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9. Sparse 2-D PZT-on-PCB Arrays With Density Tapering.

Author

Wei, Luxi, Boni, Enrico, Ramalli, Alessandro, Fool, Fabian, Noothout, Emile, van der Steen, Antonius F. W., Verweij, Martin D., Tortoli, Piero, De Jong, Nico, and Vos, Hendrik J.

Subjects
PIEZOELECTRIC ceramics, RAPID prototyping, PRINTED circuits
Abstract

Two-dimensional (2-D) arrays offer volumetric imaging capabilities without the need for probe translation or rotation. A sparse array with elements seeded in a tapering spiral pattern enables one-to-one connection to an ultrasound machine, thus allowing flexible transmission and reception strategies. To test the concept of sparse spiral array imaging, we have designed, realized, and characterized two prototype probes designed at 2.5-MHz low-frequency (LF) and 5-MHz high-frequency (HF) center frequencies. Both probes share the same electronic design, based on piezoelectric ceramics and rapid prototyping with printed circuit board substrates to wire the elements to external connectors. Different center frequencies were achieved by adjusting the piezoelectric layer thickness. The LF and HF prototype probes had 88% and 95% of working elements, producing peak pressures of 21 and 96 kPa/V when focused at 5 and 3 cm, respectively. The one-way −3-dB bandwidths were 26% and 32%. These results, together with experimental tests on tissue-mimicking phantoms, show that the probes are viable for volumetric imaging. [ABSTRACT FROM AUTHOR]

Published
2022
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13. Independent Component Analysis Filter for Small Vessel Contrast Imaging During Fast Tissue Motion.

Author

Wahyulaksana, Geraldi, Wei, Luxi, Schoormans, Jasper, Voorneveld, Jason, van der Steen, Antonius F. W., de Jong, Nico, and Vos, Hendrik J.

Subjects
INDEPENDENT component analysis, ULTRASOUND contrast media, SPEED, BLIND source separation, MICROBUBBLE diagnosis, SINGULAR value decomposition, MOTION, FLOW visualization
Abstract

Suppressing tissue clutter is an essential step in blood flow estimation and visualization, even when using ultrasound contrast agents. Blind source separation (BSS)-based clutter filter for high-framerate ultrasound imaging has been reported to perform better in tissue clutter suppression than the conventional frequency-based wall filter and nonlinear contrast pulsing schemes. The most notable BSS technique, singular value decomposition (SVD) has shown compelling results in cases of slow tissue motion. However, its performance degrades when the tissue motion is faster than the blood flow speed, conditions that are likely to occur when imaging the small vessels, such as in the myocardium. Independent component analysis (ICA) is another BSS technique that has been implemented as a clutter filter in the spatiotemporal domain. Instead, we propose to implement ICA in the spatial domain where motion should have less impact. In this work, we propose a clutter filter with the combination of SVD and ICA to improve the contrast-to-background ratio (CBR) in cases where tissue velocity is significantly faster than the flow speed. In an in vitro study, the range of fast tissue motion velocity was 5–25 mm/s and the range of flow speed was 1–12 mm/s. Our results show that the combination of ICA and SVD yields 7–10 dB higher CBR than SVD alone, especially in the tissue high-velocity range. The improvement is crucial for cardiac imaging where relatively fast myocardial motions are expected. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Dispersing and Sonoporating Biofilm-Associated Bacteria with Sonobactericide.

Author

Lattwein, Kirby R., Beekers, Inés, Kouijzer, Joop J. P., Leon-Grooters, Mariël, Langeveld, Simone A. G., van Rooij, Tom, van der Steen, Antonius F. W., de Jong, Nico, van Wamel, Willem J. B., and Kooiman, Klazina

Subjects
IMAGE analysis, BACTERIA, STAPHYLOCOCCUS aureus, CONFOCAL microscopy, PARTICLE analysis
Abstract

Bacteria encased in a biofilm poses significant challenges to successful treatment, since both the immune system and antibiotics are ineffective. Sonobactericide, which uses ultrasound and microbubbles, is a potential new strategy for increasing antimicrobial effectiveness or directly killing bacteria. Several studies suggest that sonobactericide can lead to bacterial dispersion or sonoporation (i.e., cell membrane permeabilization); however, real-time observations distinguishing individual bacteria during and directly after insonification are missing. Therefore, in this study, we investigated, in real-time and at high-resolution, the effects of ultrasound-induced microbubble oscillation on Staphylococcus aureus biofilms, without or with an antibiotic (oxacillin, 1 μg/mL). Biofilms were exposed to ultrasound (2 MHz, 100–400 kPa, 100–1000 cycles, every second for 30 s) during time-lapse confocal microscopy recordings of 10 min. Bacterial responses were quantified using post hoc image analysis with particle counting. Bacterial dispersion was observed as the dominant effect over sonoporation, resulting from oscillating microbubbles. Increasing pressure and cycles both led to significantly more dispersion, with the highest pressure leading to the most biofilm removal (up to 83.7%). Antibiotic presence led to more variable treatment responses, yet did not significantly impact the therapeutic efficacy of sonobactericide, suggesting synergism is not an immediate effect. These findings elucidate the direct effects induced by sonobactericide to best utilize its potential as a biofilm treatment strategy. [ABSTRACT FROM AUTHOR]

Published
2022
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15. Imaging inflammation in atherosclerotic plaques, targeting SST2 with [111In]In-DOTA-JR11.

Author

Meester, Eric J., Krenning, Boudewijn J., de Blois, Erik, de Jong, Marion, van der Steen, Antonius F. W., Bernsen, Monique R., and van der Heiden, Kim

Abstract

Background: Imaging Somatostatin Subtype Receptor 2 (SST2) expressing macrophages by [DOTA,Tyr3]-octreotate (DOTATATE) has proven successful for plaque detection. DOTA-JR11 is a SST2 targeting ligand with a five times higher tumor uptake than DOTATATE, and holds promise to improve plaque imaging. The aim of this study was to evaluate the potential of DOTA-JR11 for plaque detection. Methods and Results: Atherosclerotic ApoE−/− mice (n = 22) fed an atherogenic diet were imaged by SPECT/CT two hours post injection of [111In]In-DOTA-JR11 (~ 200 pmol, ~ 50 MBq). In vivo plaque uptake of [111In]In-DOTA-JR11 was visible in all mice, with a target-to-background-ratio (TBR) of 2.23 ± 0.35. Post-mortem scans after thymectomy and ex vivo scans of the arteries after excision of the arteries confirmed plaque uptake of the radioligand with TBRs of 2.46 ± 0.52 and 3.43 ± 1.45 respectively. Oil red O lipid-staining and ex vivo autoradiography of excised arteries showed [111In]In-DOTA-JR11 uptake at plaque locations. Histological processing showed CD68 (macrophages) and SST2 expressing cells in plaques. SPECT/CT, in vitro autoradiography and immunohistochemistry performed on slices of a human carotid endarterectomy sample showed [111In]In-DOTA-JR11 uptake at plaque locations containing CD68 and SST2 expressing cells. Conclusions: The results of this study indicate DOTA-JR11 as a promising ligand for visualization of atherosclerotic plaque inflammation. [ABSTRACT FROM AUTHOR]

Published
2021
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16. High Frame Rate Volumetric Imaging of Microbubbles Using a Sparse Array and Spatial Coherence Beamforming.

Author

Wei, Luxi, Wahyulaksana, Geraldi, Meijlink, Bram, Ramalli, Alessandro, Noothout, Emile, Verweij, Martin D., Boni, Enrico, Kooiman, Klazina, van der Steen, Antonius F. W., Tortoli, Piero, de Jong, Nico, and Vos, Hendrik J.

Subjects
MICROBUBBLE diagnosis, MICROBUBBLES, BEAMFORMING, IMAGING phantoms, CHORIOALLANTOIS, CHICKEN embryos, ULTRASONIC imaging
Abstract

Volumetric ultrasound imaging of blood flow with microbubbles enables a more complete visualization of the microvasculature. Sparse arrays are ideal candidates to perform volumetric imaging at reduced manufacturing complexity and cable count. However, due to the small number of transducer elements, sparse arrays often come with high clutter levels, especially when wide beams are transmitted to increase the frame rate. In this study, we demonstrate with a prototype sparse array probe and a diverging wave transmission strategy, that a uniform transmission field can be achieved. With the implementation of a spatial coherence beamformer, the background clutter signal can be effectively suppressed, leading to a signal to background ratio improvement of 25 dB. With this approach, we demonstrate the volumetric visualization of single microbubbles in a tissue-mimicking phantom as well as vasculature mapping in a live chicken embryo chorioallantoic membrane. [ABSTRACT FROM AUTHOR]

Published
2021
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17. Multicomponent Mechanical Characterization of Atherosclerotic Human Coronary Arteries: An Experimental and Computational Hybrid Approach.

