Your search keyword '"Gijsen, Frank"' showing total 18 results

1. Contribution of Red Blood Cells and Platelets to Blood Clot Computed Tomography Imaging and Compressive Mechanical Characteristics.

Author

Cahalane, Rachel M. E., Cruts, Janneke M. H., van Beusekom, Heleen M. M., de Maat, Moniek P. M., Dijkshoorn, Marcel, van der Lugt, Aad, and Gijsen, Frank J. H.

Abstract

Thrombus computed tomography (CT) imaging characteristics may correspond with thrombus mechanical properties and thus predict thrombectomy success. The impact of red blood cell (RBC) content on these properties (imaging and mechanics) has been widely studied. However, the additional effect of platelets has not been considered. The objective of the current study was to examine the individual and combined effects of blood clot RBC and platelet content on resultant CT imaging and mechanical characteristics. Human blood clot analogues were prepared from a combination of preselected RBC volumes and platelet concentrations to decouple their contributions. The resulting clot RBC content (%) and platelet content (%) were determined using Martius Scarlet Blue and CD42b staining, respectively. Non-contrast and contrast-enhanced CT (NCCT and CECT) scans were performed to measure the clot densities. CECT density increase was taken as a proxy for clinical perviousness. Unconfined compressive mechanics were analysed by performing 10 cycles of 80% strain. RBC content is the major determinant of clot NCCT density. However, additional consideration of the platelet content improves the association. CECT density increase is influenced by clot platelet and not RBC content. Platelet content is the dominant component driving clot stiffness, especially at high strains. Both RBC and platelet content contribute to the clot's viscoelastic and plastic compressive properties. The current in vitro results suggest that CT density is reflective of RBC content and subsequent clot viscoelasticity and plasticity, and that perviousness reflects the clot's platelet content and subsequent stiffness. However, these indications should be confirmed in a clinical stroke cohort. [ABSTRACT FROM AUTHOR]

Published

2024

2. The interplay of collagen, macrophages, and microcalcification in atherosclerotic plaque cap rupture mechanics.

Author

Jansen, Imke, Cahalane, Rachel, Hengst, Ranmadusha, Akyildiz, Ali, Farrell, Eric, Gijsen, Frank, Aikawa, Elena, van der Heiden, Kim, and Wissing, Tamar

Subjects

ATHEROSCLEROTIC plaque, TISSUE mechanics, MACROPHAGES, COLLAGEN, ULTIMATE strength

Abstract

The rupture of an atherosclerotic plaque cap overlying a lipid pool and/or necrotic core can lead to thrombotic cardiovascular events. In essence, the rupture of the plaque cap is a mechanical event, which occurs when the local stress exceeds the local tissue strength. However, due to inter- and intra-cap heterogeneity, the resulting ultimate cap strength varies, causing proper assessment of the plaque at risk of rupture to be lacking. Important players involved in tissue strength include the load-bearing collagenous matrix, macrophages, as major promoters of extracellular matrix degradation, and microcalcifications, deposits that can exacerbate local stress, increasing tissue propensity for rupture. This review summarizes the role of these components individually in tissue mechanics, along with the interplay between them. We argue that to be able to improve risk assessment, a better understanding of the effect of these individual components, as well as their reciprocal relationships on cap mechanics, is required. Finally, we discuss potential future steps, including a holistic multidisciplinary approach, multifactorial 3D in vitro model systems, and advancements in imaging techniques. The obtained knowledge will ultimately serve as input to help diagnose, prevent, and treat atherosclerotic cap rupture. [ABSTRACT FROM AUTHOR]

Published

2024

3. Tensile and Compressive Mechanical Behaviour of Human Blood Clot Analogues.

Author

Cahalane, Rachel M. E., de Vries, Judith J., de Maat, Moniek P. M., van Gaalen, Kim, van Beusekom, Heleen M., van der Lugt, Aad, Fereidoonnezhad, Behrooz, Akyildiz, Ali C., and Gijsen, Frank J. H.

