2-D high-frame-rate dynamic elastography using delay compensated and angularly compounded motion vectors: Preliminary results

Azar, Reza Zahiri; Baghani, Ali; Salcudean, Septimiu E.; Rohling, Robert

doi:10.1109/tuffc.2010.1709

Cited by 27 publications

(15 citation statements)

References 45 publications

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“…Sector-based sequencing consists of dividing the image into sectors, which are then acquired multiple times before acquiring the next. This method is widely used for blood flow estimation, strain-rate imaging (Heimdal et al, 1998) and, more recently, for the estimation of the tissue motion for steady-state periodic excitations (Baghani et al, 2010; Azar et al, 2010). However, it remains limited in terms of frame rate when imaging in a full field of view of the heart.…”

Section: Introductionmentioning

confidence: 99%

Electromechanical wave imaging for arrhythmias

et al. 2011

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Electromechanical Wave Imaging (EWI) is a novel ultrasound-based imaging modality for the mapping of the electromechanical wave (EW), i.e., the transient deformations occurring in immediate response to the electrical activation. The correlation between the EW and the electrical activation has been established in previous studies. However, the methods used previously to map the EW required the reconstruction of images over multiple cardiac cycle, precluding the application of EWI for non-periodic arrhythmia such as fibrillation. In this study, we develop new imaging sequences based on flash and wide-beam emissions to image the entire heart at very high frame rate (2000 fps) during free breathing in a single heartbeat. The methods are first validated by imaging the heart of an open-chest canine while simultaneously mapping the electrical activation using a 64-electrode basket catheter. Feasibility is then assessed by imaging the atria and ventricles of closed-chest, conscious canines during sinus rhythm and during right-ventricular pacing following atrioventricular dissociation, i.e., a non-periodic rhythm. The EW was validated against electrode measurements in the open-chest case, and followed the expected electrical propagation pattern in the closed-chest setting. These results indicate that EWI can be used for the characterization of non-periodic arrhythmia in conditions close to the clinical setting, in a single heartbeat, and during free-breathing.

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Section: Introductionmentioning

confidence: 99%

Electromechanical wave imaging for arrhythmias

et al. 2011

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“…When using RF cross-correlation, only two consecutive pulses are necessary to provide a high accuracy estimate of motion, leading to a four- to five-fold increase in the motion-sampling rate, field of view or beam density. Such an approach has been described as ‘sector-based sequencing’ and recently used for steady-state periodic excitations (Baghani et al, 2010; Azar et al, 2010). …”

Section: Introductionmentioning

confidence: 99%

Single-heartbeat electromechanical wave imaging with optimal strain estimation using temporally unequispaced acquisition sequences

et al. 2012

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Electromechanical Wave Imaging (EWI) is a non-invasive, ultrasound-based imaging method capable of mapping the electromechanical wave (EW) in vivo, i.e., the transient deformations occurring in response to the electrical activation of the heart. Achieving the optimal imaging frame rates, in terms of the elastographic signal-to-noise ratio, to capture the EW in a full-view of the heart poses a technical challenge due to the limitations of conventional imaging sequences, in which the frame rate is low and tied to the imaging parameters. To achieve higher frame rates, EWI is typically performed in multiple small regions of interest acquired over separate heartbeats, which are then combined into a single view. However, the reliance on multiple heartbeats has previously precluded the method from its application in non-periodic arrhythmias such as fibrillation. Moreover, the frame rates achieved remain sub-optimal, because they are determined by the imaging parameters rather than being optimized to image the EW. In this paper, we develop a temporally-unequispaced acquisition sequence (TUAS) for which a wide range of frame rates are achievable independently of the imaging parameters, while maintaining a full view of the heart at high beam density. TUAS is first used to determine the optimal frame rate for EWI in a paced canine heart in vivo. The feasibility of performing single-heartbeat EWI during ventricular fibrillation is then demonstrated. These results indicate that EWI can be performed optimally, within a single heartbeat, during free breathing, and implemented in real time for periodic and non-periodic cardiac events.

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“…An interface software system was developed in C++ and Qt 4. To achieve a high temporal resolution, a sector subdivision technique was employed [14]. Each of the sectors had four lines acquired using a pulse repetition frequency of 2 kHz, resulting in 32 sectors and the final frame composed of 128 scan lines.…”

Section: Methodsmentioning

confidence: 99%

Shear wave Vibro Magneto Acoustography for measuring tissue mimicking phantom elasticity and viscosity

Almeida

Sampaio

Pavan

et al. 2014

2014 IEEE International Ultrasonics Symposium

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Estimating the rheological properties of soft tissues is a useful procedure to identify and evaluate pathologies in medical diagnosis. Quantification of soft tissue viscoelasticity can be achieved by generating and tracking shear wave propagation. Many ultrasound-based techniques have been used to evaluate the induced shear wave. The viscosity and elasticity can be measured by shear wave dispersion. The Magneto Motive Ultrasound induces motion within magnetically labeled tissue. This paper describes the Shear wave Dispersion Vibro Magneto Acoustography (SDVMA) technique for analysis and quantifying the viscoelasticity through shear wave propagation in gelatin phantoms labeled with ferromagnetic nanoparticles. Phantoms were excited applying an external magnetic field gradient and the movements induced in the internal phantom structure due to the interaction of the field with the particles were obtained through pulse-echo equipment ultrasound. The movement information were processed to get values of elasticity and viscosity of the medium.

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2-D high-frame-rate dynamic elastography using delay compensated and angularly compounded motion vectors: Preliminary results

Cited by 27 publications

References 45 publications

Electromechanical wave imaging for arrhythmias

Electromechanical wave imaging for arrhythmias

Single-heartbeat electromechanical wave imaging with optimal strain estimation using temporally unequispaced acquisition sequences

Shear wave Vibro Magneto Acoustography for measuring tissue mimicking phantom elasticity and viscosity

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