Author

Guvenir Torun, Su, Torun, Hakki M., Hansen, Hendrik H. G., Gandini, Giulia, Berselli, Irene, Codazzi, Veronica, de Korte, Chris L., van der Steen, Antonius F. W., Migliavacca, Francesco, Chiastra, Claudio, and Akyildiz, Ali C.

Subjects
CORONARY arteries, ATHEROSCLEROTIC plaque, STRAINS & stresses (Mechanics), ULTRASONIC imaging, MYOCARDIAL infarction
Abstract

Atherosclerotic plaque rupture in coronary arteries, an important trigger of myocardial infarction, is shown to correlate with high levels of pressure-induced mechanical stresses in plaques. Finite element (FE) analyses are commonly used for plaque stress assessment. However, the required information of heterogenous material properties of atherosclerotic coronaries remains to be scarce. In this work, we characterized the component-wise mechanical properties of atherosclerotic human coronary arteries. To achieve this, we performed ex vivo inflation tests on post-mortem human coronary arteries and developed an inverse FE modeling (iFEM) pipeline, which combined high-frequency ultrasound deformation measurements, a high-field magnetic resonance-based artery composition characterization, and a machine learning-based Bayesian optimization (BO) with uniqueness assessment. By using the developed pipeline, 10 cross-sections from five atherosclerotic human coronary arteries were analyzed, and the Yeoh material model constants of the fibrous intima and arterial wall components were determined. This work outlines the developed pipeline and provides the knowledge of non-linear, multicomponent mechanical properties of atherosclerotic human coronary arteries. [ABSTRACT FROM AUTHOR]

Published
2021
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18. Dolichoarteriopathies of the extracranial internal carotid artery: The Plaque At RISK study.

Author

Dilba, Kristine, van Dam‐Nolen, Dianne H. K., Crombag, Geneviève A. J. C., van der Kolk, Anja G., Koudstaal, Peter J., Nederkoorn, Paul J., Hendrikse, Jeroen, Kooi, Marianne Eline, van der Steen, Antonius F. W., Wentzel, Jolanda J., van der Lugt, Aad, and Bos, Daniel

Subjects
INTERNAL carotid artery, ATHEROSCLEROTIC plaque, COMPUTED tomography, MOYAMOYA disease, CEREBROVASCULAR disease, SYMPTOMS, LOGISTIC regression analysis
Abstract

Background and purpose: Dolichoarteriopathies of the extracranial part of the internal carotid artery (ICA) are associated with cerebrovascular events, yet information on their prevalence and risk factors remains limited. The aim of the present study therefore was to study the prevalence and risk factors of dolichoarteriopathies in a sample of patients with cerebrovascular symptoms from the Plaque At RISK (PARISK) study. Methods: In a random sample of 100 patients from the PARISK study, multidetector computed tomography angiography (MDCTA) was performed as part of clinical workup. On MDCTA, we evaluated the extracranial trajectory of the ICA by measuring the length (in millimeters), the tortuosity index (TI; defined as the ICA length divided by the shortest possible distance from bifurcation to skull base), and dolichoarteriopathy type (tortuosity, coiling or kinking). Next, we investigated the association between cardiovascular risk factors and these measurements using linear and logistic regression analyses. Results: The mean (standard deviation) length of the ICA was 93 (± 14) mm, with a median (interquartile range) TI of 1.2 (1.1–1.3). The overall prevalence of dolichoarteriopathies was 69%, with tortuosity being the most common (72%), followed by coiling (20%), and kinking (8%). We found that age and obesity were associated with a higher TI: difference per 10‐year increase in age: 0.05 (95% confidence interval [CI] 0.02–0.08) and 0.16 (95% CI 0.07–0.25) for obesity. Obesity and hypercholesterolemia were associated with a more severe type of dolichoarteriopathy (odds ratio [OR] 2.07 [95% CI 1.04–4.12] and OR 2.17 [95% CI 1.02–4.63], respectively). Conclusion: Dolichoarteriopathies in the extracranial ICA are common in patients with cerebrovascular symptoms, and age, obesity and hypercholesterolemia may play an important role in the pathophysiology of these abnormalities. [ABSTRACT FROM AUTHOR]

Published
2021
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19. Optimization of Microbubble Concentration and Acoustic Pressure for Left Ventricular High-Frame-Rate EchoPIV in Patients.

Author

Voorneveld, Jason, Keijzer, Lana B. H., Strachinaru, Mihai, Bowen, Daniel J., Mutluer, Ferit Onur, van der Steen, Antonius F. W., Cate, Folkert J. Ten, de Jong, Nico, Vos, Hendrik J., van den Bosch, Annemien E., and Bosch, Johan G.

Subjects
SOUND pressure, MICROBUBBLES, ULTRASOUND contrast media, HEART failure, BLOOD flow, OTOACOUSTIC emissions, AORTA
Abstract

High-frame-rate (HFR) echo-particle image velocimetry (echoPIV) is a promising tool for measuring intracardiac blood flow dynamics. In this study, we investigate the optimal ultrasound contrast agent (UCA: SonoVue) infusion rate and acoustic output to use for HFR echoPIV (PRF = 4900 Hz) in the left ventricle (LV) of patients. Three infusion rates (0.3, 0.6, and 1.2 ml/min) and five acoustic output amplitudes (by varying transmit voltage: 5, 10, 15, 20, and 30 V—corresponding to mechanical indices of 0.01, 0.02, 0.03, 0.04, and 0.06 at 60-mm depth) were tested in 20 patients admitted for symptoms of heart failure. We assess the accuracy of HFR echoPIV against pulsed-wave Doppler acquisitions obtained for mitral inflow and aortic outflow. In terms of image quality, the 1.2-ml/min infusion rate provided the highest contrast-to-background ratio (CBR) (3-dB improvement over 0.3 ml/min). The highest acoustic output tested resulted in the lowest CBR. Increased acoustic output also resulted in increased microbubble disruption. For the echoPIV results, the 1.2-ml/min infusion rate provided the best vector quality and accuracy; mid-range acoustic outputs (corresponding to 15–20-V transmit voltages) provided the best agreement with the pulsed-wave Doppler. Overall, the highest infusion rate (1.2 ml/min) and mid-range acoustic output amplitudes provided the best image quality and echoPIV results. [ABSTRACT FROM AUTHOR]

Published
2021
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20. Real-Time Coded Excitation Imaging Using a CMUT-Based Side Looking Array for Intravascular Ultrasound.

Author

Zangabad, Reza Pakdaman, Bosch, Johan G., Mastik, Frits, Beurskens, Robert H. S. H., Henneken, Vincent A., Weekamp, Johannes W., van der Steen, Antonius F. W., and van Soest, Gijs

Subjects
INTRAVASCULAR ultrasonography, ULTRASONIC imaging, IMAGING phantoms, ATHEROSCLEROTIC plaque, TRANSDUCERS, MODULATION coding
Abstract

Intravascular ultrasound (IVUS) is a well-established diagnostic method that provides images of the vessel wall and atherosclerotic plaques. We investigate the potential for phased-array IVUS utilizing coded excitation (CE) for improving the penetration depth and image signal-to-noise ratio (SNR). It is realized on a new experimental broadband capacitive micromachined ultrasound transducer (CMUT) array, operated in collapse mode, with 96 elements placed at the circumference of a catheter tip with a 1.2-mm diameter. We characterized the array performance for CE imaging and showed that the −6-dB device bandwidth at a 30-V dc biasing is 25 MHz with a 20-MHz center frequency, with a transmit sensitivity of 37 kPa/V at that frequency. We designed a linear frequency modulation code to improve penetration depth by compensating for high-frequency attenuation while preserving resolution by a mismatched filter reconstruction. We imaged a wire phantom and a human coronary artery plaque. By assessing the image quality of the reconstructed wire phantom image, we achieved 60- and 70-μm axial resolutions using the short pulse and coded signal, respectively, and gained 8 dB in SNR for CE. Our developed system shows 20-frames/s, pixel-based beam-formed, real-time IVUS images. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Vulnerable plaques and patients: state-of-the-art.

