Your search keyword '"Lopata, Richard G. P."' showing total 26 results

1. Strain-based discoordination imaging during exercise in heart failure with reduced ejection fraction: Feasibility and reproducibility

Author

Fixsen, Louis S., Wouters, Philippe C., Lopata, Richard G. P., and Kemps, Hareld M. C.

Published

2022

2. A novel technique for the assessment of mechanical properties of vascular tissue

Author

Sanders, Stefan N., Lopata, Richard G. P., van Breemen, Lambert C. A., van de Vosse, Frans N., and Rutten, Marcel C. M.

Published

2020

3. Image acquisition stability of fixated musculoskeletal sonography in an exercise setting: a quantitative analysis and comparison with freehand acquisition

Author

Heres, H. Maarten, Sjoerdsma, Marloes, Schoots, Thijs, Rutten, Marcel C. M., van de Vosse, Frans N., and Lopata, Richard G. P.

Published

2020

4. In vivo bistatic dual-aperture ultrasound imaging and elastography of the abdominal aorta.

Author

van Hal, Vera H. J., de Hoop, Hein, van Sambeek, Marc R. H. M., Schwab, Hans-Martin, and Lopata, Richard G. P.

Abstract

Introduction: In this paper we introduce in vivo multi-aperture ultrasound imaging and elastography of the abdominal aorta. Monitoring of the geometry and growth of abdominal aortic aneurysms (AAA) is paramount for risk stratification and intervention planning. However, such an assessment is limited by the lateral lumen-wall contrast and resolution of conventional ultrasound. Here, an in vivo dual-aperture bistatic imaging approach is shown to improve abdominal ultrasound and strain imaging quality significantly. By scanning the aorta from different directions, a larger part of the vessel circumference can be visualized. Methods: In this first-in-man volunteer study, the performance of multiaperture ultrasound imaging and elastography of the abdominal aortic wall was assessed in 20 healthy volunteers. Dual-probe acquisition was performed in which two curved array transducers were aligned in the same imaging plane. The transducers alternately transmit and both probes receive simultaneously on each transmit event, which allows for the reconstruction of four ultrasound signals. Automatic probe localization was achieved by optimizing the coherence of the trans-probe data, using a gradient descent algorithm. Speckle-tracking was performed on the four individual bistatic signals, after which the respective axial displacements were compounded and strains were calculated. Results: Using bistatic multi-aperture ultrasound imaging, the image quality of the ultrasound images, i.e., the angular coverage of the wall, was improved which enables accurate estimation of local motion dynamics and strain in the abdominal aortic wall. The motion tracking error was reduced from 1.3 mm ± 0.63 mm to 0.16 mm ± 0.076 mm, which increased the circumferential elastographic signal-to-noise ratio (SNRe) by 12.3 dB ± 8.3 dB on average, revealing more accurate and homogeneous strain estimates compared to single-perspective ultrasound. Conclusion: Multi-aperture ultrasound imaging and elastography is feasible in vivo and can provide the clinician with vital information about the anatomical and mechanical state of AAAs in the future. [ABSTRACT FROM AUTHOR]

Published

2024

5. Contactless Cardiovascular Assessment by Imaging Photoplethysmography: A Comparison with Wearable Monitoring.

Author

van Es, Valerie A. A., Lopata, Richard G. P., Scilingo, Enzo Pasquale, and Nardelli, Mimma

Subjects

*PHOTOPLETHYSMOGRAPHY, *AUTONOMIC nervous system, *STANDARD deviations, *VAGAL tone, *POINCARE maps (Mathematics)

Abstract

Despite the notable recent developments in the field of remote photoplethysmography (rPPG), extracting a reliable pulse rate variability (PRV) signal still remains a challenge. In this study, eight image-based photoplethysmography (iPPG) extraction methods (GRD, AGRD, PCA, ICA, LE, SPE, CHROM, and POS) were compared in terms of pulse rate (PR) and PRV features. The algorithms were made robust for motion and illumination artifacts by using ad hoc pre- and postprocessing steps. Then, they were systematically tested on the public dataset UBFC-RPPG, containing data from 42 subjects sitting in front of a webcam (30 fps) while playing a time-sensitive mathematical game. The performances of the algorithms were evaluated by statistically comparing iPPG-based and finger-PPG-based PR and PRV features in terms of Spearman's correlation coefficient, normalized root mean square error (NRMSE), and Bland–Altman analysis. The study revealed POS and CHROM techniques to be the most robust for PR estimation and the assessment of overall autonomic nervous system (ANS) dynamics by using PRV features in time and frequency domains. Furthermore, we demonstrated that a reliable characterization of the vagal tone is made possible by computing the Poincaré map of PRV series derived from the POS and CHROM methods. This study supports the use of iPPG systems as promising tools to obtain clinically useful and specific information about ANS dynamics. [ABSTRACT FROM AUTHOR]

Published

2023

6. LVNet: Lightweight Model for Left Ventricle Segmentation for Short Axis Views in Echocardiographic Imaging.

Author

Awasthi, Navchetan, Vermeer, Lars, Fixsen, Louis S., Lopata, Richard G. P., and Pluim, Josien P. W.

