Archives of Acoustics, 43, 3, pp. 437–446, 2018
10.24425/123915

Synthetic Aperture Cardiac Imaging with Reduced Number of Acquisition Channels. A Feasibility Study

Yuriy TASINKEVYCH
Institute of Fundamental Technological Research PAS
Poland

Marcin LEWANDOWSKI
Institute of Fundamental Technological Research PAS
Poland

Ziemowit KLIMONDA
Institute of Fundamental Technological Research PAS
Poland

Mateusz Walczak
Institute of Fundamental Technological Research PAS
Poland

Commercially available cardiac scanners use 64–128 elements phased-array (PA) probes and classical delay-and-sum beamforming to reconstruct a sector B-mode image. For portable and hand-held scanners, which are the fastest growing market, channel count reduction can greatly decrease the total power and cost of devices. The introduction of ultra-fast imaging methods based on plane waves and diverging waves provides new insight into heart’s moving structures and enables the implementation of new myocardial assessment and advanced flow estimation methods, thanks to much higher frame rates. The goal of this study was to show the feasibility of reducing the channel count in the diverging wave synthetic aperture image reconstruction method for phased-arrays. The application of ultra-fast 32-channel subaperture imaging combined with spatial compounding allowed the frame rate of approximately 400 fps for 120 mm visualization to be achieved with image quality obtained on par with the classical 64-channel beamformer. Specifically, it was shown that the proposed method resulted in image quality metrics (lateral resolution, contrast and contrast-to-noise ratio), for a visualization depth not exceeding 50 mm, that were comparable with the classical PA beamforming. For larger visualization depths (80–100 mm) a slight degradation of the above parameters was observed. In conclusion, diverging wave phased-array imaging with reduced number of channels is a promising technology for low-cost, energy efficient hand-held cardiac scanners.
Keywords: phased-array; ultrasound imaging; diverging wave; synthetic transmit aperture.
Full Text: PDF
Copyright © Polish Academy of Sciences & Institute of Fundamental Technological Research (IPPT PAN).

References

Bae M.H., Jeong M.K. (2000), A study of synthetic aperture maging with virtual source elements in B-mode ultrasound imaging systems, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 47, 6, 1510-1519.

Cikes M., Tong L., Sutherland G.R., D'hooge J. (2014), Ultrafast Cardiac Ultrasound Imaging: Technical Principles, Applications, and Clinical Benets, JACC: Cardiovascular Imaging, 7, 8, 812 -823.

Cygan S., Kumor M., Żmigrodzki J., Leśniak-Plewińska B., Kowalski M., Kałużyński K. (2017), Left ventricular phantoms with inclusions simulating transmural and non-transmural infarctions - FEM and EchoPAC study, Medical Imaging 2017: Ultrasonic Imaging and Tomography, 1013918-1.

Hasegawa H., Kanai H. (2011), High-frame-rate echocardiography using diverging transmit beams and parallel receive beamforming, Journal of Medical Ultrasonics, 38, 3, 129-140.

Lewandowski M., Walczak M., Witek B., Kulesza P., Sielewicz K. (2012), Modular & Scalable Ultrasound Platform with GPU Processing, Proc. 2012 IEEE Ultrasonics Symp., 2071-2074.

Moore C., Castellucci J., Andersen M.V., Lefevre M., Arges K., Kisslo J., von Ramm O.T. (2015), Live high-frame-rate echocardiography, IEEE Transactions on Ultrasonics, Ferroectrics, and Frequency Control, 62, 10, 1779-1787.

Papadacci C., Pernot M., Couade M., Fink M., Tanter M. (2014), High-contrast ultrafast imaging of the heart, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 61, 2, 288-301.

Phantom (571), URL http://www.fantom.dk/571.htm.

Seraphim A., Paschou S.A., Grapsa J., Nihoyannopoulos P. (2016), Pocket-Sized Echocardiography Devices: One Stop Shop Service?, J Cardiovasc Ultrasound., 24, 1, 1-6.

Sulzbach-Hoke L.M., Schanne L.C. (1999), Using a portable ultrasound bladder scanner in the cardiac care unit, Critical Care Nurse, 6, 19, 35-39.

Tasinkevych Y., Klimonda Z., Lewandowski M., Nowicki A., Lewin P.A. (2013), Modied multielement synthetic transmit aperture method for ultrasound imaging: A tissue phantom study, Ultrasonics, 53, 570-579.

Tasinkevych Y., Trots I., Nowicki A., Lewandowski M. (2012a), Optimization of the Multielement Synthetic Transmit Aperture Method for Medical Ultrasound Imaging Applications, Archives of Acoustics, 37, 1, 47-55.

Tasinkevych Y., Trots I., Nowicki A., Lewin P.A. (2012b), Modied synthetic transmit aperture algorithm for ultrasound imaging, Ultrasonics, 52, 2, 333-342.

Tong L., Gao H., Choi H.F., D'hooge J. (2012), Comparison of conventional parallel beamforming with plane wave and diverging wave imaging for cardiac applications: a simulation study, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 59, 8, 1654-1663.




DOI: 10.24425/123915