Author

Tomaniak, Mariusz, Katagiri, Yuki, Modolo, Rodrigo, de Silva, Ranil, Khamis, Ramzi Y., Bourantas, Christos V., Torii, Ryo, Wentzel, Jolanda J., Gijsen, Frank J. H., van Soest, Gijs, Stone, Peter H., West, Nick E. J., Maehara, Akiko, Lerman, Amir, van der Steen, Antonius F. W., Lüscher, Thomas F., Virmani, Renu, Wolfgang Koenig, Stone, Gregg W., and Muller, James E.

Abstract

Despite advanced understanding of the biology of atherosclerosis, coronary heart disease remains the leading cause of death worldwide. Progress has been challenging as half of the individuals who suffer sudden cardiac death do not experience premonitory symptoms. Furthermore, it is well-recognized that also a plaque that does not cause a haemodynamically significant stenosis can trigger a sudden cardiac event, yet the majority of ruptured or eroded plaques remain clinically silent. In the past 30 years since the term ‘vulnerable plaque’ was introduced, there have been major advances in the understanding of plaque pathogenesis and pathophysiology, shifting from pursuing features of ‘vulnerability’ of a specific lesion to the more comprehensive goal of identifying patient ‘cardiovascular vulnerability’. It has been also recognized that aside a thin-capped, lipid-rich plaque associated with plaque rupture, acute coronary syndromes (ACS) are also caused by plaque erosion underlying between 25% and 60% of ACS nowadays, by calcified nodule or by functional coronary alterations. While there have been advances in preventive strategies and in pharmacotherapy, with improved agents to reduce cholesterol, thrombosis, and inflammation, events continue to occur in patients receiving optimal medical treatment. Although at present the positive predictive value of imaging precursors of the culprit plaques remains too low for clinical relevance, improving coronary plaque imaging may be instrumental in guiding pharmacotherapy intensity and could facilitate optimal allocation of novel, more aggressive, and costly treatment strategies. Recent technical and diagnostic advances justify continuation of interdisciplinary research efforts to improve cardiovascular prognosis by both systemic and ‘local’ diagnostics and therapies. The present state-of-the-art document aims to present and critically appraise the latest evidence, developments, and future perspectives in detection, prevention, and treatment of ‘high-risk’ plaques occurring in ‘vulnerable’ patients. [ABSTRACT FROM AUTHOR]

Published
2020
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22. Functional Ultrasound (fUS) During Awake Brain Surgery: The Clinical Potential of Intra-Operative Functional and Vascular Brain Mapping.

Author

Soloukey, Sadaf, Vincent, Arnaud J. P. E., Satoer, Djaina D., Mastik, Frits, Smits, Marion, Dirven, Clemens M. F., Strydis, Christos, Bosch, Johannes G., van der Steen, Antonius F. W., De Zeeuw, Chris I., Koekkoek, Sebastiaan K. E., and Kruizinga, Pieter

Subjects
BRAIN surgery, BRAIN mapping, TEMPORAL lobe, FRONTAL lobe, BRAIN tumors
Abstract

Background and Purpose: Oncological neurosurgery relies heavily on making continuous, intra-operative tumor-brain delineations based on image-guidance. Limitations of currently available imaging techniques call for the development of real-time image-guided resection tools, which allow for reliable functional and anatomical information in an intra-operative setting. Functional ultrasound (fUS), is a new mobile neuro-imaging tool with unprecedented spatiotemporal resolution, which allows for the detection of small changes in blood dynamics that reflect changes in metabolic activity of activated neurons through neurovascular coupling. We have applied fUS during conventional awake brain surgery to determine its clinical potential for both intra-operative functional and vascular brain mapping, with the ultimate aim of achieving maximum safe tumor resection. Methods: During awake brain surgery, fUS was used to image tumor vasculature and task-evoked brain activation with electrocortical stimulation mapping (ESM) as a gold standard. For functional imaging, patients were presented with motor, language or visual tasks, while the probe was placed over (ESM-defined) functional brain areas. For tumor vascular imaging, tumor tissue (pre-resection) and tumor resection cavity (post-resection) were imaged by moving the hand-held probe along a continuous trajectory over the regions of interest. Results: A total of 10 patients were included, with predominantly intra-parenchymal frontal and temporal lobe tumors of both low and higher histopathological grades. fUS was able to detect (ESM-defined) functional areas deep inside the brain for a range of functional tasks including language processing. Brain tissue could be imaged at a spatial and temporal resolution of 300 μm and 1.5–2.0 ms respectively, revealing real-time tumor-specific, and healthy vascular characteristics. Conclusion: The current study presents the potential of applying fUS during awake brain surgery. We illustrate the relevance of fUS for awake brain surgery based on its ability to capture both task-evoked functional cortical responses as well as differences in vascular characteristics between tumor and healthy tissue. As current neurosurgical practice is still pre-dominantly leaning on inherently limited pre-operative imaging techniques for tumor resection-guidance, fUS enters the scene as a promising alternative that is both anatomically and physiologically informative. [ABSTRACT FROM AUTHOR]

Published
2020
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23. High Frame Rate Ultrasound Particle Image Velocimetry for Estimating High Velocity Flow Patterns in the Left Ventricle.

Author

Voorneveld, Jason, Muralidharan, Aswin, Hope, Timothy, Vos, Hendrik J., Kruizinga, Pieter, van der Steen, Antonius F. W., Gijsen, Frank J. H., Kenjeres, Sasa, de Jong, Nico, and Bosch, Johan G.

Subjects
ULTRASONIC imaging, PARTICLE image velocimetry, LEFT heart ventricle, BLOOD flow, KINETIC energy
Abstract

Echocardiographic determination of multicomponent blood flow dynamics in the left ventricle remains a challenge. In this paper, we compare contrast enhanced, high frame rate (HFR) (1000 frames/s) echo-particle image velocimetry (ePIV) against optical particle image velocimetry (oPIV, gold standard), in a realistic left ventricular (LV) phantom. We find that ePIV compares well to oPIV, even for the high velocity inflow jet (normalized RMSE = 9% ± 1%). In addition, we perform the method of proper orthogonal decomposition, to better qualify and quantify the differences between the two modalities. We show that ePIV and oPIV resolve very similar flow structures, especially for the lowest order mode with a cosine similarity index of 86%. The coarser resolution of ePIV does result in increased variance and blurring of smaller flow structures when compared to oPIV. However, both modalities are in good agreement with each other for the modes that constitute the bulk of the kinetic energy. We conclude that HFR ePIV can accurately estimate the high velocity diastolic inflow jet and the high energy flow structures in an LV setting. [ABSTRACT FROM AUTHOR]

Published
2018
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24. Sparse Ultrasound Image Reconstruction From a Shape-Sensing Single-Element Forward-Looking Catheter.

Author

Janjic, Jovana, Mastik, Frits, Leistikow, Merel D., Bosch, Johan G., Springeling, Geert, van der Steen, Antonius F. W., and van Soest, Gijs

Subjects
ULTRASONIC imaging, FORWARD-looking infrared sensors, ANISOTROPY, CATHETERS, ACOUSTIC imaging
Abstract

Objective: Minimally invasive procedures, such as intravascular and intracardiac interventions, may benefit from guidance with forward-looking (FL) ultrasound. In this work, we investigate FL ultrasound imaging using a single-element transducer integrated in a steerable catheter, together with an optical shape sensing (OSS) system. Methods: We tested the feasibility of the proposed device by imaging the surface of a tissue-mimicking (TM) phantom and an ex vivo human carotid plaque. While manually steering the catheter tip, ultrasound A-lines are acquired at 60 Hz together with the catheter shape from the OSS system, resulting in a two-dimensional sparse and irregularly sampled data set. We implemented an adaptive Normalized Convolution (NC) algorithm to interpolate the sparse data set by applying an anisotropic Gaussian kernel that is rotated according to the local direction of the catheter scanning pattern. To choose the Gaussian widths tangential (${\sigma _t}$) and normal (${\sigma _n}$) to the scanning pattern, an exhaustive search was implemented based on RMSE computation on simulated data. Results: Simulations showed that the sparse data set contains only 5% of the original information. The chosen widths, ${\sigma _n} = \text{250}\;\mu {\textrm{m}}$ and ${\sigma _t} = \text{100}\;\mu{\textrm{m}}$ , are used to successfully reconstruct the surface of the phantom with a contrast ratio of 0.9. The same kernel is applied successfully to the carotid plaque data. Conclusion: The proposed approach enables FL imaging with a single ultrasound element, mounted on a steerable device. Significance: This principle may find application in a variety of image-guided interventions, such as chronic total occlusion (CTO) recanalization. [ABSTRACT FROM AUTHOR]

Published
2018
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25. A 2-D Ultrasound Transducer With Front-End ASIC and Low Cable Count for 3-D Forward-Looking Intravascular Imaging: Performance and Characterization.

