X-ray image segmentation for vertebral mobility analysis

Benjelloun, M.; Mahmoudi, Saïd

doi:10.1007/s11548-008-0149-1

Cited by 18 publications

(8 citation statements)

References 25 publications

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“…The primary evaluation of vertebral deformity in individuals with osteoporosis is typically performed via radiographic studies, including morphometric assessment of vertebral bodies [2][3]. A few recent studies have proposed computed-aided methods for the detection and analysis of vertebral bodies in radiographic images [4][5][6]. The objective of this work is to develop digital image processing and pattern recognition techniques for the segmentation of vertebrae in lateral X-ray images of the lumbar spine using Gabor filters [7] and decision tree [8].…”

Section: Resultsmentioning

confidence: 99%

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Special Session on Abdominal, Brain, Lumbar Spine CAD

2010

Int J CARS

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Keywords Computer-aided diagnosis Á Abdominal imaging Á CT colonography Á Electronic cleansing Purpose Fecal tagging in CT colonography (CTC) is a means of 'marking' fecal materials (stool and fluid) in the colon by use of a radiopaque oral contrast agent, such as barium or iodine. Electronic cleansing (EC) of the colon, is a promising technique for removing the tagged fecal materials in CTC images to 'virtually' cleanse the colon [1], [2]. A current problem with EC is that the majority of the existing EC methods are designed to remove only tagged fluid resulting from cathartic bowel preparation. Thus, the current EC schemes remain severely limited in removing solid or semi-solid stool that is the typical fecal residue in non-cathartic CTC, and they tend to generate severe cleansing artifacts that impair the diagnostic usefulness of the electronically cleansed non-cathartic CTC images. The artifacts of pseudo-soft-tissue structure and false fistula caused by partial volume effect and the incomplete cleansing caused by inhomogeneous tagging are two major artifacts in EC for non-cathartic CTC images. For the CTC examination imaged by a dual energy CT scanner (DE-CTC), the capability of material differentiation provides us a promising solution to identify the partial volume effect and inhomogeneous tagging in residual fecal materials.In this study, we developed a novel EC method for non-cathartic DE-CTC, denoted dual-energy EC (DE-EC), to effectively remove the residual fecal materials in non-cathartic CTC images while largely reducing the major cleansing artifacts, and validated its performance in a phantom study. MethodsThe EC artifacts -pseudo soft-tissue structures and false fistula, is caused by the partial volume effect (PVE) at the boundary between the air lumen and tagged regions, called the air-tagging boundary (ATboundary), and at a thin soft-tissue structure that is sandwiched between the air lumen and the tagged region, called the air-tissue-tagging layer (ATT-layer). EC requires the subtraction of the tagged regions and their associated AT-boundaries. Both the AT-boundary and the ATT-layer are formed by the PVE, i.e., a mixture of multiple materials at one voxel.Let each material k be modeled by a material-specific normal distribution P(A k ) parameterized by A k = {l k , P k }, where l k is the mean vector and P k is the variance matrix. Suppose that the attenuation value of a voxel can be decomposed into a linear combination of two different materials, i.e. l = a 1 9l 1 + a 2 9l 2 , where l 1 , l 2 are the mean attenuations of two materials inside the voxel, and a 1 , a 2 are the fractions of these two materials. In DE-CTC images, there are four types of materials of interest: air, fat, soft tissue, and tagged feces. Thus, there are six types of mixture combination: (air, fat/soft-tissue), (air, tagging), (fat/soft-tissue, tagging). Because the materials within each voxel are unknown, we need to calculate an estimate for the most significant materials within each voxel.Given a location x, the material...

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Section: Resultsmentioning

confidence: 99%

“…1f. The distances between the points were calculated automatically, and identified as D(1,2), D(2,3), D(3,4), and (4,5), as shown in Fig. 1f.…”

Section: Methodsmentioning

confidence: 99%

Special Session on Abdominal, Brain, Lumbar Spine CAD

2010

Int J CARS

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“…They used a novel combination of GHT and Kmeans clustering for the localization of vertebra using template matching theory. Benjelloun et al [15] presented an analysis of vertebra based on segmentation from x-ray images. They described a relative study of two algorithms to segment out vertebra.…”

Section: Figure 1: Spinal Column: Anatomical Featuresmentioning

confidence: 99%

A Comparison of Mean Models and Clustering Techniques for Vertebra Detection and Region Separation from C-Spine X-Rays

Mehmood¹,

Akram²,

Tariq³

et al. 2017

Adv. sci. technol. eng. syst. j.

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“…Benjelloun et al [6] proposed a framework of two segmentation approaches applied to X-ray images. They developed a semiautomatic tool to estimate and analyze vertebral mobility.…”

Section: Introductionmentioning

confidence: 99%

Semi-automatic detection of cervical vertebrae in X-ray images using generalized hough transform

Larhmam

Mahmoudi

Benjelloun

2012

2012 3rd International Conference on Image Processing Theory, Tools and Applications (IPTA)

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Vertebra detection presents the first step of any automatic spinal column diagnosis. This task becomes more difficult in the case of the cervical X-ray images characterized by their low contrasts and noise due to skull bones. In this paper, we describe an efficient modified template matching method for detecting cervical vertebrae using Generalized Hough Transform (GHT). The proposed method consists of three main steps toward vertebrae detection: 1) Offline training to obtain a robust average model of cervical vertebra. 2) Detecting the potential vertebra centers. 3) Adaptive Post-processing filter.X-ray Image data of 40 healthy cases were used to validate our approach by using a total of 200 cervical vertebrae. We obtained an accuracy of 89%.

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X-ray image segmentation for vertebral mobility analysis

Cited by 18 publications

References 25 publications

Special Session on Abdominal, Brain, Lumbar Spine CAD

Special Session on Abdominal, Brain, Lumbar Spine CAD

A Comparison of Mean Models and Clustering Techniques for Vertebra Detection and Region Separation from C-Spine X-Rays

Semi-automatic detection of cervical vertebrae in X-ray images using generalized hough transform

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