Title:Deep Learning-based Automated Knee Joint Localization in Radiographic
Images Using Faster R-CNN
Volume: 20
Author(s): T. Sivakumari and R. Vani*
Affiliation:
- Department of Electronics and Communication Engineering, SRM Institute of Science and Technology, Faculty of Engineering and Technology,
Ramapuram, Chennai, Tamil Nadu, India
Keywords:
Deep learning, Faster R-CNN, Knee osteoarthritis, Object detection, X-ray images, RDN.
Abstract:
Background:
Osteoarthritis is a condition that poses a risk to the knee joint, resulting in pain and impaired function. However, traditional knee X-ray evaluations
using the Kellgren-Lawrence grading system have proven to be inefficient. These evaluations are subjective, time-consuming, and labor-intensive,
particularly in busy hospital settings.
Objective:
The objective of this research was to present a deep learning-based approach that can detect knee joint regions in medical images. By addressing
the limitations of traditional methods, the aim was to develop a more efficient and automated approach for knee joint analysis.
Methods:
The proposed method utilizes the Faster R-CNN model, which consists of a region proposal network (RPN) and Fast R-CNN. The RPN generates
region proposals that potentially contain knee joint regions, while the Fast R-CNN network categorizes and extracts features from these proposals.
To train the model, a dataset of knee joint images was employed. The performance of the model was evaluated using metrics, such as accuracy,
precision, recall, F1-score, and mean IoU (Intersection Over Union).
Results:
The results demonstrated the high accuracy of the proposed method in detecting knee joint regions. The model achieved a mean IoU of 94.5,
indicating a strong overlap between the predicted and ground truth regions. These findings highlight the potential of deep learning-based
approaches in automating medical image analysis, specifically in the diagnosis and management of knee joint disorders.
Conclusion:
This study emphasizes the significance of leveraging advanced technologies, such as deep learning, in medical imaging. By developing more
efficient and accurate methods for identifying knee joint regions in medical images, it becomes feasible to enhance patient outcomes and healthcare
delivery. The proposed deep learning-based approach showcases promising results, paving the way for further advancements in the field of medical
image analysis and contributing to improved diagnostic capabilities for knee joint disorders.