Author

Janjic, Jovana, Tan, Mingliang, Daeichin, Verya, Noothout, Emile, Chen, Chao, Chen, Zhao, Chang, Zu-Yao, Beurskens, Robert H. S. H., van Soest, Gijs, van der Steen, Antonius F. W., Verweij, Martin D., Pertijs, Michiel A.P., and de Jong, Nico

Subjects
ULTRASONIC transducers, INTRAVASCULAR ultrasonography, ATHEROSCLEROSIS, IMAGE quality analysis, FINITE element method, ARTERIAL occlusions, MAGNETIC resonance imaging
Abstract

Intravascular ultrasound (IVUS) is an imaging modality used to visualize atherosclerosis from within the inner lumen of human arteries. Complex lesions like chronic total occlusions require forward-looking IVUS (FL-IVUS), instead of the conventional side-looking geometry. Volumetric imaging can be achieved with 2-D array transducers, which present major challenges in reducing cable count and device integration. In this work, we present an 80-element lead zirconium titanate matrix ultrasound transducer for FL-IVUS imaging with a front-end application-specific integrated circuit (ASIC) requiring only four cables. After investigating optimal transducer designs, we fabricated the matrix transducer consisting of 16 transmit (TX) and 64 receive (RX) elements arranged on top of an ASIC having an outer diameter of 1.5 mm and a central hole of 0.5 mm for a guidewire. We modeled the transducer using finite-element analysis and compared the simulation results to the values obtained through acoustic measurements. The TX elements showed uniform behavior with a center frequency of 14 MHz, a −3-dB bandwidth of 44%, and a transmit sensitivity of 0.4 kPa/V at 6 mm. The RX elements showed center frequency and bandwidth similar to the TX elements, with an estimated receive sensitivity of $3.7~\mu \text{V}$ /Pa. We successfully acquired a 3-D FL image of three spherical reflectors in water using delay-and-sum beamforming and the coherence factor method. Full synthetic-aperture acquisition can be achieved with frame rates on the order of 100 Hz. The acoustic characterization and the initial imaging results show the potential of the proposed transducer to achieve 3-D FL-IVUS imaging. [ABSTRACT FROM AUTHOR]

Published
2018
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26. SPIO labeling of endothelial cells using ultrasound and targeted microbubbles at diagnostic pressures.

Author

Skachkov, Ilya, Luan, Ying, van Tiel, Sandra T., van der Steen, Antonius F. W., de Jong, Nico, Bernsen, Monique R., and Kooiman, Klazina

Subjects
ENDOTHELIAL cells, CARDIOVASCULAR disease diagnosis, ENDOTHELIUM, DIAGNOSTIC imaging, MEDICAL imaging systems
Abstract

In vivo cell tracking of therapeutic, tumor, and endothelial cells is an emerging field and a promising technique for imaging cardiovascular disease and cancer development. Site-specific labeling of endothelial cells with the MRI contrast agent superparamagnetic iron oxide (SPIO) in the absence of toxic agents is challenging. Therefore, the aim of this in vitro study was to find optimal parameters for efficient and safe SPIO-labeling of endothelial cells using ultrasound-activated CD31-targeted microbubbles for future MRI tracking. Ultrasound at a frequency of 1 MHz (10,000 cycles, repetition rate of 20 Hz) was used for varying applied peak negative pressures (10–160 kPa, i.e. low mechanical index (MI) of 0.01–0.16), treatment durations (0–30 s), time of SPIO addition (-5 min– 15 min with respect to the start of the ultrasound), and incubation time after SPIO addition (5 min– 3 h). Iron specific Prussian Blue staining in combination with calcein-AM based cell viability assays were applied to define the most efficient and safe conditions for SPIO-labeling. Optimal SPIO labeling was observed when the ultrasound parameters were 40 kPa peak negative pressure (MI 0.04), applied for 30 s just before SPIO addition (0 min). Compared to the control, this resulted in an approximate 12 times increase of SPIO uptake in endothelial cells in vitro with 85% cell viability. Therefore, ultrasound-activated targeted ultrasound contrast agents show great potential for effective and safe labeling of endothelial cells with SPIO. [ABSTRACT FROM AUTHOR]

Published
2018
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27. Structured ultrasound microscopy.

Author

Janjic, Jovana, Kruizinga, Pieter, van der Meulen, Pim, Springeling, Geert, Mastik, Frits, Leus, Geert, Bosch, Johan G., van der Steen, Antonius F. W., and van Soest, Gijs

Subjects
ACOUSTIC microscopy, TRANSDUCERS, ACOUSTIC field, OPTICAL apertures, HIGH resolution imaging
Abstract

We present a form of acoustic microscopy, called Structured Ultrasound Microscopy (SUM). It creates a volumetric image by recording reflected echoes of ultrasound waves with a structured phase front using a moving single-element transducer and computational reconstruction. A priori knowledge of the acoustic field produced by the single element allows us to relate the received echoes to a 3D scatter map within the acoustic beam itself, leading to an isotropic resolution at all depths. An aberration mask in front of the acoustic element imposes the phase structure, broadening the beam and breaking the spatial coherence between different voxels at equal acoustic propagation delay, increasing the uniqueness of the reconstruction. By translating the transducer across the 3D volume, we synthetically enlarge the imaging aperture by using multiple overlapping and spatially sparsely sampled measurements to solve for the entire image. In this paper, we explain the SUM technique and demonstrate microscopic imaging at 20 MHz of a 2.3 × 2.3 × 1.2 mm object in water, with an isotropic resolution below 100 μm. The proposed approach allows for wide-field 3D imaging at isotropic microscopic resolution using a small unfocused ultrasound sensor and multiple spatially sparsely sampled measurements. This technique may find applications in many other fields where space is constrained, device simplicity is desired, and wide-field isotropic high-resolution imaging is required. [ABSTRACT FROM AUTHOR]

Published
2018
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30. Vibrational Responses of Bound and Nonbound Targeted Lipid-Coated Single Microbubbles.

Author

van Rooij, Tom, Beekers, Ines, Lattwein, Kirby R., van der Steen, Antonius F. W., de Jong, Nico, and Kooiman, Klazina

Subjects
MICROBUBBLE diagnosis, DIAGNOSTIC imaging, BIOMARKERS, PHYSISORPTION, ACOUSTICS, RESONANCE frequency analysis
Abstract

One of the main challenges for ultrasound molecular imaging is acoustically distinguishing nonbound microbubbles from those bound to their molecular target. In this in vitro study, we compared two types of in-house produced targeted lipid-coated microbubbles, either consisting of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine, C16:0 (DPPC) or 1,2-distearoyl-sn-glycero-3-phosphocholine, C18:0 (DSPC) as the main lipid, using the Brandaris 128 ultrahigh-speed camera to determine vibrational response differences between bound and nonbound biotinylated microbubbles. In contrast to previous studies that studied vibrational differences upon binding, we used a covalently bound model biomarker (i.e., streptavidin) rather than physisorption, to ensure binding of the biomarker to the membrane. The microbubbles were insonified at frequencies between 1 and 4 MHz at pressures of 50 and 150 kPa. This paper shows lower acoustic stability of bound microbubbles, of which DPPC-based microbubbles deflated most. For DPPC microbubbles with diameters between 2 and 4~\mu \textm driven at 50 kPa, resonance frequencies of bound microbubbles were all higher than 1.8 MHz, whereas those of nonbound microbubbles were significantly lower. In addition, the relative radial excursions at resonance were also higher for bound DPPC microbubbles. These differences did not persist when the pressure was increased to 150 kPa, except for the acoustic stability which further decreased. No differences in resonance frequencies were observed between bound and nonbound DSPC microbubbles. Nonlinear responses in terms of emissions at the subharmonic and second harmonic frequencies were similar for bound and nonbound microbubbles at both pressures. In conclusion, we identified differences in vibrational responses of bound DPPC microbubbles with diameters between 2 and 4~\mu \textm that distinguish them from nonbound ones. [ABSTRACT FROM AUTHOR]

Published
2017
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31. Microbubble Composition and Preparation for High-Frequency Contrast-Enhanced Ultrasound Imaging: In Vitro and In Vivo Evaluation.

