Ultrasound Imaging

Improving subharmonic emission at high-frequencies by modifying the size distribution of microbubble contrast agents

by Himanshu Shekhar

Accepted for the 8th International Conference on Ultrasonic Biomedical Microscanning, Canada, 24th-27th September 2012

The proliferation of the adventitial vasa vasorum is linked to the disruption of atherosclerotic plaques. Subharmonic... more The proliferation of the adventitial vasa vasorum is linked to the disruption of atherosclerotic plaques. Subharmonic Intravascular Ultrasound (S-IVUS) could visualize the adventitial vasa vasorum by exploiting the subharmonic behavior of microbubble contrast agents, which may help identify life-threatening plaques. However, the high threshold pressure for subharmonic behavior may compromise the sensitivity of S-IVUS imaging.
Therefore, we conducted simulations and experiments that investigated the feasibility of improving imaging sensitivity by modifying agent size distribution. Four agent populations (1.1 - 2 m m mean diameter) created from Targestar-p were excited at 12-20 MHz, with peak-negative-pressures 50 - 400 kPa. We observed that subharmonic emission was highly sensitive to variations in agent size distribution. The agent population with mean diameter of 1.97 m m demonstrated the strongest subharmonic signal, with thresholds lower than 150 kPa for all frequencies, which suggests that sensitivity of H-IVUS imaging can be improved by modifying agent size.

Improving the sensitivity of high-frequency subharmonic imaging with coded excitation: A feasibility study

by Himanshu Shekhar

Himanshu Shekhar and Marvin M. Doyley
Medical Physics / Volume 39 / Issue 4 / ULTRASOUND PHYSICS

Purpose: Subharmonic intravascular ultrasound imaging (S-IVUS) could visualize the adventitial vasa vasorum, but the... more Purpose: Subharmonic intravascular ultrasound imaging (S-IVUS) could visualize the adventitial vasa vasorum, but the high pressure threshold required to incite subharmonic behavior in an ultrasound contrast agent will compromise sensitivity—a trait that has hampered the clinical use of S-IVUS. The purpose of this study was to assess the feasibility of using coded-chirp excitations to improve the sensitivity and axial resolution of S-IVUS.
Methods: The subharmonic response of Targestar-pTM, a commercial microbubble ultrasound contrast agent (UCA), to coded-chirp (5%–20% fractional bandwidth) pulses and narrowband sine-burst (4% fractional bandwidth) pulses was assessed, first using computer simulations and then experimentally. Rectangular windowed excitation pulses with pulse durations ranging from 0.25 to 3 μs were used in all studies. All experimental studies were performed with a pair of transducers (20 MHz/10 MHz), both with diameter of 6.35 mm and focal length of 50 mm. The size distribution of the UCA was measured with a CasyTM Cell counter.
Results: The simulation predicted a pressure threshold that was an order of magnitude higher than that determined experimentally. However, all other predictions were consistent with the experimental observations. It was predicted that: (1) exciting the agent with chirps would produce stronger subharmonic response relative to those produced by sine-bursts; (2) increasing the fractional bandwidth of coded-chirp excitation would increase the sensitivity of subharmonic imaging; and (3) coded-chirp would increase axial resolution. The experimental results revealed that subharmonic-to-fundamental ratios obtained with chirps were 5.7 dB higher than those produced with sine-bursts of similar duration. The axial resolution achieved with 20% fractional bandwidth chirps was approximately twice that achieved with 4% fractional bandwidth sine-bursts.
Conclusions: The coded-chirp method is a suitable excitation strategy for subharmonic IVUS imaging. At the 20 MHz transmission frequency and 20% fractional bandwidth, coded-chirp excitation appears to represent the ideal tradeoff between subharmonic strength and axial resolution.

Ultrasonography as a tool to study afferent feedback from the muscle-tendon complex during human walking

by Michael Grey

A dual-armed robotic system for intraoperative ultrasound guided hepatic ablative therapy: A prospective study

by Gregory Fischer

High-frequency subharmonic emission with chirp-coded excitation: implications for imaging

by Himanshu Shekhar

There is growing interest in developing techniques to assess the structure and function of microvasculature, to enable... more There is growing interest in developing techniques to assess the structure and function of microvasculature, to enable clinical diagnosis and to gain insights into disease pathology. High-frequency subharmonic imaging is an emerging technique that can visualize the microvasculature with high specificity. However, the sensitivity of high-frequency subharmonic imaging is compromised because of the pressure threshold for subharmonic behavior, which may limit its potential for preclinical and clinical imaging. The goal of this work was to demonstrate that the sensitivity of subharmonic imaging could be improved by rectangular apodization and chirp-coding of the excitation pulse. We report an experimental study carried out at 20-MHz transmit frequency to compare the efficacy of narrowband sine bursts and coded-chirps towards generating subharmonics. It was demonstrated that chirp-coding of the excitation pulse could generate stable subharmonic signals for excitation bandwidths of 10-20%. The threshold for onset of subharmonic behavior was lowest when rectangularwindowed excitation pulses were employed. The subharmonic to fundamental ratio of RF spectra using coded chirps was up to 5.7 dB higher for sine bursts, and the axial resolution obtained with chirp-coded excitation was up to twofold better compared to that obtained using sine bursts. At 20-MHz transmit frequency, 20% bandwidth rectangular chirp-coded pulse appears to be a good tradeoff between sensitivity and axial resolution.

Ultrasonic biomicroscopy of viable, dead and apoptotic cells

by Michael Kolios

A model based upon pseudo regular spacing of cells combined with the randomisation of the nuclei can explain the significant changes in high-frequency ultrasound …

by Michael Kolios

Ultrasonic characterization of whole cells and isolated nuclei

by Michael Kolios

Ultrasound imaging of apoptosis in tumor response: Novel preclinical monitoring of photodynamic therapy effects

by Michael Kolios

An investigation of backscatter power spectra from cells, cell pellets and microspheres

by Michael Kolios

High-frequency ultrasound for monitoring changes in liver tissue during preservation

by Michael Kolios

Quantitative ultrasound characterization of cancer radiotherapy effects in vitro

by Michael Kolios

Monitoring tissue response to photodynamic therapy: the potential of minimally invasive electrical impedance spectroscopy and high-frequency ultrasound

by Michael Kolios

The fluid and elastic nature of nucleated cells: Implications from the cellular backscatter response

by Michael Kolios

Ultrasound imaging of apoptosis. DNA-damage effects visualized.

by Michael Kolios

Analysis of ultrasound backscatter from ensembles of cells and isolated nuclei

by Michael Kolios

An investigation of the use of transmission ultrasound to measure acoustic attenuation changes in thermal therapy

by Michael Kolios

Quantitative ultrasound characterization of responses to radiotherapy in cancer mouse models

by Michael Kolios

Ultrasound backscatter microscopy/spectroscopy and optical coherence (Doppler) tomography for mechanism-specific monitoring of photodynamic therapy in vivo and …

by Michael Kolios

A study of high frequency ultrasound scattering from non-nucleated biological specimens

by Michael Kolios