Abstract
Veterinarians use X-rays for almost all examinations of clinical fractures to determine the appropriate treatment. Before treatment, vets need to know the date of the injury, type of the broken bone, and age of the dog. The maturity of the dog and the time of the fracture affects the approach to the fracture site, the surgical procedure and needed materials. This comprehensive study has three main goals: determining the maturity of the dogs (Task 1), dating fractures (Task 2), and finally, detecting fractures of the long bones in dogs (Task 3). The most popular deep neural networks are used: AlexNet, ResNet-50 and GoogLeNet. One of the most popular machine learning algorithms, support vector machines (SVM), is used for comparison. The performance of all sub-studies is evaluated using accuracy and F1 score. Each task has been successful with different network architecture. ResNet-50, AlexNet and GoogLeNet are the most successful algorithms for the three tasks, with F1 scores of 0.75, 0.80 and 0.88, respectively. Data augmentation is performed to make models more robust, and the F1 scores of the three tasks were 0.80, 0.81, and 0.89 using ResNet-50, which is the most successful model. This preliminary work can be developed into support tools for practicing veterinarians that will make a difference in the treatment of dogs with fractured bones. Considering the lack of work in this interdisciplinary field, this paper may lead to future studies.
Highlights
In recent years, many fields of study, biomedicine, have been positively affected by the phenomenon of deep learning [1]
The importance of veterinary medicine can be emphasized with this common expression: “If human medicine is for people, veterinary medicine is for humanity.”
Veterinary medicine specializes in different fields, such as orthopedics, cardiology, urology, and virology
Summary
Many fields of study, biomedicine, have been positively affected by the phenomenon of deep learning [1]. Recent studies have examined disease and fracture detection, organ and tissue segmentation, and many more applications using magnetic resonance (MR) and tomography images with high success rates thanks to deep learning algorithms [2,3]. These successful applications are valid for human medicine. Veterinary medicine specializes in different fields, such as orthopedics, cardiology, urology, and virology. These fields required specialized education [5]. This study is aimed to help general practice veterinarians who do not have additional training in orthopedics or surgery
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