Four‐dimensional analysis of cyclic changes in coronary artery shape

Liao, Robert; Chen, S.‐Y. James; Messenger, John C.; Groves, Bertron Μ.; Burchenal, J.E.B.; Carroll, John D.

doi:10.1002/ccd.10106

Cited by 21 publications

(14 citation statements)

References 37 publications

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“…For the coronary artery, curvature range of the LAD in this study was within those reported in previous studies 13,23,28 although individual anatomic variation along the length would have a greater effect on the numerical values. We also observed a greater curvature change in the distal LAD than the proximal portion which is consistent with the literature.…”

Section: Discussionsupporting

confidence: 76%

“…According to this formula, curvature and torsion are defined as j ¼ a 0 Â a 00 k k= a 0 k k 3 and s ¼ ða 0 Â a 00 Þ Á a 000 = a 0 Â a 00 k k 2 , respectively, where a indicates a position vector in space. 9,28,29,33,35,53 By definition, this curvature metric measures an infinitesimal rate of change in the tangent vector at each point of the curve, whereas the torsion metric measures the infinitesimal rate of change in the orientation (binormal vector of the curve) of the osculating plane. While curvature is well appreciated because of its reciprocal relation to the radius of curvature, the torsion metric is less frequently used in practice because of its susceptibility to error in calculations associated with higher-order derivatives.…”

Section: Introductionmentioning

confidence: 99%

“…6,34,42,44,50,53 Various methods and quantification metrics have been proposed to characterize the aforementioned types of in vivo arterial deformations. 5,7,9,10,14,20,28,29,33,[41][42][43][44]49,50,53 For example, the ''distance factor,'' which is defined as the ratio between the vessel path length and the distance between two endpoints, is a simple metric commonly used to measure nonlinearity of vessels, i.e., tortuosity. 7,53 This metric lumps 3D information into a one-dimensional (1D) metric and hence does not clearly differentiate local curvature changes, especially when the vessel maintains the same distance factor.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Methods for Quantifying Three-Dimensional Deformation of Arteries due to Pulsatile and Nonpulsatile Forces: Implications for the Design of Stents and Stent Grafts

Choi

Cheng

Wilson³

et al. 2008

Ann Biomed Eng

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The knowledge of dynamic changes in the vascular system has become increasingly important in ensuring the safety and efficacy of endovascular devices. We developed new methods for quantifying in vivo three-dimensional (3D) arterial deformation due to pulsatile and nonpulsatile forces. A two-dimensional threshold segmentation technique combined with a level set method enabled calculation of the consistent centroid of the cross-sectional vessel lumen, whereas an optimal Fourier smoothing technique was developed to eliminate spurious irregularities of the centerline connecting the centroids. Longitudinal strain and novel metrics for axial twist and curvature change were utilized to characterize 3D deformations of the abdominal aorta, common iliac artery, and superficial femoral artery (SFA) due to musculoskeletal motion and deformations of the coronary artery due to cardiac pulsatile motion. These illustrative applications show the significance of each deformation metric, revealing significant longitudinal strain and axial twist in the SFA and coronary artery, and pronounced changes in vessel curvature in the coronary artery and in the inferior region of the SFA. The proposed methods may aid in designing preclinical tests aimed at replicating dynamic in vivo conditions in the arterial tree for the purpose of developing more durable endovascular devices including stents and stent grafts.

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Section: Discussionsupporting

confidence: 76%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Methods for Quantifying Three-Dimensional Deformation of Arteries due to Pulsatile and Nonpulsatile Forces: Implications for the Design of Stents and Stent Grafts

Choi

Cheng

Wilson³

et al. 2008

Ann Biomed Eng

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“…8 The cyclic change in coronary artery shape not only alters coronary artery curvature but also produces discrete flexion points. 9 Another unique feature of coronary arteries is that phasic pressure and blood flow are not synchronous as the maximum pressure is in systole and most coronary blood flow occurs during diastole (although there are rare exceptions). [10][11][12] This unique relationship is responsible for a highly negative stress phase angle between coronary artery circumferential strain and wall shear.…”

