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Abstract
The paper proposes a segmentation and classification technique for fracture detection in X-ray images. This novel rotation-invariant method introduces the concept of local entropy for de-noising and removing tissue from the analysed X-ray images, followed by an improved procedure for image segmentation and the detection of regions of interest. The proposed local Shannon entropy was calculated for each image pixel using a sliding 2D window. An initial image segmentation was performed on the entropy representation of the original image. Next, a graph theory-based technique was implemented for the purpose of removing false bone contours and improving the edge detection of long bones. Finally, the paper introduces a classification and localisation procedure for fracture detection by tracking the difference between the extracted contour and the estimation of an ideal healthy one. The proposed hybrid method excels at detecting small fractures (which are hard to detect visually by a radiologist) in the ulna and radius bones—common injuries in children. Therefore, it is imperative that a radiologist inspecting the X-ray image receives a warning from the computerised X-ray analysis system, in order to prevent false-negative diagnoses. The proposed method was applied to a data-set containing 860 X-ray images of child radius and ulna bones (642 fracture-free images and 218 images containing fractures). The obtained results showed the efficiency and robustness of the proposed approach, in terms of segmentation quality and classification accuracy and precision (up to and , respectively).
Highlights
Various image processing techniques are frequently used for enhancing images produced by medical image acquisition systems, such as Digital Radiography (DR), Sonography, ComputedTomography (CT), or Magnetic Resonance Imaging (MRI)
This paper proposes a hybrid computer-aided X-ray image segmentation and bone fracture detection solution, which consists of the following phases: (1) Directional alignment; (2) entropy-based bone contour extraction and denoising; (3) applying graph theoretic techniques in bone contour correction and fracture detection; and (4) a classification and localisation procedure
The proposed method for the detection of smaller, demanding fractures of the radius and ulna bones from X-ray images, based on the local entropy, was applied to a data-set consisting of 960 coronal plane images of child radius and ulna bone fractures provided by the Medical University of Graz, Department of Radiology, Division of Paediatric Radiology
Summary
Various image processing techniques are frequently used for enhancing images produced by medical image acquisition systems, such as Digital Radiography (DR), Sonography, ComputedTomography (CT), or Magnetic Resonance Imaging (MRI). Various image processing techniques are frequently used for enhancing images produced by medical image acquisition systems, such as Digital Radiography (DR), Sonography, Computed. In the case of low-quality images, numerous image processing techniques utilise information entropy as a tool for image feature extraction [1]. Modern studies in medical imaging strive to develop efficient computer-aided decision support systems to assist medical experts by flagging suspicious cases requiring closer examination [5]. The goal of these automatic computerised diagnostic systems is to reduce diagnostic time and improve accuracy by replacing the tedious inspection of medical images (traditionally done visually by human experts)
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