Author

Daeichin, Verya, van Rooij, Tom, Skachkov, Ilya, Ergin, Bulent, Specht, Patricia A. C., Lima, Alexandre, Ince, Can, Bosch, Johan G., van der Steen, Antonius F. W., de Jong, Nico, and Kooiman, Klazina

Subjects
ULTRASONIC imaging, MICROBUBBLE diagnosis, IN vitro studies, IN vivo studies, CONTRAST media, ELECTRON tubes
Abstract

Although high-frequency ultrasound imaging is gaining attention in various applications, hardly any ultrasound contrast agents (UCAs) dedicated to such frequencies (>15 MHz) are available for contrast-enhanced ultrasound (CEUS) imaging. Moreover, the composition of the limited commercially available UCAs for high-frequency CEUS (hfCEUS) is largely unknown, while shell properties have been shown to be an important factor for their performance. The aim of our study was to produce UCAs in-house for hfCEUS. Twelve different UCA formulations A-L were made by either sonication or mechanical agitation. The gas core consisted of C4F10 and the main coating lipid was either 1,2-distearoyl-sn-glycero-3-phosphocholine (DSPC; A-F formulation) or 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC; G-L formulation). Mechanical agitation resulted in UCAs with smaller microbubbles (number weighted mean diameter ~1 \mu \textm ) than sonication (number weighted mean diameter ~2 \mu \textm ). UCA formulations with similar size distributions but different main lipid components showed that the DPPC-based UCA formulations had higher nonlinear responses at both the fundamental and subharmonic frequencies in vitro for hfCEUS using the Vevo2100 high-frequency preclinical scanner (FUJIFILM VisualSonics, Inc.). In addition, UCA formulations F (DSPC-based) and L (DPPC-based) that were made by mechanical agitation performed similar in vitro to the commercially available Target-Ready MicroMarker (FUJIFILM VisualSonics, Inc.). UCA formulation F also performed similar to Target-Ready MicroMarker in vivo in pigs with similar mean contrast intensity within the kidney ( $n = 7$ ), but formulation L did not. This is likely due to the lower stability of formulation L in vivo. Our study shows that DSPC-based microbubbles produced by mechanical agitation resulted in small microbubbles with high nonlinear responses suitable for hfCEUS imaging. [ABSTRACT FROM AUTHOR]

Published
2017
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32. Acoustic Characterization of the CLINIcell for Ultrasound Contrast Agent Studies.

Author

Beekers, Ines, van Rooij, Tom, van der Steen, Antonius F. W., de Jong, Nico, Verweij, Martin D., and Kooiman, Klazina

Subjects
ACOUSTICS, ULTRASONIC imaging, MAGNETIC resonance imaging, CONTRAST-enhanced ultrasound, NANOPARTICLES
Abstract

Ultrasound contrast agents consist of gas-filled coated microbubbles that oscillate upon ultrasound insonification. Their characteristic oscillatory response provides contrast enhancement for imaging and has the potential to locally enhance drug delivery. Since microbubble response depends on the local acoustic pressure, an ultrasound compatible chamber is needed to study their behavior and the underlying drug delivery pathways. In this study, we determined the amplitude of the acoustic pressure in the CLINIcell, an optically transparent chamber suitable for cell culture. The pressure field was characterized based on microbubble response recorded using the Brandaris 128 ultrahigh-speed camera and an iterative processing method. The results were compared to a control experiment performed in an OptiCell, which is conventionally used in microbubble studies. Microbubbles in the CLINIcell responded in a controlled manner, comparable to those in the OptiCell. For frequencies from 1 to 4 MHz, the mean pressure amplitude was −5.4 dB with respect to the externally applied field. The predictable ultrasound pressure demonstrates the potential of the CLINIcell as an optical, ultrasound, and cell culture compatible device to study microbubble oscillation behavior and ultrasound-mediated drug delivery. [ABSTRACT FROM AUTHOR]

Published
2019
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33. Combined optical sizing and acoustical characterization of single freely-floating microbubbles.

Author

Ying Luan, Renaud, Guillaume, Raymond, Jason L., Segers, Tim, Lajoinie, Guillaume, Beurskens, Robert, Kokhuis, Tom J. A., van der Steen, Antonius F. W., Versluis, Michel, and de Jong, Nico

Subjects
MICROBUBBLES, CONTRAST media, ULTRASONIC waves, ACOUSTO-optic materials, EXCITATION spectrum, AXIAL flow, COMPUTER simulation
Abstract

In this study we present a combined optical sizing and acoustical characterization technique for the study of the dynamics of single freely-floating ultrasound contrast agent microbubbles exposed to long burst ultrasound excitations up to the milliseconds range. A co-axial flow device was used to position individual microbubbles on a streamline within the confocal region of three ultrasound transducers and a high-resolution microscope objective. Bright-field images of microbubbles passing through the confocal region were captured using a high-speed camera synchronized to the acoustical data acquisition to assess the microbubble response to a 1-MHz ultrasound burst. Nonlinear bubble vibrations were identified at a driving pressure as low as 50 kPa. The results demonstrate good agreement with numerical simulations based on the shell-buckling model proposed by Marmottant et al. [J. Acoust. Soc. Am. 118, 3499-3505 (2005)]. The system demonstrates the potential for a high-throughput in vitro characterization of individual microbubbles. [ABSTRACT FROM AUTHOR]

Published
2016
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34. Coronary fractional flow reserve measurements of a stenosed side branch: a computational study investigating the influence of the bifurcation angle.

Author

Chiastra, Claudio, Iannaccone, Francesco, Grundeken, Maik J., Gijsen, Frank J. H., Segers, Patrick, De Beule, Matthieu, Serruys, Patrick W., Wykrzykowska, Joanna J., van der Steen, Antonius F. W., and Wentzel, Jolanda J.

Subjects
CORONARY circulation, BLOOD flow, HEMODYNAMICS, CORONARY artery stenosis, BIFURCATION theory, COMPUTATIONAL fluid dynamics, COMPUTER simulation of fluid dynamics, BIOLOGICAL models, BLOOD pressure, PHYSICAL & theoretical chemistry, CORONARY arteries
Abstract

Background: Coronary hemodynamics and physiology specific for bifurcation lesions was not well understood. To investigate the influence of the bifurcation angle on the intracoronary hemodynamics of side branch (SB) lesions computational fluid dynamics simulations were performed.Methods: A parametric model representing a left anterior descending-first diagonal coronary bifurcation lesion was created according to the literature. Diameters obeyed fractal branching laws. Proximal and distal main branch (DMB) stenoses were both set at 60 %. We varied the distal bifurcation angles (40°, 55°, and 70°), the flow splits to the DMB and SB (55 %:45 %, 65 %:35 %, and 75 %:25 %), and the SB stenoses (40, 60, and 80 %), resulting in 27 simulations. Fractional flow reserve, defined as the ratio between the mean distal stenosis and mean aortic pressure during maximal hyperemia, was calculated for the DMB and SB (FFRSB) for all simulations.Results: The largest differences in FFRSB comparing the largest and smallest bifurcation angles were 0.02 (in cases with 40 % SB stenosis, irrespective of the assumed flow split) and 0.05 (in cases with 60 % SB stenosis, flow split 55 %:45 %). When the SB stenosis was 80 %, the difference in FFRSB between the largest and smallest bifurcation angle was 0.33 (flow split 55 %:45 %). By describing the ΔPSB-QSB relationship using a quadratic curve for cases with 80 % SB stenosis, we found that the curve was steeper (i.e. higher flow resistance) when bifurcation angle increases (ΔP = 0.451*Q + 0.010*Q (2) and ΔP = 0.687*Q + 0.017*Q (2) for 40° and 70° bifurcation angle, respectively). Our analyses revealed complex hemodynamics in all cases with evident counter-rotating helical flow structures. Larger bifurcation angles resulted in more pronounced helical flow structures (i.e. higher helicity intensity), when 60 or 80 % SB stenoses were present. A good correlation (R(2) = 0.80) between the SB pressure drop and helicity intensity was also found.Conclusions: Our analyses showed that, in bifurcation lesions with 60 % MB stenosis and 80 % SB stenosis, SB pressure drop is higher for larger bifurcation angles suggesting higher flow resistance (i.e. curves describing the ΔPSB-QSB relationship being steeper). When the SB stenosis is mild (40 %) or moderate (60 %), SB resistance is minimally influenced by the bifurcation angle, with differences not being clinically meaningful. Our findings also highlighted the complex interplay between anatomy, pressure drops, and blood flow helicity in bifurcations. [ABSTRACT FROM AUTHOR]