Abstract

Endovascular thrombectomy procedures are significantly influenced by the mechanical response of thrombi to the multi-axial loading imposed during retrieval. Compression tests are commonly used to determine compressive ex vivo thrombus and clot analogue stiffness. However, there is a shortage of data in tension. This study compares the tensile and compressive response of clot analogues made from the blood of healthy human donors in a range of compositions. Citrated whole blood was collected from six healthy human donors. Contracted and non-contracted fibrin clots, whole blood clots and clots reconstructed with a range of red blood cell (RBC) volumetric concentrations (5–80%) were prepared under static conditions. Both uniaxial tension and unconfined compression tests were performed using custom-built setups. Approximately linear nominal stress–strain profiles were found under tension, while strong strain-stiffening profiles were observed under compression. Low- and high-strain stiffness values were acquired by applying a linear fit to the initial and final 10% of the nominal stress–strain curves. Tensile stiffness values were approximately 15 times higher than low-strain compressive stiffness and 40 times lower than high-strain compressive stiffness values. Tensile stiffness decreased with an increasing RBC volume in the blood mixture. In contrast, high-strain compressive stiffness values increased from 0 to 10%, followed by a decrease from 20 to 80% RBC volumes. Furthermore, inter-donor differences were observed with up to 50% variation in the stiffness of whole blood clot analogues prepared in the same manner between healthy human donors. [ABSTRACT FROM AUTHOR]

Published

2023

4. The definition of low wall shear stress and its effect on plaque progression estimation in human coronary arteries.

Author

Hartman, Eline M. J., De Nisco, Giuseppe, Gijsen, Frank J. H., Korteland, Suze-Anne, van der Steen, Anton F. W., Daemen, Joost, and Wentzel, Jolanda J.

Subjects

INTRAVASCULAR ultrasonography, CORONARY arteries, SHEAR walls, FRICTION, COMPUTATIONAL fluid dynamics, ATHEROSCLEROTIC plaque

Abstract

Wall shear stress (WSS), the frictional force of the blood on the vessel wall, plays a crucial role in atherosclerotic plaque development. Low WSS has been associated with plaque growth, however previous research used different approaches to define low WSS to investigate its effect on plaque progression. In this study, we used four methodologies to allocate low, mid and high WSS in one dataset of human coronary arteries and investigated the predictive power of low WSS for plaque progression. Coronary reconstructions were based on multimodality imaging, using intravascular ultrasound and CT-imaging. Vessel-specific flow was measured using Doppler wire and computational fluid dynamics was performed to calculate WSS. The absolute WSS range varied greatly between the coronary arteries. On the population level, the established pattern of most plaque progression at low WSS was apparent in all methodologies defining the WSS categories. However, for the individual patient, when using measured flow to determine WSS, the absolute WSS values range so widely, that the use of absolute thresholds to determine low WSS was not appropriate to identify regions at high risk for plaque progression. [ABSTRACT FROM AUTHOR]

Published

2021

5. Lipid-rich Plaques Detected by Near-infrared Spectroscopy Are More Frequently Exposed to High Shear Stress.

Author

Hartman, Eline M. J., De Nisco, Giuseppe, Kok, Annette M., Hoogendoorn, Ayla, Coenen, Adriaan, Mastik, Frits, Korteland, Suze-Anne, Nieman, Koen, Gijsen, Frank J. H., van der Steen, Anton F. W., Daemen, Joost, and Wentzel, Jolanda J.

Abstract

High wall shear stress (WSS) and near-infrared spectroscopy (NIRS) detected lipid-rich plaque (LRP) are both known to be associated with plaque destabilization and future adverse cardiovascular events. However, knowledge of spatial co-localization of LRP and high WSS is lacking. This study investigated the co-localization of LRP based on NIRS and high WSS. Fifty-three patients presenting acute coronary syndrome underwent NIRS-intravascular-ultrasound (NIRS-IVUS) imaging of a non-culprit coronary artery. WSS was obtained using WSS profiling in 3D-reconstructions of the coronary arteries based on fusion of IVUS-segmented lumen and CT-derived 3D-centerline. Thirty-eight vessels were available for final analysis and divided into 0.5 mm/45° sectors. LRP sectors, as identified by NIRS, were more often colocalized with high WSS than sectors without LRP. Moreover, there was a dose-dependent relationship between lipid content and high WSS exposure. This study is a first step in understanding the evolution of LRPs to vulnerable plaques. [ABSTRACT FROM AUTHOR]

Published

2021

6. Identification of the haemodynamic environment permissive for plaque erosion.

Author

McElroy, Michael, Kim, Yongcheol, Niccoli, Giampaolo, Vergallo, Rocco, Langford-Smith, Alexander, Crea, Filippo, Gijsen, Frank, Johnson, Thomas, Keshmiri, Amir, and White, Stephen J.

