Contour segmentation of the intima, media, and adventitia layers in intracoronary OCT images: application to fully automatic detection of healthy wall regions

Zahnd, Guillaume; Hoogendoorn, Ayla; Combaret, Nicolas; Καρανάσος, Αντώνιος; Péry, Émilie; Sarry, Laurent; Motreff, Pascal; Niessen, Wiro J.; Regar, Evelyn; Soest, Gijs van; Gijsen, Frank; Walsum, Theo van

doi:10.1007/s11548-017-1657-7

Cited by 23 publications

(21 citation statements)

References 27 publications

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“…In previous studies, IVOCT classification studies using machine learning focused on classification of vessel layer or vulnerable plaque . In this study, we focused on classification of abnormal lumen that includes intra‐luminal atherothrombotic material (protrusion) by handcrafted features.…”

Section: Discussionmentioning

confidence: 99%

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A novel automated lumen segmentation and classification algorithm for detection of irregular protrusion after stents deployment

Yoon

Yazdi

et al. 2019

Robotics Computer Surgery

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Background: Clinically, irregular protrusions and blockages after stent deployment can lead to significant adverse outcomes such as thrombotic reocclusion or restenosis. In this study, we propose a novel fully automated method for irregular lumen segmentation and normal/abnormal lumen classification. Methods:The proposed method consists of a lumen segmentation, feature extraction, and lumen classification. In total, 92 features were extracted to classify normal/abnormal lumen. The lumen classification method is a combination of supervised learning algorithm and feature selection that is a partition-membership filter method.Results: As the results, our proposed lumen segmentation method obtained the average of dice similarity coefficient (DSC) and the accuracy of proposed features and the random forest (RF) for normal/abnormal lumen classification as 97.6% and 98.2%, respectively.Conclusions: Therefore, we can lead to better understanding of the overall vascular status and help to determine cardiovascular diagnosis. K E Y W O R D S cardiac, cardiology, heart, image analysis, vascular surgery, vessel

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Section: Discussionmentioning

confidence: 99%

“…Finally, Zahnd et al developed classification method to identify healthy and diseased region of arterial wall. A set of 17 tentative features were extracted from each column of segmented region for the classification.…”

Section: Related Workmentioning

confidence: 99%

A novel automated lumen segmentation and classification algorithm for detection of irregular protrusion after stents deployment

Yoon

Yazdi

et al. 2019

Robotics Computer Surgery

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“…These methods include the use of the local maximum OCT signal intensity, local maximum gradient of the OCT signal, and the Canny edge detector. 70,[110][111][112] The underlying tissue may present different morphologies and need further segmentation, especially when the tissue presents layered structures with varying OCT signal strength. For example, normal skin comprises epidermis (low signal) and dermis (high signal), and normal coronary arterial wall comprises intima (high signal), media (low signal), and adventitia (high signal), which are further segmented to confine the depth ranges for attenuation measurement.…”

Section: Tissue Heterogeneitymentioning

confidence: 99%

“…For example, normal skin comprises epidermis (low signal) and dermis (high signal), and normal coronary arterial wall comprises intima (high signal), media (low signal), and adventitia (high signal), which are further segmented to confine the depth ranges for attenuation measurement. 112,113 Overall, the capacity to locate homogeneous tissue regions for attenuation calculation is dependent on the specific tissue morphology and the corresponding contrast in OCT signal and may need additional revision of the methods under specific disease conditions. Such revisions will be disease-and tissue-dependent and may not be feasible for all conditions.…”

Section: Tissue Heterogeneitymentioning

confidence: 99%

Parametric imaging of attenuation by optical coherence tomography: review of models, methods, and clinical translation

et al. 2020

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Significance: Optical coherence tomography (OCT) provides cross-sectional and volumetric images of backscattering from biological tissue that reveal the tissue morphology. The strength of the scattering, characterized by an attenuation coefficient, represents an alternative and complementary tissue optical property, which can be characterized by parametric imaging of the OCT attenuation coefficient. Over the last 15 years, a multitude of studies have been reported seeking to advance methods to determine the OCT attenuation coefficient and developing them toward clinical applications. Aim: Our review provides an overview of the main models and methods, their assumptions and applicability, together with a survey of preclinical and clinical demonstrations and their translation potential. Results: The use of the attenuation coefficient, particularly when presented in the form of parametric en face images, is shown to be applicable in various medical fields. Most studies show the promise of the OCT attenuation coefficient in differentiating between tissues of clinical interest but vary widely in approach. Conclusions: As a future step, a consensus on the model and method used for the determination of the attenuation coefficient is an important precursor to large-scale studies. With our review, we hope to provide a basis for discussion toward establishing this consensus.

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“…Studies on the segmentation of endoscopic OCT images are not as extensive as the macular ones. Representative researches can be found in the processing of cardiovascular [ 28 – 30 ] and esophageal OCT images [ 31 – 36 ]. As reported, the graph based method is also effective in segmenting cardiovascular [ 30 ] and esophageal tissue layers [ 36 ].…”

Section: Introductionmentioning

confidence: 99%

Robust layer segmentation of esophageal OCT images based on graph search using edge-enhanced weights

Gan¹,

Yang²,

Yang³

et al. 2018

Biomed. Opt. Express

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Automatic segmentation of esophageal layers in OCT images is crucial for studying esophageal diseases and computer-assisted diagnosis. This work aims to improve the current techniques to increase the accuracy and robustness for esophageal OCT image segmentation. A two-step edge-enhanced graph search (EEGS) framework is proposed in this study. Firstly, a preprocessing scheme is applied to suppress speckle noise and remove the disturbance in the esophageal structure. Secondly, the image is formulated into a graph and layer boundaries are located by graph search. In this process, we propose an edge-enhanced weight matrix for the graph by combining the vertical gradients with a Canny edge map. Experiments on esophageal OCT images from guinea pigs demonstrate that the EEGS framework is more robust and more accurate than the current segmentation method. It can be potentially useful for the early detection of esophageal diseases.

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Contour segmentation of the intima, media, and adventitia layers in intracoronary OCT images: application to fully automatic detection of healthy wall regions

Cited by 23 publications

References 27 publications

A novel automated lumen segmentation and classification algorithm for detection of irregular protrusion after stents deployment

A novel automated lumen segmentation and classification algorithm for detection of irregular protrusion after stents deployment

Parametric imaging of attenuation by optical coherence tomography: review of models, methods, and clinical translation

Robust layer segmentation of esophageal OCT images based on graph search using edge-enhanced weights

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