Abstract
BackgroundPrevalence for knee osteoarthritis is rising in both Sweden and globally due to increased age and obesity in the population. This has subsequently led to an increasing demand for knee arthroplasties. Correct diagnosis and classification of a knee osteoarthritis (OA) are therefore of a great interest in following-up and planning for either conservative or operative management. Most orthopedic surgeons rely on standard weight bearing radiographs of the knee. Improving the reliability and reproducibility of these interpretations could thus be hugely beneficial. Recently, deep learning which is a form of artificial intelligence (AI), has been showing promising results in interpreting radiographic images. In this study, we aim to evaluate how well an AI can classify the severity of knee OA, using entire image series and not excluding common visual disturbances such as an implant, cast and non-degenerative pathologies.MethodsWe selected 6103 radiographic exams of the knee taken at Danderyd University Hospital between the years 2002-2016 and manually categorized them according to the Kellgren & Lawrence grading scale (KL). We then trained a convolutional neural network (CNN) of ResNet architecture using PyTorch. We evaluated the results against a test set of 300 exams that had been reviewed independently by two senior orthopedic surgeons who settled eventual interobserver disagreements through consensus sessions.ResultsThe CNN yielded an overall AUC of more than 0.87 for all KL grades except KL grade 2, which yielded an AUC of 0.8 and a mean AUC of 0.92. When merging adjacent KL grades, all but one group showed near perfect results with AUC > 0.95 indicating excellent performance.ConclusionWe have found that we could teach a CNN to correctly diagnose and classify the severity of knee OA using the KL grading system without cleaning the input data from major visual disturbances such as implants and other pathologies.
Highlights
Prevalence for knee osteoarthritis is rising in both Sweden and globally due to increased age and obesity in the population
Implants were used as a major visual disturbance to put more stress on the deep learning (DL) network. 11% of cases in the training set and 20% of cases in the test set had some type of a visible implant (Table 2)
When merging Kellgren & Lawrence (KL) grades together generating larger groups, the network performed with area under the curve (AUC) of > 0.95 for all but the mid-ranged KL grade (KL 1, 2 and 3), which displayed an AUC of 0.82; suggesting that the classes in the middle cause most issues
Summary
Prevalence for knee osteoarthritis is rising in both Sweden and globally due to increased age and obesity in the population. This has subsequently led to an increasing demand for knee arthroplasties. Correct diagnosis and classification of a knee osteoarthritis (OA) are of a great interest in following-up and planning for either conservative or operative management. Most orthopedic surgeons rely on standard weight bearing radiographs of the knee. With an aging population and increasing obesity worldwide, the prevalence of knee osteoarthritis (OA) is higher compared to other types of OA [1]. Using MRI has been showing some promises, [8] but most orthopedic surgeons still rely on standard weight bearing radiographs. Improving the reliability and reproducibility of these interpretations could be hugely beneficial
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