Subjects

HEMODYNAMICS, ATHEROSCLEROTIC plaque, ACUTE coronary syndrome, VASCULAR endothelium, OPTICAL coherence tomography

Abstract

Endothelial erosion of atherosclerotic plaques is the underlying cause of approximately 30% of acute coronary syndromes (ACS). As the vascular endothelium is profoundly affected by the haemodynamic environment to which it is exposed, we employed computational fluid dynamic (CFD) analysis of the luminal geometry from 17 patients with optical coherence tomography (OCT)-defined plaque erosion, to determine the flow environment permissive for plaque erosion. Our results demonstrate that 15 of the 17 cases analysed occurred on stenotic plaques with median 31% diameter stenosis (interquartile range 28–52%), where all but one of the adherent thrombi located proximal to, or within the region of maximum stenosis. Consequently, all flow metrics related to elevated flow were significantly increased (time averaged wall shear stress, maximum wall shear stress, time averaged wall shear stress gradient) with a reduction in relative residence time, compared to a non-diseased reference segment. We also identified two cases that did not exhibit an elevation of flow, but occurred in a region exposed to elevated oscillatory flow. Our study demonstrates that the majority of OCT-defined erosions occur where the endothelium is exposed to elevated flow, a haemodynamic environment known to evoke a distinctive phenotypic response in endothelial cells. [ABSTRACT FROM AUTHOR]

Published

2021

7. Imaging of inflammatory cellular protagonists in human atherosclerosis: a dual-isotope SPECT approach.

Author

Barrett, Hilary E., Meester, Eric J., van Gaalen, Kim, van der Heiden, Kim, Krenning, Boudewijn J., Beekman, Freek J., de Blois, Erik, de Swart, Jan, Verhagen, H J, Maina, Theodosia, Nock, Berthold A., Norenberg, Jeffrey P., de Jong, Marion, Gijsen, Frank J. H., and Bernsen, Monique R.

Subjects

SINGLE-photon emission computed tomography, CELL imaging, ATHEROSCLEROTIC plaque, SOMATOSTATIN receptors, ATHEROSCLEROSIS, INTRAVASCULAR ultrasonography, DUAL energy CT (Tomography), AMYLOID plaque

Abstract

Purpose: Atherosclerotic plaque development and progression signifies a complex inflammatory disease mediated by a multitude of proinflammatory leukocyte subsets. Using single photon emission computed tomography (SPECT) coupled with computed tomography (CT), this study tested a new dual-isotope acquisition protocol to assess each radiotracer's capability to identify plaque phenotype and inflammation levels pertaining to leukocytes expressing leukocyte function-associated antigen-1 (LFA-1) and the leukocyte subset of proinflammatory macrophages expressing somatostatin receptor subtype-2 (SST2). Individual radiotracer uptake was quantified and the presence of corresponding immunohistological cell markers was assessed. Methods: Human symptomatic carotid plaque segments were obtained from endarterectomy. Segments were incubated in dual-isotope radiotracers [111In]In-DOTA-butylamino-NorBIRT ([111In]In-Danbirt) and [99mTc]Tc-[N0–14,Asp0,Tyr3]-octreotate ([99mTc]Tc-Demotate 2) before scanning with SPECT/CT. Plaque phenotype was classified as pathological intimal thickening, fibrous cap atheroma or fibrocalcific using histology sections based on distinct morphological characteristics. Plaque segments were subsequently immuno-stained with LFA-1 and SST2 and quantified in terms of positive area fraction and compared against the corresponding SPECT images. Results: Focal uptake of co-localising dual-radiotracers identified the heterogeneous distribution of inflamed regions in the plaques which co-localised with positive immuno-stained regions of LFA-1 and SST2. [111In]In-Danbirt and [99mTc]Tc-Demotate 2 uptake demonstrated a significant positive correlation (r = 0.651; p = 0.001). Fibrous cap atheroma plaque phenotype correlated with the highest [111In]In-Danbirt and [99mTc]Tc-Demotate 2 uptake compared with fibrocalcific plaques and pathological intimal thickening phenotypes, in line with the immunohistological analyses. Conclusion: A dual-isotope acquisition protocol permits the imaging of multiple leukocyte subsets and the pro-inflammatory macrophages simultaneously in atherosclerotic plaque tissue. [111In]In-Danbirt may have added value for assessing the total inflammation levels in atherosclerotic plaques in addition to classifying plaque phenotype. [ABSTRACT FROM AUTHOR]

