Intravascular Ultrasound Imaging With Virtual Source Synthetic Aperture Focusing and Coherence Factor Weighting

Yu, Mingyue; Li, Yang; Ma, Teng; Shung, K. Kirk; Zhou, Qifa

doi:10.1109/tmi.2017.2723479

Cited by 21 publications

(8 citation statements)

References 44 publications

(54 reference statements)

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“…The hand-held UBM probe was placed on the acoustic window and scanned in a plane perpendicular to the target wires of the phantom. Under the premise of keeping the axial and lateral resolution unchanged, the phantom was used to verify the influence of the number of bits of the coded excitation on the depth of detection 33 .…”

Section: Methodsmentioning

confidence: 99%

Research on Golay-coded excitation in real-time imaging of high frequency ultrasound biomicroscopy

Wang

Yang

et al. 2021

Sci Rep

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High frequency ultrasonic imaging provides clinicians with high-resolution diagnostic images and more accurate measurement results. The technique is now widely used in ophthalmology, dermatology, and small animal imaging. However, since ultrasonic attenuation in tissue increases rapidly with increasing frequency, the depth of detection of high frequency ultrasound in tissue is limited to a few millimeters. In this paper, a novel method of using Golay-coded excitation as a replacement for conventional single-pulse excitation in high frequency ultrasound biomicroscopy was proposed, and real-time imaging was realized. While maintaining the transmission voltage and image resolution unchanged, the detection depth can be effectively improved. The ultrasonic transmission frequency is 30 MHz and the transmission voltage is ± 60 V p-p. In this study, 4-bit, 8-bit, and 16-bit coding sequences and decoding compression were used. To verify the effectiveness of the coding sequence in real-time imaging of ultrasound biomicroscopy, we designed a 10-μm diameter line target echo experiment, an ultrasound phantom experiment, and an in vitro porcine eye experiment. The experimental results show that the code/decode method of signal processing can not only maintain a resolution consistent with that of single-pulse transmission, but can also improve the detection depth and signal-to-noise ratio.

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Section: Methodsmentioning

confidence: 99%

Research on Golay-coded excitation in real-time imaging of high frequency ultrasound biomicroscopy

Wang

Yang

et al. 2021

Sci Rep

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“…A similar problem exists when focused beams are used to synthesize emitting aperture. M. Yu et al 14 adopted virtual source SA method in a single-element IVUS system to improve image quality in depth other than the focusing depth. They overcome the limited beam width by increasing the scanning density to 1000 lines per frame.…”

Section: Eccentric Cylinder Wave Compound Imaging (Ecwc)mentioning

confidence: 99%

“…There are points that coherence-factor-based methods can improve resolution, 12,14 which should be correct for single scatterers located far from others. But for scatterers close to each other, the coherence factor (CF) gets blurred together, and scatterers could not be distinguished.…”

Section: Introductionmentioning

confidence: 99%

An Optimum Imaging Scheme for IVUS Arrays: Eccentric Cylinder Wave Compounding

Feng

2019

Ultrason Imaging

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With the development of integrated circuit (IC) technologies, complex transmitting and receiving circuits can be integrated into miniature intravascular ultrasound (IVUS) catheters, making it possible to adopt better synthesizing schemes for better imaging. Eccentric cylinder wave compounding should be an optimum synthesizing scheme for the small size cylinder shaped catheter. Eccentric cylinder waves centered at different points are emitted, signals are collected after each emission, and images can be synthesized with easy post processing. Detailed analyses about resolution and grating lobes were made; the optimum eccentric distance was determined. Simulations were done to examine the resolution, signal-to-noise ratio, and resistance to crosstalk and nonuniformity of arrays. Dual apodization and magnitude-based deconvolution were applied to further improve the results.

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“…However, mechanical scanning of the transducer can provide the clinician with a high-resolution, transmural 360˚view of the tissue layers of the GI tract and is therefore of immediate interest as it can potentially provide highly detailed cross-sectional images of the GI wall. Compared with the other two solutions, mechanical rotating transducer (Figure 1c) simplifies device fabrication and electronics and is therefore particularly useful for USCE in its early development, paralleling to the development of the similar solution in intravascular ultrasound (Yu et al 2017). In a previous study, we demonstrated a mechanically scanned ultrasound capsule, shown in Figure 1c, that showed potential for clinical applications based on experimental data from ex vivo tests (Wang et al 2017b).…”

Section: Introductionmentioning

confidence: 99%

Ultrasound Capsule Endoscopy With a Mechanically Scanning Micro-ultrasound: A Porcine Study

Qiu

Huang

Zhang

et al. 2020

Ultrasound in Medicine & Biology

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Wireless capsule endoscopy has been used for the clinical examination of the gastrointestinal (GI) tract for two decades. However, most commercially available devices only utilise optical imaging to examine the GI wall surface. Using this sensing modality, pathology within the GI wall cannot be detected. Micro-ultrasound (mUS) using high-frequency (>20 MHz) ultrasound can provide a means of transmural or cross-sectional image of the GI tract. Depth of imaging is approximately 10 mm with a resolution of between 40À120 mm that is sufficient to differentiate between subsurface histologic layers of the various regions of the GI tract. Ultrasound capsule endoscopy (USCE) uses a capsule equipped with mUS transducers that are capable of imaging below the GI wall surface, offering thereby a complementary sensing technique to optical imaging capsule endoscopy. In this work, a USCE device integrated with a »30 MHz ultrasonic transducer was developed to capture a full 360˚image of the lumen. The performance of the device was initially evaluated using a wire phantom, indicating an axial resolution of 69.0 mm and lateral resolution of 262.5 mm. Later, in vivo imaging performance was characterised in the oesophagus and small intestine of anaesthetized pigs. The reconstructed images demonstrate clear layer differentiation of the lumen wall. The tissue thicknesses measured from the B-scan images show good agreement with ex vivo images from the literature. The high-resolution ultrasound images in the in vivo porcine model achieved with this device is an encouraging preliminary step in the translation of these devices toward future clinical use.

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Intravascular Ultrasound Imaging With Virtual Source Synthetic Aperture Focusing and Coherence Factor Weighting

Cited by 21 publications

References 44 publications

Research on Golay-coded excitation in real-time imaging of high frequency ultrasound biomicroscopy

Research on Golay-coded excitation in real-time imaging of high frequency ultrasound biomicroscopy

An Optimum Imaging Scheme for IVUS Arrays: Eccentric Cylinder Wave Compounding

Ultrasound Capsule Endoscopy With a Mechanically Scanning Micro-ultrasound: A Porcine Study

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