretable “fingerprint” for diagnosis of OA in human cartilage. This is proposed as method level innovation applicable to both arthro- or endoscopic (minimally invasive) or potential exoscopic (non-invasive) optical approaches. Samples were excised from femoral heads post hip arthroplasty from OA patients (n = 13) and age-matched control (osteoporosis) patients (n = 14). Under multivariate statistical analysis and supervised machine learning, tissue was classified to high precision: 100% segregation of tissue classes (using 10 principal components), and a classification accuracy of 95% (control) and 80% (OA), using the combined vibrational data. There was a marked performance improvement (5 to 6-fold for multivariate analysis) using the spectromics fingerprint compared to results obtained from solely Raman or NIR-SWIR data. Furthermore, clinically relevant tissue components were identified through discriminatory spectral features – spectromics biomarkers – allowing interpretable feedback from the enhanced fingerprint. In summary, spectromics provides comprehensive information for early OA detection and disease stratification, imperative for effective intervention in treating the degenerative onset disease for an aging demographic. This novel and elegant approach for data fusion is compatible with various NIR-SWIR optical devices that will allow deep non-destructive penetration.
4264-4280
Cook, Hiroki
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Crisford, Anna
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Bourdakos, Konstantinos
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Dunlop, Doug
5f8d8b5c-e516-48b8-831f-c6e5529a52cc
Oreffo, Richard O.C.
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Mahajan, Sumeet
b131f40a-479e-4432-b662-19d60d4069e9
13 June 2024
Cook, Hiroki
f1bbf7c2-e380-4bb7-8464-67e6aa987e44
Crisford, Anna
135675e1-a172-4d93-989b-93d1efb022c3
Bourdakos, Konstantinos
83f6fc3a-db12-476b-9a78-4aad8756f82f
Dunlop, Doug
5f8d8b5c-e516-48b8-831f-c6e5529a52cc
Oreffo, Richard O.C.
ff9fff72-6855-4d0f-bfb2-311d0e8f3778
Mahajan, Sumeet
b131f40a-479e-4432-b662-19d60d4069e9
Cook, Hiroki, Crisford, Anna, Bourdakos, Konstantinos, Dunlop, Doug, Oreffo, Richard O.C. and Mahajan, Sumeet
(2024)
Holistic vibrational spectromics assessment of human cartilage for osteoarthritis diagnosis.
Biomedical Optics Express, 15 (7), .
(doi:10.1364/BOE.520171).
Abstract
Osteoarthritis (OA) is the most common degenerative joint disease, presented as wearing down of articular cartilage and resulting in pain and limited mobility for 1 in 10 adults in the UK [Osteoarthr. Cartil. 28(6), 792 (2020) [CrossRef] ]. There is an unmet need for patient friendly paradigms for clinical assessment that do not use ionizing radiation (CT), exogenous contrast enhancing dyes (MRI), and biopsy. Hence, techniques that use non-destructive, near- and shortwave infrared light (NIR, SWIR) may be ideal for providing label-free, deep tissue interrogation. This study demonstrates multimodal “spectromics”, low-level abstraction data fusion of non-destructive NIR Raman scattering spectroscopy and NIR-SWIR absorption spectroscopy, providing an enhanced, interpretable “fingerprint” for diagnosis of OA in human cartilage. This is proposed as method level innovation applicable to both arthro- or endoscopic (minimally invasive) or potential exoscopic (non-invasive) optical approaches. Samples were excised from femoral heads post hip arthroplasty from OA patients (n = 13) and age-matched control (osteoporosis) patients (n = 14). Under multivariate statistical analysis and supervised machine learning, tissue was classified to high precision: 100% segregation of tissue classes (using 10 principal components), and a classification accuracy of 95% (control) and 80% (OA), using the combined vibrational data. There was a marked performance improvement (5 to 6-fold for multivariate analysis) using the spectromics fingerprint compared to results obtained from solely Raman or NIR-SWIR data. Furthermore, clinically relevant tissue components were identified through discriminatory spectral features – spectromics biomarkers – allowing interpretable feedback from the enhanced fingerprint. In summary, spectromics provides comprehensive information for early OA detection and disease stratification, imperative for effective intervention in treating the degenerative onset disease for an aging demographic. This novel and elegant approach for data fusion is compatible with various NIR-SWIR optical devices that will allow deep non-destructive penetration.
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boe-15-7-4264
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Accepted/In Press date: 31 May 2024
Published date: 13 June 2024
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Local EPrints ID: 493361
URI: http://eprints.soton.ac.uk/id/eprint/493361
ISSN: 2156-7085
PURE UUID: ff2a5dc1-d335-494a-81ad-0e573ad779da
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Date deposited: 30 Aug 2024 16:36
Last modified: 31 Aug 2024 01:48
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Author:
Hiroki Cook
Author:
Konstantinos Bourdakos
Author:
Doug Dunlop
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