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

Choi, Gilwoo; Cheng, Christopher P.; Wilson, Nathan M.; Taylor, Charles A.

doi:10.1007/s10439-008-9590-0

Cited by 88 publications

(80 citation statements)

References 47 publications

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“…Another limitation concerns the limited number of patients included; however, the typical number of subjects in similar work is between 1 and a maximum of 10. [12][13][14]17,18 In addition, the patients considered in this study covered a large range of arterial calcifications, which is sufficient to provide an assessment of the effect of the PAD on the arterial deformations.…”

Section: Discussionmentioning

confidence: 99%

Quantification of Popliteal Artery Deformation During Leg Flexion in Subjects With Peripheral Artery Disease: A Pilot Study

Gökgöl

Diehm

Kara

et al. 2013

Journal of Endovascular Therapy

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Purpose: To quantify the in-vivo deformations of the popliteal arterial segment (PAS) during leg flexion in subjects with clinically relevant (Fontaine Stage IIb) peripheral arterial disease (PAD).Methods: Five patients with varying calcification levels of the PAS undergoing endovascular revascularization underwent 3D rotational angiography. Image acquisition was performed with the leg straight and with a flexion of 70°/20° in the knee/hip joint. The arterial centerline and the corresponding branches in both positions were segmented to create 3D reconstructions of the arterial trees. Axial deformation, twisting, and curvatures were quantified. Furthermore, the relationships between the calcification levels and the deformations were investigated. Results:We observed an average shortening of the PAS of 5.9% ± 2.5% and twist rate of 3.8 Conclusions:The PAS of patients with symptomatic PAD is exposed to significant deformations during flexion of the knee joint. The curvature is directly affected by the extent of arterial calcification. In contrast, the changes in arterial length and twisting angles are comparable to those of healthy arteries. These measurements have the potential to be used for realistic arterial modeling to improve stent designs.This study also showed the ability of rotational angiography to quantify the three-dimensional deformations of the PAS in patients with various levels of calcification, and that this technique can be used to collect data on larger groups of patients.

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Section: Discussionmentioning

confidence: 99%

Quantification of Popliteal Artery Deformation During Leg Flexion in Subjects With Peripheral Artery Disease: A Pilot Study

Gökgöl

Diehm

Kara

et al. 2013

Journal of Endovascular Therapy

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“…In this context, previous works, using robust and objective techniques, were developed to successfully characterize the 3D geometry of arteries. 5,29 However, these methods are not compatible with non-contrast CT image quality where simplified calculations should be proposed. Using non-contrast CT images, traditional methods restrict the aortic size measurement to the ascending and descending diameters.…”

Section: Aortic Segmentation Algorithm: Potential Applicationsmentioning

confidence: 99%

Aging Impact on Thoracic Aorta 3D Morphometry in Intermediate-Risk Subjects: Looking Beyond Coronary Arteries with Non-Contrast Cardiac CT

et al. 2011

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An increasing number of intermediate risk asymptomatic subjects benefit from measures of atherosclerosis burden like coronary artery calcification studies with non-contrast heart computed tomography (CT). However, additional information can be derived from these studies, looking beyond the coronary arteries and without exposing the patients to further radiation. We report a semi-automatic method that objectively assesses ascending, arch and descending aorta dimension and shape from non-contrast CT datasets to investigate the effect of aging on thoracic aorta geometry. First, the segmentation process identifies the vessel centerline coordinates following a toroidal path for the curvilinear portion and axial planes for descending aorta. Then, reconstructing oblique planes orthogonal to the centerline direction, it iteratively fits circles inside the vessel cross-section. Finally, regional thoracic aorta dimensions (diameter, volume and length) and shape (vessel curvature and tortuosity) are calculated. A population of 200 normotensive men was recruited. Length, mean diameter and volume differed by 1.2 cm, 0.13 cm and 21 cm(3) per decade of life, respectively. Aortic shape uncoiled with aging, reducing its tortuosity and increasing its radius of curvature. The arch was the most affected segment. In conclusion, non-contrast cardiac CT imaging can be successfully employed to assess thoracic aorta 3D morphometry.

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“…Although average curvatures for the infrarenal abdominal aorta and iliac branches have been reported in an earlier methods article for three patients 46 and in recent work by Choi et al 12,13 related to physiological vessel movement, to our knowledge no comprehensive analysis of proximal renal artery or anterior visceral branch curvature exists. The curvature and torsion profiles presented for the various vessels in this study give a novel insight into the regional variation of the parameters over the actual artery length in different subjects.…”

Section: Discussionmentioning

confidence: 94%

Geometric Variability of the Abdominal Aorta and Its Major Peripheral Branches

2010

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Vessel geometry determines blood flow dynamics and plays a crucial role in the pathogenesis of vascular disease. In vivo assessment of three-dimensional (3D) vessel anatomy is vital to improve the realism of arterial flow model geometries and investigate factors associated with the localisation of atherosclerosis. The quantification of vascular geometry is also particularly important for the proper design and preclinical testing of endovascular devices used to treat peripheral arterial disease. The purpose of this study was to quantitatively evaluate the intersubject variability of 3D branching and curvature of the abdominal aorta and its major peripheral arteries. Contrast-enhanced renal MRA scans of healthy abdominal vessels obtained in 12 subjects (8 men, 4 women mean age 49 years, range 27-84 years) were segmented, and smoothed centerlines were determined as descriptors of arterial geometry. Robust techniques were employed to characterise non-planar vessel curvature, arterial taper, and 3D branching parameters. Noticeable 3D curvature and tapering were quantified for the proximal anterior visceral and renal branches. Mean 3D branching angles of 63.5+/-10.1 degrees and 73.1+/-6.8 degrees were established for the right and left renal arteries, respectively. Angles describing the ostial position and initial trajectory of the renal arteries confirmed the antero-lateral origin and direction of the right and the more lateral orientation of the left. The anterior visceral branches emerged predominantly from the left side of the anterior aortic wall. Branching parameters determined at the aortic bifurcation demonstrated mild asymmetry and non-planarity at this location. In summary, the results from this study address the scarcity of available in vivo 3D quantitative geometric data relating to the abdominal vasculature and reflect the geometric variability in living subjects.

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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

Cited by 88 publications

References 47 publications

Quantification of Popliteal Artery Deformation During Leg Flexion in Subjects With Peripheral Artery Disease: A Pilot Study

Quantification of Popliteal Artery Deformation During Leg Flexion in Subjects With Peripheral Artery Disease: A Pilot Study

Aging Impact on Thoracic Aorta 3D Morphometry in Intermediate-Risk Subjects: Looking Beyond Coronary Arteries with Non-Contrast Cardiac CT

Geometric Variability of the Abdominal Aorta and Its Major Peripheral Branches

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