Subjects

COMPUTER-assisted image analysis (Medicine), DIAGNOSTIC imaging, PAPILLARY muscles, ULTRASONIC imaging, IMAGE segmentation, ECHOCARDIOGRAPHY, MEDICAL equipment, MEDICAL care costs

Abstract

Lightweight segmentation models are becoming more popular for fast diagnosis on small and low cost medical imaging devices. This study focuses on the segmentation of the left ventricle (LV) in cardiac ultrasound (US) images. A new lightweight model [LV network (LVNet)] is proposed for segmentation, which gives the benefits of requiring fewer parameters but with improved segmentation performance in terms of Dice score (DS). The proposed model is compared with state-of-the-art methods, such as UNet, MiniNetV2, and fully convolutional dense dilated network (FCdDN). The model proposed comes with a post-processing pipeline that further enhances the segmentation results. In general, the training is done directly using the segmentation mask as the output and the US image as the input of the model. A new strategy for segmentation is also introduced in addition to the direct training method used. Compared with the UNet model, an improvement in DS performance as high as 5% for segmentation with papillary (WP) muscles was found, while showcasing an improvement of 18.5% when the papillary muscles are excluded. The model proposed requires only 5% of the memory required by a UNet model. LVNet achieves a better trade-off between the number of parameters and its segmentation performance as compared with other conventional models. The developed codes are available at https://github.com/navchetanawasthi/Left_Ventricle_Segmentation. [ABSTRACT FROM AUTHOR]

Published

2022

7. Multiperspective Bistatic Ultrasound Imaging and Elastography of the Ex Vivo Abdominal Aorta.

Author

van Hal, Vera H. J., De Hoop, Hein, Muller, Jan-Willem, van Sambeek, Marc R. H. M., Schwab, Hans-Martin, and Lopata, Richard G. P.

Subjects

ABDOMINAL aorta, ULTRASONIC imaging, AORTIC rupture, ELASTOGRAPHY, MIMO radar, BISTATIC radar

Abstract

Knowledge of aneurysm geometry and local mechanical wall parameters using ultrasound (US) can contribute to a better prediction of rupture risk in abdominal aortic aneurysms (AAAs). However, aortic strain imaging using conventional US is limited by the lateral lumen–wall contrast and resolution. In this study, ultrafast multiperspective bistatic (MP BS) imaging is used to improve aortic US, in which two curved array transducers receive simultaneously on each transmit event. The advantage of such bistatic US imaging on both image quality and strain estimations was investigated by comparing it to single-perspective monostatic (SP MS) and MP monostatic (MP MS) imaging, i.e., alternately transmitting and receiving with either transducer. Experimental strain imaging was performed in US simulations and in an experimental study on porcine aortas. Different compounding strategies were tested to retrieve the most useful information from each received US signal. Finally, apart from the conventional sector grid in curved array US imaging, a polar grid with respect to the vessel’s local coordinate system is introduced. This new reconstruction method demonstrated improved displacement estimations in aortic US. The US simulations showed increased strain estimation accuracy using MP BS imaging bistatic imaging compared to MP MS imaging, with a decrease in the average relative error between 41% and 84% in vessel wall regions between transducers. In the experimental results, the mean image contrast-to-noise ratio was improved by up to 8 dB in the vessel wall regions between transducers. This resulted in an increased mean elastographic signal-to-noise ratio by about 15 dB in radial strain and 6 dB in circumferential strain. [ABSTRACT FROM AUTHOR]

Published

2022

8. A Generalized Approach for Automatic 3-D Geometry Assessment of Blood Vessels in Transverse Ultrasound Images Using Convolutional Neural Networks.

Author

de Ruijter, Joerik, Muijsers, Judith J. M., van de Vosse, Frans N., van Sambeek, Marc R. H. M., and Lopata, Richard G. P.

Subjects

CONVOLUTIONAL neural networks, BLOOD vessels, ULTRASONIC imaging, CROSS-sectional imaging, RETINAL blood vessels, CAROTID artery

Abstract

Accurate 3-D geometries of arteries and veins are important clinical data for diagnosis of arterial disease and intervention planning. Automatic segmentation of vessels in the transverse view suffers from the low lateral resolution and contrast. Convolutional neural networks are a promising tool for automatic segmentation of medical images, outperforming the traditional segmentation methods with high robustness. In this study, we aim to create a general, robust, and accurate method to segment the lumen–wall boundary of healthy central and peripheral vessels in large field-of-view freehand ultrasound (US) datasets. Data were acquired using the freehand US, in combination with a probe tracker. A total of ±36 000 cross-sectional images, acquired in the common, internal, and external carotid artery (${N} = 37$), in the radial, ulnar artery, and cephalic vein (${N} = 12$), and in the femoral artery (${N} = 5$) were included. To create masks (of the lumen) for training data, a conventional automatic segmentation method was used. The neural networks were trained on: 1) data of all vessels and 2) the carotid artery only. The performance was compared and tested using an open-access dataset. The recall, precision, DICE, and intersection over union (IoU) were calculated. Overall, segmentation was successful in the carotid and peripheral arteries. The Multires U-net architecture performs best overall with DICE = 0.93 when trained on the total dataset. Future studies will focus on the inclusion of vascular pathologies. [ABSTRACT FROM AUTHOR]

