Classifying Pre-Radiographic Osteoarthritis of the Knee Using Wearable Acoustics Sensing at the Point of Care

Overview

Journal IEEE Sens J

Date 2024 Nov 7

PMID 39507235

Authors

Christopher J Nichols

Goktug C Ozmen

Kristine Richardson

Omer T Inan

Dave Ewart

Affiliations

Soon will be listed here.

Abstract

This study was undertaken to determine if knee acoustic emissions (KAE) measured at the point of care with a wearable device can classify knees with pre-radiographic osteoarthritis (pre-OA) from healthy knees. We performed a single-center cross-sectional observational study comparing KAE in healthy knees to knees with clinical symptoms compatible with knee OA that did not meet classification criteria for radiographic knee OA. KAE were measured during scripted maneuvers performed in clinic exam rooms or similarly noisy medical center locations in healthy (n=20), pre-OA (n=11), and, for comparison, OA (n=12) knees. Acoustic features were extracted from the KAE and used to train models to classify pre-OA, OA, and control knees with logistic regression. Model performance was measured and optimized with Leave-One-Out Cross-Validation. Regressive sensitivity analysis was performed to combine acoustic information from individual maneuvers to further optimize performance. Test-retest reliability of KAE was measured with intraclass correlation analysis. Classification models trained with KAE were accurate for both pre-OA and OA (94% accurate, 0.96 and 0.99 area under a receiver operating characteristic curve (AUC), respectively). Acoustic features selected for use in the optimized models had high test-retest reliability by intrasession and intersession intraclass correlation analysis (mean intraclass correlation coefficient 0.971 +/- 0.08 standard deviation). Analysis of KAE measured in acoustically uncontrolled medical settings using an easily accessible wearable device accurately classified pre-OA knees from healthy control knees in our small cohort. Accessible methods of identifying pre-OA could enable regular joint health monitoring and improve OA treatment and rehabilitation outcomes.

Citing Articles

Validating Joint Acoustic Emissions Models as a Generalizable Predictor of Joint Health.

Richardson K, Nichols C, Stegeman R, Zachs D, Tuma A, Heller J IEEE Sens J. 2024; 24(10):17219-17230.

PMID: 39507379 PMC: 11539186. DOI: 10.1109/jsen.2024.3382613.

Correlation between proprioception, functionality, patient-reported knee condition and joint acoustic emissions.

Khokhlova L, Komaris D, OFlynn B, Tedesco S PLoS One. 2024; 19(11):e0310123.

PMID: 39504329 PMC: 11540232. DOI: 10.1371/journal.pone.0310123.

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