Published
2016
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35. Improving the Performance of a 1-D Ultrasound Transducer Array by Subdicing.

Author

Janjic, Jovana, Shabanimotlagh, Maysam, van Soest, Gijs, van der Steen, Antonius F. W., de Jong, Nico, and Verweij, Martin D.

Subjects
ULTRASONIC transducers, ACOUSTIC transducer arrays, VIBRATION (Mechanics), UNIFORM motion, FINITE element method
Abstract

In medical ultrasound transducer design, the geometry of the individual elements is crucial since it affects the vibration mode of each element and its radiation impedance. For a fixed frequency, optimal vibration (i.e., uniform surface motion) can be achieved by designing elements with very small width-to-thickness ratios. However, for optimal radiation impedance (i.e., highest radiated power), the width should be as large as possible. This leads to a contradiction that can be solved by subdicing wide elements. To systematically examine the effect of subdicing on the performance of a 1-D ultrasound transducer array, we applied finite-element simulations. We investigated the influence of subdicing on the radiation impedance, on the time and frequency response, and on the directivity of linear arrays with variable element widths. We also studied the effect of varying the depth of the subdicing cut. The results show that, for elements having a width greater than 0.6 times the wavelength, subdicing improves the performance compared with that of nonsubdiced elements: the emitted pressure may be increased up to a factor of three, the ringing time may be reduced by up to 50%, the bandwidth increased by up to 77%, and the sidelobes reduced by up to 13 dB. Moreover, this simulation study shows that all these improvements can already be achieved by subdicing the elements to a depth of 70% of the total element thickness. Thus, subdicing can improve important transducer parameters and, therefore, help in achieving images with improved signal-to-noise ratio and improved resolution. [ABSTRACT FROM PUBLISHER]

Published
2016
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36. The impact of scaled boundary conditions on wall shear stress computations in atherosclerotic human coronary bifurcations.

Author

Schrauwen, Jelle T. C., Schwarz, Janina C. V., Wentzel, Jolanda J., van der Steen, Antonius F. W., Siebes, Maria, and Gijsen, Frank J. H.

Subjects
BOUNDARY value problems, SHEARING force, ATHEROSCLEROSIS
Abstract

The aim of this study was to determine if reliable patient-specific wall shear stress (WSS) can be computed when diameter-based scaling laws are used to impose the boundary conditions for computational fluid dynamics. This study focused on mildly diseased human coronary bifurcations since they are predilection sites for atherosclerosis. Eight patients scheduled for percutaneous coronary intervention were imaged with angiography. The velocity proximal and distal of a bifurcation was acquired with intravascular Doppler measurements. These measurements were used for inflow and outflow boundary conditions for the first set of WSS computations. For the second set of computations, absolute inflow and outflow ratios were derived from geometry-based scaling laws based on angiography data. Normalized WSS maps per segment were obtained by dividing the absolute WSS by the mean WSS value. Absolute and normalized WSS maps from the measuredapproach and the scaled-approach were compared. A reasonable agreement was found between the measured and scaled inflows, with a median difference of 0.08 ml/s [0.01; 0.20]. The measured and the scaled outflow ratios showed a good agreement: 1.5 percentage points [19.0; 4.5]. Absolute WSS maps were sensitive to the inflow and outflow variations, and relatively large differences between the two approaches were observed. For normalized WSS maps, the results for the two approaches were equivalent. This study showed that normalized WSS can be obtained from angiography data alone by applying diameter-based scaling laws to define the boundary conditions. Caution should be taken when absolute WSS is assessed from computations using scaled boundary conditions. [ABSTRACT FROM AUTHOR]

Published
2016
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37. Peak cap stress calculations in coronary atherosclerotic plaques with an incomplete necrotic core geometry.

Author

Kok, Annette M., Speelman, Lambert, Virmani, Renu, van der Steen, Antonius F. W., Gijsen, Frank J. H., and Wentzel, Jolanda J.

Subjects
ATHEROSCLEROTIC plaque, MECHANICAL stress analysis, CORONARY artery physiology, FINITE element method, HISTOLOGY, ATHEROSCLEROSIS, BIOLOGICAL models, CORONARY arteries, NECROSIS, PHYSIOLOGIC strain
Abstract

Background: Stress calculations in atherosclerotic coronary vulnerable plaques can aid in predicting coronary cap rupture. In vivo plaque geometry and composition of coronary arteries can merely be obtained via intravascular imaging. Only optical driven imaging techniques have sufficient resolution to visualize the fibrous cap, but due to limited penetration depth deeper components such as the backside of the necrotic core (NC) are generally not visible. The goal of this study was to investigate whether peak cap stresses can be approximated by reconstructing the backside of the NC.Methods: Manual segmentations of coronary histological cross-sections served as a geometrical ground truth and were obtained from seven patients resulting in 73 NCs. Next, the backside was removed and reconstructed according to an estimation of the relative necrotic core thickness (rNCt). The rNCt was estimated at three locations along the NC angle and based on either group averaged parameters or plaque specific parameters. Stress calculations were performed in both the ground truth geometry and the reconstructed geometries and compared.Results: Good geometrical agreement was found between the ground truth NC and the reconstructed NCs, based on group averaged rNCt estimation and plaque specific rNCt estimation, measuring the NC area difference (25.1 % IQR 14.0-41.3 % and 17.9 % IQR 9.81-32.7 %) and similarity index (0.85 IQR 0.77-0.90 and 0.88 IQR 0.79-0.91). The peak cap stresses obtained with both reconstruction methods showed a high correlation with respect to the ground truth, r(2) = 0.91 and r(2) = 0.95, respectively. For high stress plaques, the peak cap stress difference with respect to the ground truth significantly improved for the NC reconstruction based plaque specific features (6 %) compared to the reconstruction group averaged based (16 %).Conclusions: In conclusion, good geometry and stress agreement was observed between the ground truth NC geometry and the reconstructed geometries. Although group averaged rNCt estimation seemed to be sufficient for the NC reconstruction and stress calculations, including plaque specific data further improved stress predictions, especially for higher stresses. [ABSTRACT FROM AUTHOR]

Published
2016
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38. F– k Domain Imaging for Synthetic Aperture Sequential Beamforming.

Author

Vos, Hendrik J., van Neer, Paul L. M. J., Mota, Mariana Melo, Verweij, Martin D., van der Steen, Antonius F. W., and Volker, Arno W. F.