Published

2021

9. Ultrasound-Based Fluid-Structure Interaction Modeling of Abdominal Aortic Aneurysms Incorporating Pre-stress.

Author

Fonken, Judith H. C., Maas, Esther J., Nievergeld, Arjet H. M., van Sambeek, Marc R. H. M., van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

FLUID-structure interaction, ABDOMINAL aortic aneurysms, AORTIC rupture, SHEARING force, BLOOD pressure

Abstract

Currently, the prediction of rupture risk in abdominal aortic aneurysms (AAAs) solely relies on maximum diameter. However, wall mechanics and hemodynamics have shown to provide better risk indicators. Patient-specific fluid-structure interaction (FSI) simulations based on a non-invasive image modality are required to establish a patient-specific risk indicator. In this study, a robust framework to execute FSI simulations based on time-resolved three-dimensional ultrasound (3D+t US) data was obtained and employed on a data set of 30 AAA patients. Furthermore, the effect of including a pre-stress estimation (PSE) to obtain the stresses present in the measured geometry was evaluated. The established workflow uses the patient-specific 3D+t US-based segmentation and brachial blood pressure as input to generate meshes and boundary conditions for the FSI simulations. The 3D+t US-based FSI framework was successfully employed on an extensive set of AAA patient data. Omitting the pre-stress results in increased displacements, decreased wall stresses, and deviating time-averaged wall shear stress and oscillatory shear index patterns. These results underline the importance of incorporating pre-stress in FSI simulations. After validation, the presented framework provides an important tool for personalized modeling and longitudinal studies on AAA growth and rupture risk. [ABSTRACT FROM AUTHOR]

Published

2021

10. Spectroscopic photoacoustic imaging of cartilage damage.

Author

Wu, M., van Teeffelen, B.C.J., Ito, K., van de Vosse, F.N., Janssen, R.P.A., van Donkelaar, C.C., Lopata, R.G.P., Wu, Min, van Teeffelen, Bente C J, Ito, Keita, van de Vosse, Frans N, Janssen, Rob P A, van Donkelaar, Corrinus C, and Lopata, Richard G P

Abstract

Objective: Osteoarthritis (OA) is a chronic joint disease characterized by progressive degradation of cartilage. It affects more than 10% of the people aged over 60 years-old worldwide with a rising prevalence due to the increasingly aging population. OA is a major source of pain, disability, and socioeconomic cost. Currently, the lack of effective diagnosis and affordable imaging options for early detection and monitoring of OA presents the clinic with many challenges. Spectroscopic Photoacoustic (sPA) imaging has the potential to reveal changes in cartilage composition with different degrees of damage, based on optical absorption contrast.Design: In this study, the capabilities of sPA imaging and its potential to characterize cartilage damage were explored. To this end, 15 pieces of cartilage samples from patients undergoing a total joint replacement were collected and were imaged ex vivo with sPA imaging at a wide optical spectral range (between 500 nm and 1,300 nm) to investigate the photoacoustic properties of cartilage tissue. All the PA spectra of the cartilage samples were analyzed and compared to the corresponding histological results.Results: The collagen related PA spectral changes were clearly visible in our imaging data and were related to different degrees of cartilage damage. The results are in good agreement with histology and the current gold standard, i.e., the Mankin score.Conclusions: This study demonstrates the potential and possible clinical application of sPA imaging in OA. [ABSTRACT FROM AUTHOR]

Published

2021

11. A Spatial Near-Field Clutter Reduction Filter Preserving Tissue Speckle in Echocardiography.

Author

Sjoerdsma, Marloes, Bouwmeester, Sjoerd, Houthuizen, Patrick, van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

SPECKLE interference, ULTRASONIC imaging, ECHOCARDIOGRAPHY, CROSS correlation, IMAGE intensifiers, DOPPLER echocardiography, MYOCARDIUM, SIGNAL-to-noise ratio

Abstract

Near-field (NF) clutter in echocardiography is depicted as a diffuse haze hindering the visualization of the myocardium and the blood-pool, thereby degrading its diagnostic value. Several clutter filters have been developed, which are limited in patients with contraction motion and rhythm anomalies, and in 3-D ultrasound (US). This study introduces a new NF clutter reduction method, which preserves US speckles required for strain imaging. The filter developed detects the NF clutter region in the spatial frequency domain. The filter employs an oriented, multiscale approach, and assumes the NF clutter to be predominantly present in the highest and lowest bandpass images. These bandpass images were filtered, whilst sparing features in the myocardium and NF clutter-free regions. The performance of the filter was assessed in a volunteer study, in ten 3-D apical and parasternal view acquisitions, and in a retrospective clinical study composed of 20 cardiac patients with different indications for echocardiography. The filter reduced NF clutter in all data sets, whilst preserving all or most of the myocardium. Additionally, it demonstrated a consistent enhancement of image quality, with an increase in contrast of 4.3 dB on average, and generated a clearer myocardial boundary distinction. Furthermore, the speckles were preserved according to the quality index based on local variance, the structural similarity index method, and normalized cross correlation values, being 0.82, 0.92, and 0.95 on average, respectively. Global longitudinal strain measurements on NF clutter reduced images were improved or equivalent compared to the original acquisitions, with an average increase in strain signal-to-noise ratio of 34%. [ABSTRACT FROM AUTHOR]

Published

2021

12. Multiperspective Ultrasound Strain Imaging of the Abdominal Aorta.

Author

de Hoop, Hein, Petterson, Niels J., van de Vosse, Frans N., van Sambeek, Marc R. H. M., Schwab, Hans-Martin, and Lopata, Richard G. P.

