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Abstract

Vibrational spectroscopy methods such as mid-infrared (MIR), near-infrared (NIR), and Raman spectroscopies have been shown to have great potential for in vivo biomedical applications, such as arthroscopic evaluation of joint injuries and degeneration. Considering that these techniques provide complementary chemical information, in this study, we hypothesized that combining the MIR, NIR, and Raman data from human osteochondral samples can improve the detection of cartilage degradation. This study evaluated 272 osteochondral samples from 18 human knee joins, comprising both healthy and damaged tissue according to the reference Osteoarthritis Research Society International grading system. We established the one-block and multi-block classification models using partial least squares discriminant analysis (PLSDA), random forest, and support vector machine (SVM) algorithms. Feature modeling by principal component analysis was tested for the SVM (PCA-SVM) models. The best one-block models were built using MIR and Raman data, discriminating healthy cartilage from damaged with an accuracy of 77.5% for MIR and 77.8% for Raman using the PCA-SVM algorithm, whereas the NIR data did not perform as well achieving only 68.5% accuracy for the best model using PCA-SVM. The multi-block approach allowed an improvement with an accuracy of 81.4% for the best model by PCA-SVM. Fusing three blocks using MIR, NIR, and Raman by multi-block PLSDA significantly improved the performance of the single-block models to 79.1% correct classification. The significance was proven by statistical testing using analysis of variance. Thus, the study suggests the potential and the complementary value of the fusion of different spectroscopic techniques and provides valuable data analysis tools for the diagnostics of cartilage health.

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Keywords

Osteoarthritis OA human cartilage Raman near-infrared NIR mid-infrared MIR spectroscopy machine learning

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References

Hunter

D.J.

Bierma-Zeinstra

. “Osteoarthritis”. Lancet. 2019. 393(10182): 1745–1759.

Hiligsmann

Reginster

J.Y.

. “The Economic Weight of Osteoarthritis in Europe”. Medicographia. 2013. 35(1): 197–202.

Kiadaliri

A.A.

Lohmander

L.S.

Moradi-Lakeh

Petersson

I.F.

Englund

. “High and Rising Burden of Hip and Knee Osteoarthritis in the Nordic Region: Findings from the Global Burden of Disease Study 2015”. Acta Orthopaedica. 2018. 89(2): 177–183.

Bennell

K.L.

Hinman

R.S.

. “A Review of the Clinical Evidence for Exercise in Osteoarthritis of the Hip and Knee”. J. Sci. Med. Sport. 2011. 14(1): 4–9.

Brittberg

Winalski

C.S.

. “Evaluation of Cartilage Injuries and Repair”. J. Bone Jt. Surg. 2003. 85(Suppl. 2): 58–69.

Brismar

B.H.

Wredmark

Movin

Leandersson

Svensson

. “Observer Reliability in the Arthroscopic Classification of Osteoarthritis of the Knee”. J. Bone Jt. Surg. Brit. 2002. 84(1): 42–47.

Spahn

Klinger

H.M.

Baums

Pinkepank

Hofmann

G.O.

. “Reliability in Arthroscopic Grading of Cartilage Lesions: Results of a Prospective Blinded Study for Evaluation of Inter-Observer Reliability”. Arch. Orthop. Unfall.-Chir. 2011. 131(3): 377–381.

Prakash

Joukainen

Torniainen

Honkanen

M.K.M.

, et al. “Near-Infrared Spectroscopy Enables Quantitative Evaluation of Human Cartilage Biomechanical Properties During Arthroscopy”. Osteoarthr. Cartil. 2019. 27(8): 1235–1243.

Sarin

J.K.

Nykänen

Tiitu

Mancini

I.A.D.

, et al. “Arthroscopic Determination of Cartilage Proteoglycan Content and Collagen Network Structure with Near-Infrared Spectroscopy”. Ann. Biomed. Eng. 2019. 47(8): 1815–1826.

10.

Sarin

J.K.

Te Moller

N.C.R.

Mancini

I.A.D.

