Superharmonic imaging with chirp coded excitation: filtering spectrally overlapped harmonics

Harput, Sevan; McLaughlan, James R.; Cowell, David M. J.; Freear, Steven

doi:10.1109/tuffc.2014.006424

Cited by 19 publications

(11 citation statements)

References 50 publications

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“…This finding is contrary to second harmonic UCA imaging in practice. As implication, increasing the SNR should be the main focus for optimising superharmonic ultrasound contrast imaging, similar to the work recently activated by Harput et al for tissue superharmonic imaging 12 .…”

Section: Resultsmentioning

confidence: 77%

Ultrasound contrast agent imaging: Real-time imaging of the superharmonics

Peruzzini

Viti

Tortoli

et al. 2015

AIP Conference Proceedings

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Abstract. Currently, in medical ultrasound contrast agent (UCA) imaging the second harmonic scattering of the microbubbles is regularly used. This scattering is in competition with the signal that is caused by nonlinear wave propagation in tissue. It was reported that UCA imaging based on the third or higher harmonics, i.e. "superharmonic" imaging, shows better contrast. However, the superharmonic scattering has a lower signal level compared to e.g. second harmonic signals. This study investigates the contrast-to-tissue ratio (CTR) and signal to noise ratio (SNR) of superharmonic UCA scattering in a tissue/vessel mimicking phantom using a real-time clinical scanner. Numerical simulations were performed to estimate the level of harmonics generated by the microbubbles. Data were acquired with a custom built dual-frequency cardiac phased array probe. Fundamental real-time images were produced while beam formed radiofrequency (RF) data was stored for further offline processing. The phantom consisted of a cavity filled with UCA surrounded by tissue mimicking material. The acoustic pressure in the cavity of the phantom was 110 kPa (MI = 0.11) ensuring non-destructivity of UCA. After processing of the acquired data from the phantom, the UCA-filled cavity could be clearly observed in the images, while tissue signals were suppressed at or below the noise floor. The measured CTR values were 36 dB, >38 dB, and >32 dB, for the second, third, and fourth harmonic respectively, which were in agreement with those reported earlier for preliminary contrast superharmonic imaging. The single frame SNR values (in which 'signal' denotes the signal level from the UCA area) were 23 dB, 18 dB, and 11 dB, respectively. This indicates that noise, and not the tissue signal, is the limiting factor for the UCA detection when using the superharmonics in nondestructive mode.

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Section: Resultsmentioning

confidence: 77%

Ultrasound contrast agent imaging: Real-time imaging of the superharmonics

Peruzzini

Viti

Tortoli

et al. 2015

AIP Conference Proceedings

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“…While this combination of harmonic imaging and chirp transmission improves the resolution of the technique, side lobes can appear due to the chirp compression and frequency overlapping. The method can be improved by extracting the chirp SH component in a space between the time and frequency using the fractional Fourier transform (FrFT) [7]. Furthermore, pulse encoding is not limited to frequency encoding (chirp) and other codes such as Barker and Golay codes can also be used.…”

Section: Encoded Pulsesmentioning

confidence: 99%

Ultrasound Imaging with Microbubbles [Life Sciences]

Stanziola

Toulemonde

Yildiz

et al. 2016

IEEE Signal Process. Mag.

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“…Generation of wideband short-duration pulses is desirable both in diagnostic and therapeutic ultrasound. Wideband pulses improve the diagnostic image resolution and the functionality of other ultrasound modalities, such as harmonic imaging and multiple-excitation techniques [11][12][13][14]. In ultrasound therapy, short-duration monopolar ultrasonic pulses can create a spatially concentrated high-energy region, which minimizes the potential collateral damage in the surrounding healthy tissue [15].…”

Section: Introductionmentioning

confidence: 99%

Generation of Ultrasound Pulses in Water Using Granular Chains with a Finite Matching Layer

et al. 2017

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Wave propagation in granular chains is subject to dispersive effects as well as nonlinear effects arising from the Hertzian contact law. This enables the formation of wideband pulses, which is a desirable feature in the context of diagnostic and therapeutic ultrasound applications. However, coupling of the ultrasonic energy from a chain of spheres into biological tissue is a big challenge. In order to improve the energy transfer efficiency into biological materials, a matching layer is required. A prototype device is designed to address this by using six aluminum spheres and a vitreous carbon matching layer. The matching layer and the precompression force are selected specifically to maximize the acoustic pressure in water and its bandwidth. The designed device generates a train of wideband ultrasonic pulses from a narrow-band input with a center frequency of 73 kHz. An analytical model is created to simulate the behavior of a matching layer as a flexible thin plate clamped from the edges. This model is then verified using free-field hydrophone measurements in water, which successfully predict the increased bandwidth by generation of harmonics. The shapes of the measured and predicted waveforms are compared by calculating the normalized cross-correlation, which shows 83% similarity between both. Since the generation of harmonics is of interest in this study, the total harmonic distortion (THD) and the −6-dB bandwidth of the signals are used to analyze signal fidelity between the hydrophone measurements and the model predictions. The acoustic signals in water have a root-mean-square THD of 73%, and the model predicts a root-mean-square THD of 78%. The −6-dB bandwidths of individual pulses measured by a hydrophone and predicted with the model are 280 and 252 kHz, respectively. At these high ultrasonic frequencies, it is an experimental demonstration of resonant chains operating in water with a matching layer.

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Superharmonic imaging with chirp coded excitation: filtering spectrally overlapped harmonics

Cited by 19 publications

References 50 publications

Ultrasound contrast agent imaging: Real-time imaging of the superharmonics

Ultrasound contrast agent imaging: Real-time imaging of the superharmonics

Ultrasound Imaging with Microbubbles [Life Sciences]

Generation of Ultrasound Pulses in Water Using Granular Chains with a Finite Matching Layer

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