Abstract
In the medical sector, three-dimensional (3D) images are commonly used like computed tomography (CT) and magnetic resonance imaging (MRI). The 3D MRI is a non-invasive method of studying the soft-tissue structures in a knee joint for osteoarthritis studies. It can greatly improve the accuracy of segmenting structures such as cartilage, bone marrow lesion, and meniscus by identifying the bone structure first. U-net is a convolutional neural network that was originally designed to segment the biological images with limited training data. The input of the original U-net is a single 2D image and the output is a binary 2D image. In this study, we modified the U-net model to identify the knee bone structures using 3D MRI, which is a sequence of 2D slices. A fully automatic model has been proposed to detect and segment knee bones. The proposed model was trained, tested, and validated using 99 knee MRI cases where each case consists of 160 2D slices for a single knee scan. To evaluate the model’s performance, the similarity, dice coefficient (DICE), and area error metrics were calculated. Separate models were trained using different knee bone components including tibia, femur, patella, as well as a combined model for segmenting all the knee bones. Using the whole MRI sequence (160 slices), the method was able to detect the beginning and ending bone slices first, and then segment the bone structures for all the slices in between. On the testing set, the detection model accomplished 98.79% accuracy and the segmentation model achieved DICE 96.94% and similarity 93.98%. The proposed method outperforms several state-of-the-art methods, i.e., it outperforms U-net by 3.68%, SegNet by 14.45%, and FCN-8 by 2.34%, in terms of DICE score using the same dataset.
Highlights
Publisher’s Note: MDPI stays neutralKnee osteoarthritis (OA) is a progressive chronic condition described by any changes in the structure of the bone, cartilage, synovium, or other joint structures [1,2,3]
In terms of the detection task, we segmentation models while the binary cross-entropy has been used as a loss function for all used precision, recall, and the overall accuracy which can be detection models in order to backpropagate through the Convolutional neural networks (CNNs)
This study proposed a fully automatic method to detect and segment the bones in the sequence of 3D knee magnetic resonance imaging (MRI) using modified U-net models
Summary
Publisher’s Note: MDPI stays neutralKnee osteoarthritis (OA) is a progressive chronic condition described by any changes in the structure of the bone, cartilage, synovium, or other joint structures [1,2,3]. Among the different types of arthritis, OA affects the elderly and is considered to be the most recurrent type. This arthritis condition reduces the lifespan of elderly people as it poses restrictions in carrying out their tasks, which results in a disability and financial constraints for the societies and their healthcare systems. Of its gross domestic product (GDP), to take care of the people infected with arthritis [5]. The total lifetime care cost for anyone infected with knee OA was calculated to be USD 140,300 [6]. In 2010, it was estimated that 9.9 million U.S adults suffer from symptomatic knee OA [7]. By 2030, an estimation of 20% of the U.S population, around
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