Subjects

ULTRASONIC imaging, ABDOMINAL aortic aneurysms, HEART beat, AORTA, IMAGE registration, ABDOMINAL aorta, SIGNAL-to-noise ratio

Abstract

Current decision-making for clinical intervention of abdominal aortic aneurysms (AAAs) is based on the maximum diameter of the aortic wall, but this does not provide patient-specific information on rupture risk. Ultrasound (US) imaging can assess both geometry and deformation of the aortic wall. However, low lateral contrast and resolution are currently limiting the precision of both geometry and local strain estimates. To tackle these drawbacks, a multiperspective scanning mode was developed on a dual transducer US system to perform strain imaging at high frame rates. Experimental imaging was performed on porcine aortas embedded in a phantom of the abdomen, pressurized in a mock circulation loop. US images were acquired with three acquisition schemes: Multiperspective ultrafast imaging, single perspective ultrafast imaging, and conventional line-by-line scanning. Image registration was performed by automatic detection of the transducer surfaces. Multiperspective images and axial displacements were compounded for improved segmentation and tracking of the aortic wall, respectively. Performance was compared in terms of image quality, motion tracking, and strain estimation. Multiperspective compound displacement estimation reduced the mean motion tracking error over one cardiac cycle by a factor 10 compared to conventional scanning. Resolution increased in radial and circumferential strain images, and circumferential signal-to-noise ratio (SNRe) increased by 10 dB. Radial SNRe is high in wall regions moving towards the transducer. In other regions, radial strain estimates remain cumbersome for the frequency used. In conclusion, multiperspective US imaging was demonstrated to improve motion tracking and circumferential strain estimation of porcine aortas in an experimental set-up. [ABSTRACT FROM AUTHOR]

Published

2020

13. Ultrasound‐based estimation of remaining cardiac function in LVAD‐supported ex vivo hearts.

Author

Fixsen, Louis S., Petterson, Niels J., Houthuizen, Patrick, Rutten, Marcel C. M., van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

HEART beat, HEART assist devices, ECHOCARDIOGRAPHY, HEMODYNAMICS, HEART, HEART failure patients

Abstract

Left ventricular assist devices (LVAD) provide cardiac support to patients with advanced heart failure. Methods that can directly measure remaining LV function following device implantation do not currently exist. Previous studies have shown that a combination of loading (LV pressure) and deformation (strain) measurements enables quantitation of myocardial work. We investigated the use of ultrasound (US) strain imaging and pressure–strain loop analysis in LVAD‐supported hearts under different hemodynamic and pump unloading conditions, with the aim of determining LV function with and without LVAD support. Ex vivo porcine hearts (n = 4) were implanted with LVADs and attached to a mock circulatory loop. Measurements were performed at hemodynamically defined "heart conditions" as the hearts deteriorated from baseline. Hemodynamic (including LV pressure) and radio‐frequency US data were acquired during a pump‐ramp protocol at speeds from 0 (with no pump outflow) to 10 000 revolutions per minute (rpm). Regional circumferential (εcirc) and radial (εrad) strains were estimated over each heart cycle. Regional ventricular dyssynchrony was quantitated through time‐to‐peak strain. Mean change in LV pulse pressure and εcirc between 0 and 10 krpm were −21.8 mm Hg and −7.24% in the first condition; in the final condition −46.8 mm Hg and −19.2%, respectively. εrad was not indicative of changes in pump speed or heart condition. Pressure–strain loops showed a degradation in the LV function and an increased influence of LV unloading: loop area reduced by 90% between 0 krpm in the first heart condition and 10 krpm in the last condition. High pump speeds and degraded condition led to increased dyssynchrony between the septal and lateral LV walls. Functional measurement of the LV while undergoing LVAD support is possible by using US strain imaging and pressure–strain loops. This can provide important information about remaining pump function. Use of novel LV pressure estimation or measurement techniques would be required for any future use in LVAD patients. [ABSTRACT FROM AUTHOR]

Published

2020

14. Quantification of aortic stiffness and wall stress in healthy volunteers and abdominal aortic aneurysm patients using time-resolved 3D ultrasound: a comparison study.

Author

Disseldorp, Emiel M J van, Petterson, Niels J, Vosse, Frans N van de, Sambeek, Marc R H M van, and Lopata, Richard G P

Subjects

ABDOMINAL aortic aneurysms, AGE distribution, AGING, ARTERIES, BLOOD pressure, COMPARATIVE studies, ECHOCARDIOGRAPHY, FINITE element method