Published

2020

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

Author

Zahnd, Guillaume, Hoogendoorn, Ayla, Combaret, Nicolas, Karanasos, Antonios, Péry, Emilie, Sarry, Laurent, Motreff, Pascal, Niessen, Wiro, Regar, Evelyn, Soest, Gijs, Gijsen, Frank, and Walsum, Theo

Abstract

Purpose: Quantitative and automatic analysis of intracoronary optical coherence tomography images is useful and time-saving to assess cardiovascular risk in the clinical arena. Methods: First, the interfaces of the intima, media, and adventitia layers are segmented, by means of an original front propagation scheme, running in a 4D multi-parametric space, to simultaneously extract three non-crossing contours in the initial cross-sectional image. Second, information resulting from the tentative contours is exploited by a machine learning approach to identify healthy and diseased regions of the arterial wall. The framework is fully automatic. Results: The method was applied to 40 patients from two different medical centers. The framework was trained on 140 images and validated on 260 other images. For the contour segmentation method, the average segmentation errors were $$29 \pm 46~\upmu \text {m}$$ for the intima-media interface, $$30 \pm 50~\upmu \text {m}$$ for the media-adventitia interface, and $$50 \pm 64~\upmu \text {m}$$ for the adventitia-periadventitia interface. The classification method demonstrated a good accuracy, with a median Dice coefficient equal to 0.93 and an interquartile range of (0.78-0.98). Conclusion: The proposed framework demonstrated promising offline performances and could potentially be translated into a reliable tool for various clinical applications, such as quantification of tissue layer thickness and global summarization of healthy regions in entire pullbacks. [ABSTRACT FROM AUTHOR]

Published

2017

9. Fusion of fibrous cap thickness and wall shear stress to assess plaque vulnerability in coronary arteries: a pilot study.

Author

Zahnd, Guillaume, Schrauwen, Jelle, Karanasos, Antonios, Regar, Evelyn, Niessen, Wiro, Walsum, Theo, and Gijsen, Frank

Abstract

Purpose: Identification of rupture-prone plaques in coronary arteries is a major clinical challenge. Fibrous cap thickness and wall shear stress are two relevant image-based risk factors, but these two parameters are generally computed and analyzed separately. Accordingly, combining these two parameters can potentially improve the identification of at-risk regions. Therefore, the purpose of this study is to investigate the feasibility of the fusion of wall shear stress and fibrous cap thickness of coronary arteries in patient data. Methods: Fourteen patients were included in this pilot study. Imaging of the coronary arteries was performed with optical coherence tomography and with angiography. Fibrous cap thickness was automatically quantified from optical coherence tomography pullbacks using a contour segmentation approach based on fast marching. Wall shear stress was computed by applying computational fluid dynamics on the 3D volume reconstructed from two angiograms. The two parameters then were co-registered using anatomical landmarks such as side branches. Results: The two image modalities were successfully co-registered, with a mean (±SD) error corresponding to $$8.6\,\pm \,6.7\,\%$$ of the length of the analyzed region. For all the analyzed participants, the average thinnest portion of each fibrous cap was $$129\,\pm \,69\,\upmu \text {m}$$ , and the average WSS value at the location of the fibrous cap was $$1.46\,\pm \,1.16\,\text {Pa}$$ . A unique index was finally generated for each patient via the fusion of fibrous cap thickness and wall shear stress measurements, to translate all the measured parameters into a single risk map. Conclusion: The introduced risk map integrates two complementary parameters and has potential to provide valuable information about plaque vulnerability. [ABSTRACT FROM AUTHOR]

Published

2016

10. A Framework for Local Mechanical Characterization of Atherosclerotic Plaques: Combination of Ultrasound Displacement Imaging and Inverse Finite Element Analysis.