Brommer

, et al. “Arthroscopic Near Infrared Spectroscopy Enables Simultaneous Quantitative Evaluation of Articular Cartilage and Subchondral Bone In Vivo”. Sci. Rep. 2018. 8(1): 13409–13409.

11.

Sarin

J.K.

Torniainen

Prakash

Rieppo

, et al. “Dataset on Equine Cartilage Near Infrared Spectra, Composition, and Functional Properties”. Sci. Data. 2019. 6(1): 164–164.

12.

Hanifi

Yang

Kavukcuoglu

, et al. “Infrared Fiber Optic Probe Evaluation of Degenerative Cartilage Correlates to Histological Grading”. Am. J. Sports Med. 2012. 40(12): 2853–2861.

13.

Esmonde-White

K.A.

Esmonde-White

F.W.L.

Morris

M.D.

Roessler

B.J.

. “Fiber-Optic Raman Spectroscopy of Joint Tissues”. Analyst. 2011. 136(8): 1675–1685.

14.

Rieppo

Töyräs

Saarakkala

. “Vibrational Spectroscopy of Articular Cartilage”. Appl. Spectrosc. Rev. 2017. 52(3): 249–266.

15.

Tuck

Blanc

Touti

Patterson

N.H.

, et al. “Multimodal Imaging Based on Vibrational Spectroscopies and Mass Spectrometry Imaging Applied to Biological Tissue: A Multiscale and Multiomics Review”. Anal. Chem. 2021. 93(1): 445–477.

16.

Summers

K.L.

Fimognari

Hollings

Kiernan

, et al. “A Multimodal Spectroscopic Imaging Method to Characterize the Metal and Macromolecular Content of Proteinaceous Aggregates (‘Amyloid Plaques’)”. Biochemistry. 2017. 56(32): 4107–4116.

17.

Shaikh

Tafintseva

Nippolainen

Virtanen

, et al. “Characterisation of Cartilage Damage via Fusing Mid-Infrared, Near-Infrared, and Raman Spectroscopic Data”. J. Pers. Med. 2023. 13(7): 1036.

18.

Padalkar

M.V.

Pleshko

. “Wavelength-Dependent Penetration Depth of Near Infrared Radiation into Cartilage”. Analyst. 2015. 140(7): 2093–2100.

19.

Gowen

A.A.

Dorrepaal

M.R.

. “Multivariate Chemical Image Fusion of Vibrational Spectroscopic Imaging Modalities”. Molecules. 2016. 21(7): 870.

20.

Magnussen

E.A.

Zimmermann

Blazhko

Dzurendova

, et al. “Deep Learning-Enabled Inference of 3D Molecular Absorption Distribution of Biological Cells from IR Spectra”. Commun. Chem. 2022. 5(1): 175.

21.

Zimmerman

Tafintseva

Bagcıoglu

Høegh Berdahl

Kohler

. “Analysis of Allergenic Pollen by FT-IR Microspectroscopy”. Anal. Chem. 2016. 88(1): 803–811.

22.

Wold

Hellberg

Lundstedt

Sjostrom

Wold

. “IPLS Model Building: Theory and Applications”. In: Proceedings of the Symposium on PLS Model Building: Theory and Application. Frankfurt am Main; 23–25 September 1987.

23.

Diehn

Zimmermann

Tafintseva

Seifert

, et al. “Combining Chemical Information From Grass Pollen in Multimodal Characterization”. Front. Plant Sci. 2020. 10: 1788. https://doi.org/10.3389/fpls.2019.01788

24.

Westerhuis

J.A.

Kourti

MacGregor

J.F.

. “Analysis of Multiblock and Hierarchical PCA and PLS Models”. J. Chemom. 1998. 12(5): 301–321.

25.

Curtasu

M.V.

Tafintseva

Bendiks

Z.A.

Marco

M.L.

, et al. “Obesity-Related Metabolome and Gut Microbiota Profiles of Juvenile Gottingen Minipigs-Long-Term Intake of Fructose and Resistant Starch”. Metabolites. 2020. 10(11): 456.