Abstract

Aims Using non-invasive 3D ultrasound, peak wall stress (PWS) and aortic stiffness can be evaluated, which may provide additional criteria in abdominal aortic aneurysm (AAA) risk assessment. In this study, these measures were determined in both young and age-matched individuals, and AAA patients while its relation to age, maximum diameter, and growth was assessed statistically. Methods and results Time-resolved 3D-US data were acquired for 30 volunteers and 65 AAA patients. The aortic geometry was segmented, and tracked over the cardiac cycle using 3D speckle tracking to characterize the wall motion. Wall stress analysis was performed using finite element analysis. Model parameters were optimized until the model output matched the measured 3D displacements. A significant increase in aortic stiffness was measured between the age-matched volunteers [median 0.58, interquartile range (IQR) 0.48–0.71 kPa⋅m] and the small AAA patients (median 1.84, IQR 1.38–2.46 kPa⋅m; P < 0.001). In addition, an increase in aortic stiffness was evaluated between the small (30–39 mm) and large (≥50 mm) AAAs (median 2.72, IQR 1.99–3.14 kPa⋅m; P  = 0.01). The 99th percentile wall stress showed a positive correlation with diameter (ρ  = 0.73, P < 0.001), and significant differences between age-matched volunteers and AAA patients. Conclusion The AAA pathology causes an early and significant increase in aortic stiffness of the abdominal aorta, even after correcting for the expected effect of ageing and differences in arterial pressure. Moreover, some AAAs revealed relatively high PWS, although the maximum diameter was below the threshold for surgical repair. Using the current method, these measures become available during follow-up, which could improve AAA rupture risk assessment. [ABSTRACT FROM AUTHOR]

Published

2019

15. Investigation on the Effect of Spatial Compounding on Photoacoustic Images of Carotid Plaques in the In Vivo Available Rotational Range.

Author

Arabul, M. Umit, Heres, H. Maarten, Rutten, Marcel C. M., van Sambeek, Marc R. H. M., van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

CAROTID artery diseases, ACOUSTIC imaging, SIGNAL-to-noise ratio, POLYVINYL alcohol, IMAGING phantoms, DIAGNOSIS

Abstract

Photoacoustic imaging (PAI) is a promising imaging modality due to its high optical specificity. However, the low signal-to-noise ratio (SNR) and contrast-to-noise ratio (CNR) of in vivo PA images are major challenges that prevent PAI from finding its place in clinics. This paper investigates the merit of spatial compounding of PA images in arterial phantoms and the achievable improvements of SNR, when in vivo conditions are mimicked. The analysis of the compounding technique was performed on a polyvinyl alcohol vessel phantom with black threads embedded in its wall. The in vivo conditions were mimicked by limiting the rotation range in ±30°, adding turbid surrounding medium, and filling the lumen with porcine blood. Finally, the performance of the technique was evaluated in ex vivo human carotid plaque samples. Results showed that spatial compounding elevates the SNR by 5–10 dB and CNR by 1–5 dB, depending on the location of the absorbers. This paper elucidates prospective in vivo PA characterization of carotid plaques by proposing a method to enhance PA image quality. [ABSTRACT FROM PUBLISHER]

Published

2018

16. Visualization of vasculature using a hand-held photoacoustic probe: phantom and in vivo validation.

Author

Heres, H. Maarten, Arabul, Mustafa Umit, Rutten, Marcel C. M., Van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

BLOOD-vessel abnormalities, VASCULAR disease diagnosis, ACOUSTIC imaging, PHOTOACOUSTIC spectroscopy, MEDICAL radiography, PHOTOACOUSTIC spectra, DIAGNOSIS

Abstract

Assessment of microvasculature and tissue perfusion can provide diagnostic information on local or systemic diseases. Photoacoustic (PA) imaging has strong clinical potential because of its sensitivity to hemoglobin. We used a hand-held PA probe with integrated diode lasers and examined its feasibility and validity in the detection of increasing blood volume and (sub) dermal vascularization. Blood volume detection was tested in custom-made perfusion phantoms. Results showed that an increase of blood volume in a physiological range of 1.3% to 5.4% could be detected. The results were validated with power Doppler sonography. Using a motorized scanning setup, areas of the skin were imaged at relatively short scanning times (<10 s/cm2) with PA. Threedimensional visualization of these structures was achieved by combining the consecutively acquired crosssectional images. Images revealed the epidermis and submillimeter vasculature up to depth of 5 mm. The geometries of imaged vasculature were validated with segmentation of the vasculature in high-frequency ultrasound imaging. This study proves the feasibility of PA imaging in its current implementation for the detection of perfusion-related parameters in skin and subdermal tissue and underlines its potential as a diagnostic tool in vascular or dermal pathologies. [ABSTRACT FROM AUTHOR]

Published

2017

17. Toward the detection of intraplaque hemorrhage in carotid artery lesions using photoacoustic imaging.

Author

Arabul, Mustafa Umit, Heres, Maarten, Rutten, Marcel C. M., van Sambeek, Marc R., van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

CAROTID artery disease diagnosis, HEMORRHAGE diagnosis, ACOUSTIC imaging, PHOTOACOUSTIC spectroscopy, MEDICAL radiography, PHOTOACOUSTIC spectra