Author

Akyildiz, Ali, Hansen, Hendrik, Nieuwstadt, Harm, Speelman, Lambert, Korte, Chris, Steen, Antonius, and Gijsen, Frank

Abstract

Biomechanical models have the potential to predict plaque rupture. For reliable models, correct material properties of plaque components are a prerequisite. This study presents a new technique, where high resolution ultrasound displacement imaging and inverse finite element (FE) modeling is combined, to estimate material properties of plaque components. Iliac arteries with plaques were excised from 6 atherosclerotic pigs and subjected to an inflation test with pressures ranging from 10 to 120 mmHg. The arteries were imaged with high frequency 40 MHz ultrasound. Deformation maps of the plaques were reconstructed by cross correlation of the ultrasound radiofrequency data. Subsequently, the arteries were perfusion fixed for histology and structural components were identified. The histological data were registered to the ultrasound data to construct FE model of the plaques. Material properties of the arterial wall and the intima of the atherosclerotic plaques were estimated using a grid search method. The computed displacement fields showed good agreement with the measured displacement fields, implying that the FE models were able to capture local inhomogeneities within the plaque. On average, nonlinear stiffening of both the wall and the intima was observed, and the wall of the atheroslcerotic porcine iliac arteries was markedly stiffer than the intima (877 ± 459 vs. 100 ± 68 kPa at 100 mmHg). The large spread in the data further illustrates the wide variation of the material properties. We demonstrated the feasibility of a mixed experimental-numerical framework to determine the material properties of arterial wall and intima of atherosclerotic plaques from intact arteries, and concluded that, due to the observed variation, plaque specific properties are required for accurate stress simulations. [ABSTRACT FROM AUTHOR]

Published

2016

11. Semi-automated Quantification of Fibrous Cap Thickness in Intracoronary Optical Coherence Tomography.

Author

Zahnd, Guillaume, Karanasos, Antonios, van Soest, Gijs, Regar, Evelyn, Niessen, Wiro J., Gijsen, Frank, and van Walsum, Theo

Published

2014

12. Quantification of fibrous cap thickness in intracoronary optical coherence tomography with a contour segmentation method based on dynamic programming.

Author

Zahnd, Guillaume, Karanasos, Antonios, Soest, Gijs, Regar, Evelyn, Niessen, Wiro, Gijsen, Frank, and Walsum, Theo

Abstract

Objectives: Fibrous cap thickness is the most critical component of plaque stability. Therefore, in vivo quantification of cap thickness could yield valuable information for estimating the risk of plaque rupture. In the context of preoperative planning and perioperative decision making, intracoronary optical coherence tomography imaging can provide a very detailed characterization of the arterial wall structure. However, visual interpretation of the images is laborious, subject to variability, and therefore not always sufficiently reliable for immediate decision of treatment. Methods: A novel semiautomatic segmentation method to quantify coronary fibrous cap thickness in optical coherence tomography is introduced. To cope with the most challenging issue when estimating cap thickness (namely the diffuse appearance of the anatomical abluminal interface to be detected), the proposed method is based on a robust dynamic programming framework using a geometrical a priori. To determine the optimal parameter settings, a training phase was conducted on 10 patients. Results: Validated on a dataset of 179 images from 21 patients, the present framework could successfully extract the fibrous cap contours. When assessing minimal cap thickness, segmentation results from the proposed method were in good agreement with the reference tracings performed by a medical expert (mean absolute error and standard deviation of $$22\,\pm \,18\,\upmu \hbox {m},\hbox { R}\,=\,.73$$ ) and were similar to inter-observer reproducibility ( $$21\,\pm \,19\,\upmu \hbox {m}$$ , R = .74), while being significantly faster and fully reproducible. Conclusion: The proposed framework demonstrated promising performances and could potentially be used for online identification of high-risk plaques. [ABSTRACT FROM AUTHOR]

Published

2015

13. Fast and Accurate Pressure-Drop Prediction in Straightened Atherosclerotic Coronary Arteries.

Author

Schrauwen, Jelle, Koeze, Dion, Wentzel, Jolanda, Vosse, Frans, Steen, Anton, and Gijsen, Frank