Subjects
SYNTHETIC apertures, BEAMFORMING, DIAGNOSTIC ultrasonic imaging, IMAGE quality analysis, APPLICATION-specific integrated circuits, WAVENUMBER
Abstract

Spatial resolution in medical ultrasound images is a key component in image quality and an important factor for clinical diagnosis. In early systems, the lateral resolution was optimal in the focus but rapidly decreased outside the focal region. Improvements have been found in, e.g., dynamic-receive beamforming, in which the entire image is focused in receive, but this requires complex processing of element data and is not applicable for mechanical scanning of single-element images. This paper exploits the concept of two-stage beamforming based on virtual source–receivers, which reduces the front-end computational load while maintaining a similar data rate and frame rate compared to dynamic-receive beamforming. We introduce frequency–wavenumber domain data processing to obtain fast second-stage data processing while having similarly high lateral resolution as dynamic-receive beamforming and processing in time-space domain. The technique is very suitable in combination with emerging technologies such as application-specific integrated circuits (ASICs), hand-held devices, and wireless data transfer. The suggested method consists of three steps. In the first step, single-focused RF line data are shifted in time to relocate the focal point to a new origin $t^\prime = 0,\;z^\prime = 0$. This new origin is considered as an array of virtual source/receiver pairs, as has been suggested previously in literature. In the second step, the dataset is efficiently processed in the wavenumber–frequency domain to form an image that is in focus throughout its entire depth. In the third step, the data shift is undone to obtain a correct depth axis in the image. The method has been tested first with a single-element scanning system and second in a tissue-mimicking phantom using a linear array. In both setups, the method resulted in a - {6}{\text{-dB}} lateral point spread function (PSF) which was constant over the entire depth range, and similar to dynamic-receive beamforming and synthetic aperture sequential beamforming. The signal-to-noise ratio increased by 6 dB in both the near field and far field. These results show that the second-stage processing algorithm effectively produces a focused image over the entire depth range from a single-focused ultrasound field. [ABSTRACT FROM AUTHOR]

Published
2016
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40. Influence of the Accuracy of Angiography-Based Reconstructions on Velocity and Wall Shear Stress Computations in Coronary Bifurcations: A Phantom Study.

Author

Schrauwen, Jelle T. C., Karanasos, Antonios, van Ditzhuijzen, Nienke S., Aben, Jean-Paul, van der Steen, Antonius F. W., Wentzel, Jolanda J., and Gijsen, Frank J. H.

Subjects
ANGIOGRAPHY, SHEARING force, BIFURCATION theory, IMAGING phantoms, COMPUTATIONAL fluid dynamics
Abstract

Introduction: Wall shear stress (WSS) plays a key role in the onset and progression of atherosclerosis in human coronary arteries. Especially sites with low and oscillating WSS near bifurcations have a higher propensity to develop atherosclerosis. WSS computations in coronary bifurcations can be performed in angiography-based 3D reconstructions. It is essential to evaluate how reconstruction errors influence WSS computations in mildly-diseased coronary bifurcations. In mildly-diseased lesions WSS could potentially provide more insight in plaque progression. Materials Methods: Four Plexiglas phantom models of coronary bifurcations were imaged with bi-plane angiography. The lumens were segmented by two clinically experienced readers. Based on the segmentations 3D models were generated. This resulted in three models per phantom: one gold-standard from the phantom model itself, and one from each reader. Steady-state and transient simulations were performed with computational fluid dynamics to compute the WSS. A similarity index and a noninferiority test were used to compare the WSS in the phantoms and their reconstructions. The margin for this test was based on the resolution constraints of angiography. Results: The reconstruction errors were similar to previously reported data; in seven out of eight reconstructions less than 0.10 mm. WSS in the regions proximal and far distal of the stenosis showed a good agreement. However, the low WSS areas directly distal of the stenosis showed some disagreement between the phantoms and the readers. This was due to small deviations in the reconstruction of the stenosis that caused differences in the resulting jet, and consequently the size and location of the low WSS area. Discussion: This study showed that WSS can accurately be computed within angiography-based 3D reconstructions of coronary arteries with early stage atherosclerosis. Qualitatively, there was a good agreement between the phantoms and the readers. Quantitatively, the low WSS regions directly distal to the stenosis were sensitive to small reconstruction errors. [ABSTRACT FROM AUTHOR]

Published
2015
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41. Dynamic acousto-elastic testing applied to a highly dispersive medium and evidence of shell buckling of lipid-coated gas microbubbles.

Author

Renaud, Guillaume, Bosch, Johan G., van der Steen, Antonius F. W., and de Jong, Nico

Subjects
ACOUSTOELASTICITY, MECHANICAL buckling, MICROBUBBLES, GAS mixtures, TIME-domain analysis
Abstract

Dynamic acousto-elastic testing is applied to a mixture of lipid-coated microbubbles in water. A dynamic change of ambient pressure is produced by a 16 kHz pressure wave having a peak pressure amplitude of 28 kPa. The induced changes of phase velocity and attenuation are captured by a sequence of short ultrasound pulses with a center frequency of 4 MHz. As a consequence of the dispersion brought about by the resonance of microbubbles at a frequency close to 2 MHz, time-domain approaches like the cross-correlation method are shown to be unsuited to determine the variation in ultrasound wavespeed. A frequency-domain analysis shows that the acousto-elastic effect (first order pressure derivative of ultrasound phase velocity) depends on the ultrasound frequency. The acousto-elastic effect tends to that measured in water for an ultrasound frequency above the resonance frequency of microbubbles, while it is two orders of magnitude larger for an ultrasound frequency close to or below the resonance frequency of microbubbles. Besides the large magnitude of the acousto-elastic effect observed for an ultrasound frequency below the resonance frequency of microbubbles, the first order pressure derivative of ultrasound phase velocity is negative. This supports the occurrence of shell buckling of lipid-coated microbubbles induced by the 16 kHz pressure wave. [ABSTRACT FROM AUTHOR]

Published
2015
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42. Photonics in cardiovascular medicine.

Author

van Soest, Gijs, Regar, Evelyn, and van der Steen, Antonius F. W.

Subjects
PHOTONICS, CARDIOVASCULAR disease diagnostic equipment, CARDIOVASCULAR disease treatment, HEART diseases, OPTICAL fiber detectors, LASER ablation, FABRY-Perot interferometers, EQUIPMENT & supplies
Abstract

The author discusses the cardiovascular application of photonics technology for the treatment and diagnosis of heart and arteries condition. Topics discussed include the use of optical fiber catheters to perform localized laser ablation, the introduction of Fabry-Pérot (FP) interferometer pressure sensing catheter, and the difference between the cardiovascular and cancer medicine.

Published
2015
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44. Quantification of bound microbubbles in ultrasound molecular imaging.

Author

Daeichin, Verya, Akkus, Zeynettin, Skachkov, Ilya, Kooiman, Klazina, Needles, Andrew, Sluimer, Judith, Janssen, Ben, Daemen, Mat J. A. P., van der Steen, Antonius F. W., de Jong, Nico, and Bosch, Johan G.

Subjects
MICROBUBBLES, MOLECULAR diagnosis, NONINVASIVE diagnostic tests, CONTRAST media, HYPERCHOLESTEREMIA, LABORATORY mice
Abstract

Molecular markers associated with diseases can be visualized and quantified noninvasively with targeted ultrasound contrast agent (t-UCA) consisting of microbubbles (MBs) that can bind to specific molecular targets. Techniques used for quantifying t-UCA assume that all unbound MBs are taken out of the blood pool few minutes after injection and only MBs bound to the molecular markers remain. However, differences in physiology, diseases, and experimental conditions can increase the longevity of unbound MBs. In such conditions, unbound MBs will falsely be quantified as bound MBs. We have developed a novel technique to distinguish and classify bound from unbound MBs. In the post-processing steps, first, tissue motion was compensated using block-matching (BM) techniques. To preserve only stationary contrast signals, a minimum intensity projection (MinIP) or 20th-percentile intensity projection (PerIP) was applied. The after-flash MinIP or PerIP was subtracted from the before-flash MinIP or PerIP. In this way, tissue artifacts in contrast images were suppressed. In the next step, bound MB candidates were detected. Finally, detected objects were tracked to classify the candidates as unbound or bound MBs based on their displacement. This technique was validated in vitro, followed by two in vivo experiments in mice. Tumors (n = 2) and salivary glands of hypercholesterolemic mice (n = 8) were imaged using a commercially available scanner. Boluses of 100 ?L of a commercially available t-UCA targeted to angiogenesis markers and untargeted control UCA were injected separately. Our results show considerable reduction in misclassification of unbound MBs as bound ones. Using our method, the ratio of bound MBs in salivary gland for images with targeted UCA versus control UCA was improved by up to two times compared with unprocessed images. [ABSTRACT FROM PUBLISHER]

Published
2015
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45. Lumen Segmentation and Motion Estimation in B-Mode and Contrast-Enhanced Ultrasound Images of the Carotid Artery in Patients With Atherosclerotic Plaque.

