4 research outputs found
Automatic detection and quantification of abdominal aortic calcification in dual energy X-ray absorptiometry
Cardiovascular disease (CVD) is a major cause of mortality and the main cause of morbidity worldwide. CVD may lead to heart attacks and strokes and most of these are caused by atherosclerosis; this is a medical condition in which the arteries become narrowed and hardened due to an excessive build-up of plaque on the inner artery wall. Arterial calcification and, in particular, abdominal aortic calcification (AAC) is a manifestation of atherosclerosis and a prognostic indicator of CVD. In this paper, a two-stage automatic method to detect and quantify the severity of AAC is described; it is based on the analysis of lateral vertebral fracture assessment (VFA) images. These images were obtained on a dual energy x-ray absorptiometry (DXA) scanner used in single energy mode. First, an active appearance model was used to segment the lumbar vertebrae L1-L4 and the aorta on VFA images; the segmentation of the aorta was based on its position with respect to the vertebrae. In the second stage, feature vectors representing calcified regions in the aorta were extracted to quantify the severity of AAC. The presence and severity of AAC was also determined using an established visual scoring system (AC24). The abdominal aorta was divided into four parts immediately anterior to each vertebra, and the severity of calcification in the anterior and posterior walls was graded separately for each part on a 0-3 scale. The results were summed to give a composite severity score ranging from 0 to 24. This severity score was classified as follows: mild AAC (score 0-4), moderate AAC (score 5-12) and severe AAC (score 12-24). Two classification algorithms (k-nearest neighbour and support vector machine) were trained and tested to assign the automatically extracted feature vectors into the three classes. There was good agreement between the automatic and visual AC24 methods and the accuracy of the automated technique relative to visual classification indicated that it is capable of identifying and quantifying AAC over a range of severit
A robust technique for the detection and quantification of abdominal aortic calcification using dual energy X-Ray absorptiometry
Arterial calcification is a manifestation of atherosclerosis, which over the last two
decades has become a recognised predictor of cardiovascular disease. Abdominal
Aortic Calcification (AAC) and osteoporosis have been shown to coincide in older
individuals. The accepted method of diagnosing osteoporosis is through the
measurement of bone mineral density by dual energy x-ray absorptiometry (DXA).
Vertebral fracture assessment (VFA) images obtained alongside BMD using DXA
technology provide an inexpensive resource for AAC diagnosis.
Although several simple methods have been proposed for manual semi-quantitative
scoring of AAC in x-ray images in the past, these methods have limitations in terms of
capturing small changes in atherosclerosis progression and are time-consuming.
Several automatic approaches have been proposed to measure AAC on radiographs.
However, these methods have not been related to any accepted medical AAC scoring
systems and thus are not likely to be adopted easily by the medical community. In
addition, there has been no attempt to apply the proposed methods to VFA images.
The main focus of the research presented in this thesis is the automatic quantification of
AAC in VFA images acquired in single energy mode. The thesis is divided into two main
parts. In the first part, an automatic method for AAC detection and quantification in VFA
images is proposed and evaluated on a large number of images. In the second part, the
performance of both single and dual energy VFA imaging for the detection of uniformly
distributed calcification is investigated.
The automatic method for AAC detection consists of two stages. In the first stage an
active appearance model was employed for the purpose of segmentaion. In the second
stage, adaptive thresholding techniques were used to detect AAC, whilst automatic
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classification techniques were used to quantify the detected calcification. The
performance of several classifiers were investigated, and the proposed method was
evaluated against the manual AC-24 scoring method using several hundred images and
two human readers. A thorough statistical analysis of the results showed that, overall,
the SVM classifier gave the best results. Weighted accuracy, sensitivity, specificity
assessed for 4 AAC categories were 89.2%, 78.5% and 92.3% respectively while the
corresponding values for 3 AAC categories were 88.6%, 86%, 90.4%.
In the second part, a study using a tissue-mimicking physical phantom is described. The
phantom consists of an aluminium strip within Perspex to simulate calcification and
abdominal soft tissue respectively.
VFA images of different phantom configurations were acquired in single energy (SE) and
dual energy (DE) modes. The minimum detectable aluminium thickness was assessed
visually and related to contrast and contrast-to-noise ratio. Percentage coefficient of
variation was used to quantify uniformity, repeatability and reproducibility with a Perspex
width of 25 cm, the smallest thickness of aluminium that could be detected was 0.20-
0.25 mm.
The initial results are promising, and the system proposed in this research can be used
as an alternative method to the manual scoring system (AC-24) for a wide range of AAC.
The principal conclusion from the phantom work is that under idealised imaging
conditions, VFA images have the potential to be used for detecting small thicknesses of
calcification with good linearity, repeatability and reproducibility in SE and DE modes for
patients with a body width < 30 cm