Abstract

Atherosclerotic disease progression in coronary arteries is influenced by wall shear stress. To compute patient-specific wall shear stress, computational fluid dynamics (CFD) is required. In this study we propose a method for computing the pressure-drop in regions proximal and distal to a plaque, which can serve as a boundary condition in CFD. As a first step towards exploring the proposed method we investigated ten straightened coronary arteries. First, the flow fields were calculated with CFD and velocity profiles were fitted on the results. Second, the Navier-Stokes equation was simplified and solved with the found velocity profiles to obtain a pressure-drop estimate (Δ p). Next, Δ p was compared to the pressure-drop from CFD (Δ p) as a validation step. Finally, the velocity profiles, and thus the pressure-drop were predicted based on geometry and flow, resulting in Δ p. We found that Δ p adequately estimated Δ p with velocity profiles that have one free parameter β. This β was successfully related to geometry and flow, resulting in an excellent agreement between Δ p and Δ p: 3.9 ± 4.9% difference at Re = 150. We showed that this method can quickly and accurately predict pressure-drop on the basis of geometry and flow in straightened coronary arteries that are mildly diseased. [ABSTRACT FROM AUTHOR]

Published

2015

14. The Influence of Shear Stress on Restenosis.

Author

Cannon, Christopher P., Armani, Annemarie M., Duckers, Henricus J., Nabel, Elizabeth G., Thury, Attila, Wentzel, Jolanda J., Gijsen, Frank J. H., Schuurbiers, Johan C. H., Krams, Rob, de Feyter, Pim J., Serruys, Patrick W., and Slager, Cornelis J.

Abstract

Wall shear stress (WSS) is the (tangential) drag force acting on the luminal wall, induced by blood flow, normalized to wall area. As WSS is defined as force/area, its dimension equals that of pressure, i.e., N/m2 or Pa. An older, frequently used unit for shear stress, i.e., dyne/cm2 relates to Pa according to 1 Pa = 10 dyne/cm2. WSS on the endothelium (Fig. 1) can be calculated from the local shear rate (s−1) times blood viscosity (μ) (Pa/s). Shear rate is the spatial blood velocity gradient ([m/s]/m). Especially near the vessel wall, generally large velocity gradients between adjacent fluid layers exist and the shear stress is at its highest value. In a simple straight tube the Hagen-Poiseuille formula (WSS = 4μQ/πR3, with μ viscosity, R tube radius and Q flow) can be applied for steady laminar viscous flow. A normal WSS range of 0.68 ± 0.2 Pa was derived from Doppler based velocity measurements in angiographically normal coronary Fig. 1.Top: flow velocity profile in axial cross-section. Over a very small distance (bottom) velocity increases linearly with distance and wall shear rate (velocity difference/distance) approaches vd/d. arteries of 21 patients (1). Considering the fact that the flow in the investigated branches varied from 6 to 123.2 mL/min, while blood viscosity was assumed constant (3.5 mPa/s), the surprisingly narrow range of shear stress values clearly demonstrates the efficacy of the regulation of coronary lumen size by WSS. [ABSTRACT FROM AUTHOR]

Published

2007

15. Implications of a bioresorbable vascular scaffold implantation on vessel wall strain of the treated and the adjacent segments.

Author

Bourantas, Christos, Garcia-Garcia, Hector, Campos, Carlos, Zhang, Yao-Jun, Muramatsu, Takashi, Morel, Marie-Angèle, Nakatani, Shimpei, Gao, Xingyu, Cho, Yun-Kyeong, Isibashi, Yuki, Gijsen, Frank, Onuma, Yoshinobu, and Serruys, Patrick

Abstract

Background Metallic stents change permanently the mechanical properties of the vessel wall. However little is known about the implications of bioresorbable vascular scaffolds (BVS) on the vessel wall strain. Methods Patients (n = 53) implanted with an Absorb BVS that had palpographic evaluation at any time point [before device implantation, immediate after treatment, at short-term (6-12 months) or mid-term follow-up (24-36 months)] were included in the current analysis. The palpographic data were used to estimate the mean of the maximum strain values and the obtained measurements were classified using the Rotterdam classification (ROC) score and expressed as ROC/mm. Results Scaffold implantation led to a significant decrease of the vessel wall strain in the treated segment [0.35 (0.20, 0.38) vs. 0.19 (0.09, 0.29); P = 0.005] but it did not affect the proximal and distal edge. In patients who had serial palpographic examination the vessel wall strain continued to decrease in the scaffolded segment at short-term [0.20 (0.12, 0.29) vs. 0.14 (0.08, 0.20); P = 0.048] and mid-term follow-up [0.20 (0.12, 0.29) vs. 0.15 (0.10, 0.19), P = 0.024]. No changes were noted with time in the mechanical properties of the vessel wall at the proximal and distal edge. Conclusions Absorb BVS implantation results in a permanent alteration of the mechanical properties of the vessel wall in the treated segment. Long term follow-up data are needed in order to examine the clinical implications of these findings. [ABSTRACT FROM AUTHOR]