Abstract

Photoacoustic imaging (PAI) may have the ability to reveal the composition and the anatomical structure of carotid plaques, which determines its mechanical properties and vulnerability. We used PAI and plane wave ultrasound (PUS) imaging to obtain three-dimensional (3-D) images of endarterectomy samples ex vivo and compared the results with histology to investigate the potential of PAI-based identification of intraplaque hemorrhage. Seven carotid plaque samples were obtained from patients undergoing carotid endarterectomy and imaged with a fully integrated hand-held photoacoustic (PA) probe, consisting of a pulsed diode laser (t PULSE = 130 ns, EPULSE = 1 mJ, λ = 808 nm) and a linear array transducer (f c = 7.5 MHz). The samples were rotated 360 deg with 10 deg steps, and data were spatially compounded to obtain complete 3-D images of the plaques. Areas of high absorption in the 3-D datasets were identified and compared to histological data of the plaques. Data in six out of seven endarterectomy samples revealed the presence of intraplaque hemorrhages that were not visible in the PUS images. Due to the noninvasive nature of PAI, this ex vivo study may elucidate preclinical studies toward the in vivo, noninvasive, vulnerability assessment of the atherosclerotic carotid plaque. [ABSTRACT FROM AUTHOR]

Published

2017

18. Application of an Adaptive Polynomial Chaos Expansion on Computationally Expensive Three-Dimensional Cardiovascular Models for Uncertainty Quantification and Sensitivity Analysis.

Author

Quicken, Sjeng, Donders, Wouter P., van Disseldorp, Emiel M. J., Gashi, Kujtim, Mees, Barend M. E., van de Vosse, Frans N., Lopata, Richard G. P., Delhaas, Tammo, and Huberts, Wouter

Published

2016

19. Modeling toolchain for realistic simulation of photoacoustic data acquisition.

Author

Muller, Jan-Willem, Arabul, Mustafa Ü., Schwab, Hans-Martin, Rutten, Marcel C. M., van Sambeek, Marc R. H. M., Wu, Min, and Lopata, Richard G. P.

Subjects

ACQUISITION of data, SPECKLE interferometry, ATHEROSCLEROTIC plaque, SAMPLING (Process), SIGNAL-to-noise ratio, ACOUSTIC wave propagation

Abstract

Significance: Physics-based simulations of photoacoustic (PA) signals are used to validate new methods, to characterize PA setups and to generate training datasets for machine learning. However, a thoroughly validated PA simulation toolchain that can simulate realistic images is still lacking. Aim: A quantitative toolchain was developed to model PA image acquisition in complex tissues, by simulating both the optical fluence and the acoustic wave propagation. Approach: Sampling techniques were developed to decrease artifacts in acoustic simulations. The performance of the simulations was analyzed by measuring the point spread function (PSF) and using a rotatable three-channel phantom, filled with cholesterol, a human carotid plaque sample, and porcine blood. Ex vivo human plaque samples were simulated to validate the methods in more complex tissues. Results: The sampling techniques could enhance the quality of the simulated PA images effectively. The resolution and intensity of the PSF in the turbid medium matched the experimental data well. Overall, the appearance, signal-to-noise ratio and speckle of the images could be simulated accurately. Conclusions: A PA toolchain was developed and validated, and the results indicate a great potential of PA simulations in more complex and heterogeneous media. [ABSTRACT FROM AUTHOR]

Published

2022

20. Predicting Target Displacements Using Ultrasound Elastography and Finite Element Modeling.

Author

den Buijs, Jorn op, Hansen, Hendrik H. G., Lopata, Richard G. P., de Korte, Chris L., and Misra, Sarthak

Subjects

SOFT tissue injuries, FINITE element method, RADIO frequency, OPERATIVE surgery, ENDOSCOPIC surgery complications, SURGICAL instruments, ULTRASONIC imaging, BIOMEDICAL transducers

Abstract

Soft tissue displacements during minimally invasive surgical procedures may cause target motion and subsequent misplacement of the surgical tool. A technique is presented to predict target displacements using a combination of ultrasound elastography and finite element (FE) modeling. A cubic gelatin/agar phantom with stiff targets was manufactured to obtain pre- and post-loading ultrasound radio frequency (RF) data from a linear array transducer. The RF data were used to compute displacement and strain images, from which the distribution of elasticity was reconstructed using an inverse FE-based approach. The FE model was subsequently used to predict target displacements upon application of different boundary and loading conditions to the phantom. The influence of geometry was investigated by application of the technique to a breast-shaped phantom. The distribution of elasticity in the phantoms as determined from the strain distribution agreed well with results from mechanical testing. Upon application of different boundary and loading conditions to the cubic phantom, the FE model-predicted target motion were consistent with ultrasound measurements. The FE-based approach could also accurately predict the displacement of the target upon compression and indentation of the breast-shaped phantom. This study provides experimental evidence that organ geometry and boundary conditions surrounding the organ are important factors influencing target motion. In future work, the technique presented in this paper could be used for preoperative planning of minimally invasive surgical interventions. [ABSTRACT FROM PUBLISHER]

Published

2011

21. Dynamic imaging of skeletal muscle contraction in three orthogonal directions.

Author

Lopata, Richard G. P., Dijk, Johannes P. van, Pillen, Sigrid, Nillesen, Maartje M., Maas, Huub, Thijssen, Johan M., Stegeman, Dick F., and De Korte, Chris L.