26.

Pritzker

K.P.H.

Gay

Jimenez

S.A.

Ostergaard

, et al. “Osteoarthritis Cartilage Histopathology: Grading and Staging”. Osteoarthr. Cartil. 2006. 14(1): 13–29.

27.

Martens

. Multivariate Analysis of Quality: An Introduction. Chichester, UK: John Wiley and Sons, 2001.

28.

Tafintseva

Lintvedt

T.A.

Solheim

J.H.

Zimmermann

, et al. “Preprocessing Strategies for Sparse Infrared Spectroscopy: A Case Study on Cartilage Diagnostics”. Molecules. 2022. 27(3): 873.

29.

Aledda

Kohler

Zimmermann

Patel

, et al. “Sparse Wavelengths Data in Mid-Infrared Spectroscopy: Modelling Approaches and Channel Sampling”. J. Biophotonics. 2023. 16(10): e202300049.

30.

Breiman

. “Random Forests”. Mach. Learning. 2001. 45(1): 5–32.

31.

Duda

R.O.

Hart

P.E.

Stork

D.G.

. Pattern Classification. Hoboken, NJ: John Wiley and Sons, 2012.

32.

Tafintseva

Vigneau

Shapaval

Cariou

, et al. “Hierarchical Classification of Microorganisms Based on High-Dimensional Phenotypic Data”. J. Biophotonics. 2018. 11(3): e201700047.

33.

Müller

Schuhmacher

Schörner

Großerueschkamp

, et al. “Dimensionality Reduction for Deep Learning in Infrared Microscopy: A Comparative Computational Survey”. Analyst. 2023. 148(20): 5022–5032.

34.

Zebari

Abdulazeez

Zeebaree

Zebari

Saeed

. “A Comprehensive Review of Dimensionality Reduction Techniques for Feature Selection and Feature Extraction”. J. Appl. Sci. Technol. Trends. 2020. 1(2): 56–70.

35.

Virtanen

Nippolainen

Shaikh

Afara

I.O.

, et al. “Infrared Fiber-Optic Spectroscopy Detects Bovine Articular Cartilage Degeneration”. Cartilage. 2021. 13(Suppl. 2): 285S–294S.

36.

Afara

I.O.

Oloyede

. “Resolving the Near-Infrared Spectrum of Articular Cartilage”. Cartilage. 2021. 13(Suppl. 1): 729S–737S.

37.

Martinez

M.G.

Bullock

A.J.

MacNeil

Rehman

I.U.

. “Characterisation of Structural Changes in Collagen with Raman Spectroscopy”. Appl. Spectrosc. Rev. 2019. 54(6): 509–542.

38.

Abdulwahab

. “Introductory Chapter: Cartilage Disorders”. In: Almqvist

El Hamaky

A.E.

Abdulwahab

, editors. Cartilage Disorders: Recent Findings and Treatment. London: IntechOpen, 2023.

39.

Pezzotti

Zhu

Terai

Marin

, et al. “Raman Spectroscopic Insight Into Osteoarthritic Cartilage Regeneration by mRNA Therapeutics Encoding Cartilage-Anabolic Transcription Factor Runx1”. Mater. Today Bio. 2022. 13: 100210.

40.

Olson

N.E.

Xiao

Lei

Ault

A.P.

. “Simultaneous Optical Photothermal Infrared (O-PTIR) and Raman Spectroscopy of Submicrometer Atmospheric Particles”. Anal. Chem. 2020. 92(14): 9932–9939.

41.

Pauli

Whiteside

Heras

F.L.

Nesic

, et al. “Comparison of Cartilage Histopathology Assessment Systems on Human Knee Joints at All Stages of Osteoarthritis Development”. Osteoarthr. Cartil. 2012. 20(6): 476–485.

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Machine Learning Approaches for the Fusion of Near-Infrared,Mid-Infrared,and Raman Data to Identify Cartilage Degradation in Human Osteochondral Plugs

Abstract

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