Infrared Spectroscopy Can Differentiate Between Cartilage Injury Models: Implication for Assessment of Cartilage Integrity

Publication date

2024

Authors

Shahini, Fatemeh
Oskouei, Soroush
Nippolainen, Ervin
Mohammadi, Ali
Sarin, Jaakko K
te Moller, NikaeORCID 0000-0001-8675-330XISNI 0000000492512440
Brommer, HaroldISNI 0000000395220112
Shaikh, Rubina
Korhonen, Rami K
van Weeren, RenéORCID 0000-0002-6654-1817ISNI 0000000390951215

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Advisors

Supervisors

Document Type

Article
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License

cc_by

Abstract

In order to improve the ability of clinical diagnosis to differentiate articular cartilage (AC) injury of different origins, this study explores the sensitivity of mid-infrared (MIR) spectroscopy for detecting structural, compositional, and functional changes in AC resulting from two injury types. Three grooves (two in parallel in the palmar-dorsal direction and one in the mediolateral direction) were made via arthrotomy in the AC of the radial facet of the third carpal bone (middle carpal joint) and of the intermediate carpal bone (the radiocarpal joint) of nine healthy adult female Shetland ponies (age = 6.8 ± 2.6 years; range 4-13 years) using blunt and sharp tools. The defects were randomly assigned to each of the two joints. Ponies underwent a 3-week box rest followed by 8 weeks of treadmill training and 26 weeks of free pasture exercise before being euthanized for osteochondral sample collection. The osteochondral samples underwent biomechanical indentation testing, followed by MIR spectroscopic assessment. Digital densitometry was conducted afterward to estimate the tissue's proteoglycan (PG) content. Subsequently, machine learning models were developed to classify the samples to estimate their biomechanical properties and PG content based on the MIR spectra according to injury type. Results show that MIR is able to discriminate healthy from injured AC (91%) and between injury types (88%). The method can also estimate AC properties with relatively low error (thickness = 12.7% mm, equilibrium modulus = 10.7% MPa, instantaneous modulus = 11.8% MPa). These findings demonstrate the potential of MIR spectroscopy as a tool for assessment of AC integrity changes that result from injury.

Keywords

Articular cartilage, Chondral groove model, Equine, Machine learning, Mid-infrared spectroscopy, Osteoarthritis, Biomedical Engineering

Citation

Shahini, F, Oskouei, S, Nippolainen, E, Mohammadi, A, Sarin, J K, Moller, N C R T, Brommer, H, Shaikh, R, Korhonen, R K, van Weeren, P R, Töyräs, J & Afara, I O 2024, 'Infrared Spectroscopy Can Differentiate Between Cartilage Injury Models : Implication for Assessment of Cartilage Integrity', Annals of Biomedical Engineering, vol. 52, no. 9, pp. 2521–2533. https://doi.org/10.1007/s10439-024-03540-x