Subjects

BICEPS femoris, NEURAL stimulation, MEDICAL imaging systems, NERVES, MUSCLE contraction

Abstract

In this study, a multidimensional strain estimation method using biplane ultrasound is presented to assess local relative deformation (i.e., local strain) in three orthogonal directions in skeletal muscles during induced and voluntary contractions. The method was tested in the musculus biceps brachii of five healthy subjects for three different types of muscle contraction: 1) excitation of the muscle with a single electrical pulse via the musculocutaneous nerve, resulting in a so-called "twitch" contraction; 2) a train of five pulses at 10 Hz and 20 Hz, respectively, to obtain a submaximum tetanic contraction; and 3) voluntary contractions at 30, 60, and 100% of maximum contraction force. Results show that biplane ultrasound strain imaging is feasible. The method yielded adequate performance using the radio frequency data in tracking the tissue motion and enabled the measurement of local deformation in both the vertical direction (orthogonal to the arm) and in the horizontal directions (parallel and perpendicular to direction of the arm) in two orthogonal cross sections of the muscle. The twitch experiments appeared to be reproducible in all three directions, and high strains in vertical (25 to 30%) and horizontal (-20% to - 10%) directions were measured. Visual inspection of both the ultrasound data, as well as the strain data, revealed a relaxation that was significantly slower than the force decay. The pulse train experiments nicely illustrated the performance of our technique: I) similar patterns of force and strain waveforms were found; and 2) each stimulation frequency yielded a different strain pattern, e.g., peak vertical strain was 40% during 10-Hz stimulation and 60% during 20-Hz stimulation. The voluntar contraction patterns were found to be both practically feasible and reproducible, which will enable muscles and more natural contraction patterns to be examined without the need of electrical stimulation. [ABSTRACT FROM AUTHOR]

Published

2010

22. Methodical Study on the Estimation of Strain in Shearing and Rotating Structures Using Radio Frequency Ultrasound Based on 1-D and 2-D Strain Estimation Techniques.

Author

Lopata, Richard G. P., Hansen, Hendrik H. G., Nillesen, Maartje M., Thijssen, Johan M., Kapusta, Livia, and De Korte, Chris L.

Subjects

*SHEAR (Mechanics), *RADIO frequency, *ULTRASONICS, *SIMULATION methods & models, *ALGORITHMS, *ESTIMATION theory

Abstract

This simulation study is concerned with: 1) the feasibility of measuring rotation and 2) the assessment of the performance of strain estimation in shearing and rotating structures. The performance of 3 different radio frequency (RF) based methods is investigated. Linear array ultrasound data of a deforming block were simulated (axial shear strain = 2.0, 4.0, and 6.0%, vertical strain = 0.0, 1.0, and 2.0%). Furthermore, data of a rotating block were simulated over an angular range of 0.5° to 10°. Local displacements were estimated using a coarse-to-fine algorithm using 1-D and 2-D precompression kernels. A new estimation method was developed in which axial displacements were used to correct the search area for local axial motion. The study revealed that this so-called free-shape 2-D method outperformed the other 2 methods and produced more accurate displacement images. For higher axial shear strains, the variance of the axial strain and the axial shear strain reduced by a factor of 4 to 5. Rotations could be accurately measured up to 4.0 to 5.0°. Again, the free-shape 2-D method yielded the most accurate results. After reconstruction of the rotation angle, the mean angles were slightly underestimated. The precision of the strain estimates decreased with increasing rotation angles. In conclusion, the proposed free-shape 2-D method enhances the measurement of (axial shear) strains and rotation. Experimental validation of the new method still has to be performed. [ABSTRACT FROM AUTHOR]

Published

2010

23. Quantitative Assessment of Oral Orbicular Muscle Deformation After Cleft Lip Reconstruction: An Ultrasound Elastography Study.

Author

de Korte, Chris L., van Hees, Nancy, Lopata, Richard G. P., Weijers, Gert, Katsaros, Christos, and Thijssen, Johan M.

Subjects

CLEFT lip, LIP abnormalities, SCARS, REOPERATION, DISABILITIES

Abstract

Reconstruction of a cleft lip leads inevitably to scar tissue formation. Scar tissue within the restored oral orbicular muscle might be assessed by quantification of the local contractility of this muscle. Furthermore, information about the contraction capability of the oral orbicular muscle is crucial for planning the revision surgery of an individual patient. We used ultrasound elastography to determine the local deformation (strain) of the upper lip and to differentiate contracting muscle from passive scar tissue. Raw ultrasound data (radio-frequency format; rf-) were acquired, while the lips were brought from normal state into a pout condition and back in normal state, in three patients and three normal individuals. During this movement, the oral orbicular muscle contracts and, consequently, thickens in contrast to scar tissue that will not contract, or even expand. An iterative coarse-to-fine strain estimation method was used to calculate the local tissue strain. Analysis of the raw ultrasound data allows estimation of tissue strain with a high precision. The minimum strain that can be assessed reproducibly is 0.1%. In normal individuals, strain of the orbicular oral muscle was in the order of 20%. Also, a uniform strain distribution in the oral orbicular muscle was found. However, in patients deviating values were found in the region of the reconstruction and the muscle tissue surrounding that. In two patients with a successful reconstruction, strain was reduced by 6% in the reconstructed region with respect to the normal parts of the muscle (from 22% to 16% and from 25% to 19%). In a patient with severe esthetical and functional disability, strain decreased from 30% in the normal region to 5% in the reconstructed region. With ultrasound elastography, the strain of the oral orbicular muscle can be quantified. In healthy subjects, the strain profiles and maximum strain values in all parts of the muscle were similar. The maximum strain of the muscle during pout was 20% ± 1%. In surgically repaired cleft lips, decreased deformation was observed. [ABSTRACT FROM AUTHOR]

Published

2009

24. Noninvasive Carotid Strain Imaging Using Angular Compounding at Large Beam Steered Angles: Validation in Vessel Phantoms.