Published

2014

16. Small coronary calcifications are not detectable by 64-slice contrast enhanced computed tomography.

Author

Giessen, Alina, Gijsen, Frank, Wentzel, Jolanda, Jairam, Pushpa, Walsum, Theo, Neefjes, Lisan, Mollet, Nico, Niessen, Wiro, Vosse, Frans, Feyter, Pim, and Steen, Antonius

Abstract

Recently, small calcifications have been associated with unstable plaques. Plaque calcifications are both in intravascular ultrasound (IVUS) and multi-slice computed tomography (MSCT) easily recognized. However, smaller calcifications might be missed on MSCT due to its lower resolution. Because it is unknown to which extent calcifications can be detected with MSCT, we compared calcification detection on contrast enhanced MSCT with IVUS. The coronary arteries of patients with myocardial infarction or unstable angina were imaged by 64-slice MSCT angiography and IVUS. The IVUS and MSCT images were registered and the arteries were inspected on the presence of calcifications on both modalities independently. We measured the length and the maximum circumferential angle of each calcification on IVUS. In 31 arteries, we found 99 calcifications on IVUS, of which only 47 were also detected on MSCT. The calcifications missed on MSCT ( n = 52) were significantly smaller in angle (27° ± 16° vs. 59° ± 31°) and length (1.4 ± 0.8 vs. 3.7 ± 2.2 mm) than those detected on MSCT. Calcifications could only be detected reliably on MSCT if they were larger than 2.1 mm in length or 36° in angle. Half of the calcifications seen on the IVUS images cannot be detected on contrast enhanced 64-slice MSCT angiography images because of their size. The limited resolution of MSCT is the main reason for missing small calcifications. [ABSTRACT FROM AUTHOR]

Published

2011

17. 3D fusion of intravascular ultrasound and coronary computed tomography for in-vivo wall shear stress analysis: a feasibility study.

Author

Giessen, Alina, Schaap, Michiel, Gijsen, Frank, Groen, Harald, Walsum, Theo, Mollet, Nico, Dijkstra, Jouke, Vosse, Frans, Niessen, Wiro, Feyter, Pim, Steen, Antonius, and Wentzel, Jolanda

Abstract

Wall shear stress, the force per area acting on the lumen wall due to the blood flow, is an important biomechanical parameter in the localization and progression of atherosclerosis. To calculate shear stress and relate it to atherosclerosis, a 3D description of the lumen and vessel wall is required. We present a framework to obtain the 3D reconstruction of human coronary arteries by the fusion of intravascular ultrasound (IVUS) and coronary computed tomography angiography (CT). We imaged 23 patients with IVUS and CT. The images from both modalities were registered for 35 arteries, using bifurcations as landmarks. The IVUS images together with IVUS derived lumen and wall contours were positioned on the 3D centerline, which was derived from CT. The resulting 3D lumen and wall contours were transformed to a surface for calculation of shear stress and plaque thickness. We applied variations in selection of landmarks and investigated whether these variations influenced the relation between shear stress and plaque thickness. Fusion was successfully achieved in 31 of the 35 arteries. The average length of the fused segments was 36.4 ± 15.7 mm. The length in IVUS and CT of the fused parts correlated excellently ( R = 0.98). Both for a mildly diseased and a very diseased coronary artery, shear stress was calculated and related to plaque thickness. Variations in the selection of the landmarks for these two arteries did not affect the relationship between shear stress and plaque thickness. This new framework can therefore successfully be applied for shear stress analysis in human coronary arteries. [ABSTRACT FROM AUTHOR]

Published

2010

18. Call for Standards in Technical Documentation of Intracoronary Stents.

Author

Lanzer, Peter, Gijsen, Frank, Topoleski, L., and Holzapfel, Gerhard

Abstract

Copyright of Herz is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2010