Author

Carvalho, Diego D. B., Akkus, Zeynettin, van den Oord, Stijn C. H., Schinkel, Arend F. L., van der Steen, Antonius F. W., Niessen, Wiro J., Bosch, Johan G., and Klein, Stefan

Subjects
IMAGE segmentation, ULTRASONIC imaging, CAROTID artery, ATHEROSCLEROTIC plaque, COMPARATIVE studies, PATIENTS
Abstract

In standard B-mode ultrasound (BMUS), segmentation of the lumen of atherosclerotic carotid arteries and studying the lumen geometry over time are difficult owing to irregular lumen shapes, noise, artifacts, and echolucent plaques. Contrast enhanced ultrasound (CEUS) improves lumen visualization, but lumen segmentation remains challenging owing to varying intensities, CEUS-specific artifacts and lack of tissue visualization. To overcome these challenges, we propose a novel method using simultaneously acquired BMUS&CEUS image sequences. Initially, the method estimates nonrigid motion (NME) from the image sequences, using intensity-based image registration. The motion-compensated image sequence is then averaged to obtain a single “epitome” image with improved signal-to-noise ratio. The lumen is segmented from the epitome image through an intensity joint-histogram classification and a graph-based segmentation. NME was validated by comparing displacements with manual annotations in 11 carotids. The average root mean square error (RMSE) was 112\pm 73~\mu m. Segmentation results were validated against manual delineations in the epitome images of two different datasets, respectively containing 11 (RMSE 191\pm 43~\mu m) and 10 (RMSE 351\pm 176~\mu m) carotids. From the deformation fields, we derived arterial distensibility with values comparable to the literature. The average errors in all experiments were in the inter-observer variability range. To the best of our knowledge, this is the first study exploiting combined BMUS&CEUS images for atherosclerotic carotid lumen segmentation. [ABSTRACT FROM PUBLISHER]

Published
2015
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46. Carotid Intraplaque Neovascularization Quantification Software (CINQS).

Author

Akkus, Zeynettin, van Burken, Gerard, van den Oord, Stijn C. H., Schinkel, Arend F. L., de Jong, Nico, van der Steen, Antonius F. W., and Bosch, Johan G.

Subjects
IMAGE processing, PATHOLOGIC neovascularization, DIAGNOSTIC imaging research, ALGORITHM research, BIOMARKERS, CAROTID artery diseases
Abstract

Intraplaque neovascularization (IPN) is an important biomarker of atherosclerotic plaque vulnerability. As IPN can be detected by contrast enhanced ultrasound (CEUS), imaging-biomarkers derived from CEUS may allow early prediction of plaque vulnerability. To select the best quantitative imaging-biomarkers for prediction of plaque vulnerability, a systematic analysis of IPN with existing and new analysis algorithms is necessary. Currently available commercial contrast quantification tools are not applicable for quantitative analysis of carotid IPN due to substantial motion of the carotid artery, artifacts, and intermittent perfusion of plaques. We therefore developed a specialized software package called Carotid intraplaque neovascularization quantification software (CINQS). It was designed for effective and systematic comparison of sets of quantitative imaging biomarkers. CINQS includes several analysis algorithms for carotid IPN quantification and overcomes the limitations of current contrast quantification tools and existing carotid IPN quantification approaches. CINQS has a modular design which allows integrating new analysis tools. Wizard-like analysis tools and its graphical-user-interface facilitate its usage. In this paper, we describe the concept, analysis tools, and performance of CINQS and present analysis results of 45 plaques of 23 patients. The results in 45 plaques showed excellent agreement with visual IPN scores for two quantitative imaging-biomarkers (The area under the receiver operating characteristic curve was 0.92 and 0.93). [ABSTRACT FROM PUBLISHER]

Published
2015
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47. Simultaneous segmentation of multiple heart cavities in 3D transesophageal echocardiograms.

Author

Haak, Alexander, Vegas-Sanchez-Ferrero, Gonzalo, Mulder, Harriet H., Kirisli, Hortense A., Baka, Nora, Metz, Coert, Klein, Stefan, Ren, Ben, van Burken, Gerard, Pluim, Josien P.W., van der Steen, Antonius F. W., van Walsum, Theo, and Bosch, Johannes G.

Abstract

Three-dimensional transesophageal echocardiography (3D TEE) is an excellent modality for real-time visualization of the heart and monitoring of interventions. However, 3D TEE segmentation is still a challenging task due to the complex anatomy, the limited field of view, and typical ultrasound artifacts. To improve the usability of 3D TEE for monitoring interventions, we propose to segment all cavities within the TEE view with a multi-cavity Active Shape Model (ASM) derived from Computed Tomography Angiography (CTA) in conjunction with a tissue/blood classification based on a Gamma Mixture Model (GMM). 3D TEE image data of five patients were acquired with a Philips X7-2t matrix TEE probe. Tissue probability maps were estimated by a two class (blood/tissue) GMM. A statistical shape model containing left and right ventricle, left and right atrium and aorta (LV, LA, RV, LA, Ao) was derived from CTA scans of 151 patients by Principal Component Analysis. Models from individual cavities (ASMpart: ASMLV etc.) and of the whole heart (ASMtot) were generated. First, ASMtot was aligned with the 3D TEE by indicating 3 anatomical landmarks. Second, pose and shape of ASMtot were iteratively updated by a weighted update scheme excluding parts outside of the image sector. Third, shape and pose of each ASMpart were initialized based on shape and pose of ASMtot and iteratively updated in a constrained manner to fit the tissue probability maps. All 3D TEE sets were manually outlined in multiple short and long axis views by two observers. The mean outline of both observers was compared to the ASM segmentations by calculating Dice coefficients. All patients had preoperative CTA scans which were segmented using an atlas approach. The TEE and the CTA segmentation were registered and Dice coefficients were computed. The Dice coefficients of the whole heart between the average observer and ASM segmentations were 0.91, 0.75, 0.87, 0.88, and 0.84 (interobserver variability: 0.95, 0.92, 0.92, 0.88, and 0.90) for TEE set 1 to 5 respectively. The Dice coefficient for the whole hart between CTA and TEE segmentation were 0.85, 0.80, 0.80, 0.81, and 0.71 and showed good agreement. In this work we could successfully show the accuracy and robustness of the proposed multi-cavity segmentation scheme. [ABSTRACT FROM PUBLISHER]

Published
2013
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49. Spatiotemporal interpolation by normalized convolution for 4D transesophageal echocardiography.

Author

Haak, Alexander, van Stralen, Marijn, van Burken, Gerard, Klein, Stefan, Pluim, Josien P.W., de Jong, Nico, van der Steen, Antonius F. W., and Bosch, Johannes G.

Abstract

For interventional monitoring, we aim at 4D ultrasound reconstructions of structures in the beating heart from 2D transesophageal echo images by fast scan plane rotation, unsynchronized to the heart rate. For such sparsely and irregularly sampled 2D images, a special spatiotemporal interpolation approach is desired. We have previously shown the potential of spatiotemporal interpolation by normalized convolution (NC). In this work we optimized NC for our application and compared it to nearest neighbor interpolation (NN) and to temporal binning followed by linear spatial interpolation (LTB). The test datasets consisted of 600, 1350, and 1800 2D images and were derived by slicing a 4D echocardiography data sets at random rotation angle (θ, range: 0–180°) and random normalized cardiac phase (τ, range: 0–1). A Gaussian kernel was used for NC and optimal kernel sizes (στ and σθ) were found by performing an exhaustive search. The RMS gray value error (RMSE) of the reconstructed images was computed for all interpolation methods. The estimated optimal kernels were σθ=3.24°/ στ=0.048, σθ=2.34°/στ=0.026, and σθ=1.89°/στ=0.023 for 600, 1350, and 1800 input images, respectively. The minimum RMSE for NC was 13.8, 10.4, and 9.4 for 600, 1350, and 1800 input images, respectively. The NN/LTB reconstruction had an RMSE of 17.8/16.4, 13.9/15.1, and 12.0/14.7 for 600, 1350, and 1800 2D input images, respectively. We showed that NC outperforms NN and LTB. For a small number of input images the advantage of NC is more pronounced. [ABSTRACT FROM PUBLISHER]

Published
2011
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