Author

Hansen, Hendrik H. G., Lopata, Richard G. P., and de Korte, Chris L.

Subjects

*ULTRASONIC imaging, *CEREBROVASCULAR disease, *MYOCARDIAL infarction, *ATHEROSCLEROTIC plaque, *DIAGNOSTIC imaging, *MEDICAL imaging systems, *MEDICAL photography

Abstract

Stroke and myocardial infarction are initiated by rupturing vulnerable atherosclerotic plaques. With noninvasive ultrasound elastography, these plaques might be detected in carotid arteries. However, since the ultrasound beam is generally not aligned with the radial direction in which the artery pulsates, radial and circumferential strains need to be derived from axial and lateral data. Conventional techniques to perform this conversion have the disadvantage that lateral strain is required. Since the lateral strain has relatively poor accuracy, the quality of the radial and circumferential strains is reduced. In this study, the radial and circumferential strain estimates are improved by combining axial strain data acquired at multiple insonification angles. Adaptive techniques to correct for grating lobe interference and other artifacts that occur when performing beam steering at large angles are introduced. Acquisitions at multiple angles are performed with a beam steered linear array. For each beam steered angle, there are two spatially restricted regions of the circular vessel cross section where the axial strain is closely aligned with the radial strain and two spatially restricted regions (different from the radial strain regions) where the axial strain is closely aligned with the circumferential strain. These segments with high quality strain estimates are compounded to form radial or circumferential strain images. Compound radial and circumferential strain images were constructed for a homogeneous vessel phantom with a concentric lumen subjected to different intraluminal pressures. Comparison of the elastographic signal-to-noise ratio (SNRe) and contrast-to-noise ratio (CNRe) revealed that compounding increases the image quality considerably compared to images from 0° information only. SNRe and CNRe increase up to 2.7 and 6.6 dB, respectively. The highest image quality was achieved by projecting axial data, completed with a small segment determined by either principal component analysis or by application of a rotation matrix. [ABSTRACT FROM AUTHOR]

Published

2009

25. Advanced Ultrasound and Photoacoustic Imaging in Cardiology.

Author

Wu, Min, Awasthi, Navchetan, Rad, Nastaran Mohammadian, Pluim, Josien P. W., and Lopata, Richard G. P.

Subjects

ACOUSTIC imaging, ULTRASONIC imaging, DEEP learning, CAUSES of death, LIGHT absorption, CARDIAC radionuclide imaging

Abstract

Cardiovascular diseases (CVDs) remain the leading cause of death worldwide. An effective management and treatment of CVDs highly relies on accurate diagnosis of the disease. As the most common imaging technique for clinical diagnosis of the CVDs, US imaging has been intensively explored. Especially with the introduction of deep learning (DL) techniques, US imaging has advanced tremendously in recent years. Photoacoustic imaging (PAI) is one of the most promising new imaging methods in addition to the existing clinical imaging methods. It can characterize different tissue compositions based on optical absorption contrast and thus can assess the functionality of the tissue. This paper reviews some major technological developments in both US (combined with deep learning techniques) and PA imaging in the application of diagnosis of CVDs. [ABSTRACT FROM AUTHOR]

Published

2021

26. Towards mechanical characterization of intact endarterectomy samples of carotid arteries during inflation using Echo-CT.

Author

Boekhoven, Renate W., Rutten, Marcel C. M., van Sambeek, Marc R., van de Vosse, Frans N., and Lopata, Richard G. P.

Subjects

*CAROTID endarterectomy, *PHYSIOLOGIC strain, *ARTERIAL calcification, *ATHEROSCLEROSIS, *COMPUTED tomography, *BIOMECHANICS, *ULTRASONIC imaging, *ATHEROSCLEROTIC plaque

Abstract

In this study, an experimental framework is described that allows pressurization of intact, human atherosclerotic carotid samples (inflation testing), in combination with ultrasound imaging. Eight fresh human carotid endarterectomy samples were successfully pressurized and tested. About 36 2-D (+1) ultrasound datasets were acquired by rotating the vessel in 10° steps (Echo-CT), from which both 3-D geometry and 3-D strain data were obtained. Both geometry and morphology were assessed with micro-CT imaging, identifying calcified and lipid rich regions. US-based and CT-based geometries were matched for comparison and were found to show good agreement, with an average similarity index of 0.71. Realistic pressure-volume relations were found for 6 out of 9 samples. 3-D strain datasets were reconstructed, revealing realistic strain patterns and magnitudes, although the data did suffer from a relatively high variability. The percentage of fat and calcifications (micro-CT) were compared with the median, 75th and 99th percentile strain values (Echo-CT). A moderate trend was observed for 75th and 99th percentile strains, higher strains were found for more lipid rich plaques, where lower strains were found for highly calcified plaques. However, an inverse numerical modeling technique is necessary for proper mechanical characterization the of plaque components, using the geometry, morphology and wall deformation as input. [ABSTRACT FROM AUTHOR]

Published

2014