Automatic Model-Based Segmentation of the Heart in CT Images

Ecabert, Olivier; Peters, Jörg; Schramm, Hauke; Lorenz, Cristian; Berg, Jens von; Walker, Matthew J.; Vembar, Mani; Olszewski, Mark E.; Subramanyan, Krishna; Lavi, G.; Weese, Jürgen

doi:10.1109/tmi.2008.918330

Cited by 335 publications

(271 citation statements)

References 33 publications

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“…Then, during the segmentation, competitive contours with equal weights ( = 0.5) were used. The fixed threshold ( ℎ) was computed as the average value between the mean intensity on the selected region (window of size equal to 3 × 3 × 3 mm 3 ) and the expected intensity of the atrial/aortic walls (50 HU, (Ecabert et al, 2008)). The stop criteria of the BEAS-threshold method relies on the difference between mesh positions in two consecutive iterations and it finishes when small differences are found.…”

Section: Implementation Detailsmentioning

confidence: 99%

A competitive strategy for atrial and aortic tract segmentation based on deformable models

Morais

Vilaça

Queirós

et al. 2017

Medical Image Analysis

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A competitive strategy for atrial and aortic tract segmentation based on deformable models AbstractMultiple strategies have previously been described for atrial region (i.e. atrial bodies and aortic tract) segmentation. Although these techniques have proven their accuracy, inadequate results in the mid atrial walls are common, restricting their application for specific cardiac interventions. In this work, we introduce a novel competitive strategy to perform atrial region segmentation with correct delineation of the thin mid walls, and integrated it into the B-spline Explicit Active Surfaces framework. A double-stage segmentation process is used, which starts with a fast contour growing followed by a refinement stage with local descriptors. Independent functions are used to define each region, being afterward combined to compete for the optimal boundary. The competition locally constrains the surface evolution, prevents overlaps and allows refinement to the walls. Three different scenarios were used to demonstrate the advantages of the proposed approach, through the evaluation of its segmentation accuracy, and its performance for heterogeneous mid walls. Both computed tomography and magnetic resonance imaging datasets were used, presenting results similar to the state-of-the-art methods for both atria and aorta. The competitive strategy showed its superior performance with statistically significant differences against the traditional freeevolution approach in cases with bad image quality or missed atrial/aortic walls. Moreover, only the competitive approach was able to accurately segment the atrial/aortic wall. Overall, the proposed strategy showed to be suitable for atrial region segmentation with a correct segmentation of the mid thin walls, demonstrating its added value with respect to the traditional techniques.

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Section: Implementation Detailsmentioning

confidence: 99%

A competitive strategy for atrial and aortic tract segmentation based on deformable models

Morais

Vilaça

Queirós

et al. 2017

Medical Image Analysis

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“…Based on the atlas, the cardiac shape or function of a popula- Rougon et al (2004) Tagged MR 11 healthy Statistical motion model Suinesiaputra et al (2009) 2D cine MR 44 healthy Statistical contour model Fonseca et al (2011) 2D cine MR 2864 healthy, 470 patients Statistical shape model Duchateau et al (2011) 2D US 21 healthy Statistical motion model Duchateau et al (2012) 2D Ecabert et al (2008) CT 13 patients Statistical shape model Zhuang et al (2010) Whole-heart MR 10 healthy - Hoogendoorn et al (2013) CT 138 patients Statistical shape model tion can be analysed and compared in a common space. The statistical shape model is the most commonly used tool for shape analysis.…”

Section: Related Workmentioning

confidence: 99%

A bi-ventricular cardiac atlas built from 1000+ high resolution MR images of healthy subjects and an analysis of shape and motion

Bai

Shi

Marvao

et al. 2015

Medical Image Analysis

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“…The main advantage of our tracking method is that it is a template/model-based tracking of the AVP in fluoroscopic sequences, to overcome the limitations of edge detection image-based methods [24]. Searching two feature points (i.e.…”

Section: Discussionmentioning

confidence: 99%

Aortic valve prosthesis tracking for transapical aortic valve implantation

et al. 2010

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Purpose Transapical aortic valve implantation (TA-AVI) is a new minimally invasive surgical treatment of aortic stenosis for high risk patients. The placement of aortic valve prosthesis (AVP) is performed under 2D Xray fluoroscopic guidance. Difficult clinical complications can arise if the implanted valve is misplaced. Therefore we present a method to track the AVP in 2D X-ray fluoroscopic images in order to improve the accuracy of the TA-AVI. MethodsThe proposed tracking method includes the template matching approach to estimate the position of AVP and a shape model of the prosthesis to extract the corner points of the AVP in each image of sequence. To start the AVP tracking procedure, an initialization step is performed by manually defining the corner points of the prosthesis in the first image of sequence to provide the required algorithm parameters such as the AVP model parameters.Results We evaluated the AVP tracking method on six 2D intra-operative fluoroscopic image sequences. The results of automatic AVP localization agree well with manually-defined AVP positions. The maximum localization errors of tracked prosthesis are less than 1 mm and within the clinical accepted range.Conclusions For assisting the TA-AVI, a method for tracking the AVP in 2D X-ray fluoroscopic image sequences has been developed. Our AVP tracking method is a first step towards automatic optimal placement of the AVP during the TA-AVI.

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Automatic Model-Based Segmentation of the Heart in CT Images

Cited by 335 publications

References 33 publications

A competitive strategy for atrial and aortic tract segmentation based on deformable models

A competitive strategy for atrial and aortic tract segmentation based on deformable models

A bi-ventricular cardiac atlas built from 1000+ high resolution MR images of healthy subjects and an analysis of shape and motion

Aortic valve prosthesis tracking for transapical aortic valve implantation

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