Section: Mechanical Deformation Of Coronary Arteriesmentioning

confidence: 99%

Role of Epicardial Fat to Buffer Deformation and Vibration in Coronary Arteries

Rabkin¹

2017

CMRVH

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OBjECTiVES: To examine the putative physiologic role of epicardial fat to buffer the coronary arteries and to review the data on deformation and vibration in coronary arteries. METhODS: OvidSP Medline, Embase, and PubMed were systematically searched. Eligible articles on vibration in arteries and deformation of coronary arteries were assessed. RESulTS: Coronary arteries are unique because they undergo substantial deformations with twisting, bending, and stretching that are due to cardiac contraction and the tethering of the large coronary arteries to the epicardial surface of the heart. In addition, phasic coronary artery pressure and blood flow are not synchronous producing a high negative stress phase angle between circumferential strain and wall shear. Fluid flow-induced vibrations, a universal finding in conduits transporting fluid with pulsatile flow, have been documented in arteries. Arterial vibration can damage the structure of arterial wall, especially elastin and endothelial cells, leading to alterations in the arterial function. Support for a beneficial mechanical role for epicardial fat is based on the data that wrapping material to the outside of conduits not only reduces the vibration but also decreases their movement. The overall impact of an external wrap is a reduction in the probability of conduit fatigue and failure. Characteristics of the artery, such as shear modulus, are a function of the properties of each layer of the artery. The application of epicardial fat to the adventitia of arteries alters the biophysical characteristics of the artery which is the sum of each layer including the epicardial fat. Vibration, resonance, and deformation energy are lost when they hit the surface of an absorbing material. COnCluSiOnS: The integration of the biophysics of coronary arteries with knowledge of material damping principles supports a physiologic role for epicardial fat to buffer deformation and vibration in coronary arteries.

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“…In three-dimensional analysis tortuosity of the artery is best described by the well-known Frenet formulas which define the tortuosity of the spatial curve (arterial centerline) through its curvature and torsion [11,[23][24][25]. The Frenet frame is formed by three vectors: tangent, normal, and binormal that form the orthonormal basis.…”

Section: -2 / Vol 134 June 2012mentioning

confidence: 99%

Three-Dimensional Geometry of the Human Carotid Artery

Kamenskiy

MacTaggart

Pipinos

et al. 2012

Journal of Biomechanical Engineering

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Accurate characterization of carotid artery geometry is vital to our understanding of the pathogenesis of atherosclerosis. Three-dimensional computer reconstructions based on medical imaging are now ubiquitous; however, mean carotid artery geometry has not yet been comprehensively characterized. The goal of this work was to build and study such geometry based on data from 16 male patients with severe carotid artery disease. Results of computerized tomography angiography were used to analyze the cross-sectional images implementing a semiautomated segmentation algorithm. Extracted data were used to reconstruct the mean three-dimensional geometry and to determine average values and variability of bifurcation and planarity angles, diameters and cross-sectional areas. Contrary to simplified carotid geometry typically depicted and used, our mean artery was tortuous exhibiting nonplanarity and complex curvature and torsion variations. The bifurcation angle was 36 deg ± 11 deg if measured using arterial centerlines and 15 deg ± 14 deg if measured between the walls of the carotid bifurcation branches. The average planarity angle was 11 deg ± 10 deg. Both bifurcation and planarity angles were substantially smaller than values reported in most studies. Cross sections were elliptical, with an average ratio of semimajor to semiminor axes of 1.2. The cross-sectional area increased twofold in the bulb compared to the proximal common, but then decreased 1.5-fold for the combined area of distal internal and external carotid artery. Inter-patient variability was substantial, especially in the bulb region; however, some common geometrical features were observed in most patients. Obtained quantitative data on the mean carotid artery geometry and its variability among patients with severe carotid artery disease can be used by biomedical engineers and biomechanics vascular modelers in their studies of carotid pathophysiology, and by endovascular device and materials manufacturers interested in the mean geometrical features of the artery to target the broad patient population.

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Four‐dimensional analysis of cyclic changes in coronary artery shape

Cited by 21 publications

References 37 publications

Methods for Quantifying Three-Dimensional Deformation of Arteries due to Pulsatile and Nonpulsatile Forces: Implications for the Design of Stents and Stent Grafts

Methods for Quantifying Three-Dimensional Deformation of Arteries due to Pulsatile and Nonpulsatile Forces: Implications for the Design of Stents and Stent Grafts

Role of Epicardial Fat to Buffer Deformation and Vibration in Coronary Arteries

Three-Dimensional Geometry of the Human Carotid Artery

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