Your search keyword '"Coussios C"' showing total 6 results

1. Passive acoustic mapping of extravasation following ultrasound-enhanced drug delivery.

Author

Paverd C, Lyka E, Elbes D, and Coussios C

Subjects

Computer Simulation, Humans, Neoplasms drug therapy, Ultrasonography instrumentation, Acoustics, Drug Delivery Systems, Extravasation of Diagnostic and Therapeutic Materials, Image Processing, Computer-Assisted methods, Phantoms, Imaging, Ultrasonography methods

Abstract

The amount and distribution of chemotherapeutic agents delivered to tumours can vary significantly due to tumour heterogeneity, even under focussed ultrasound (FUS) assisted drug delivery regimes. The ability to non-invasively localise cavitation nuclei of a similar size to therapeutic drugs, both within the vasculature and tumour tissue, may provide a useful marker of ultrasound-enhanced drug delivery and extravasation. Solid polymer based nanoscale cavitation nuclei, under FUS excitation, have previously been shown to extravasate into tissue-mimicking phantoms, and to increase drug delivery in murine tumour models in vivo. Here we show in a tissue-mimicking material that these nuclei, once extravasated under FUS excitation, are still acoustically active and can be non-invasively localised using passive acoustic mapping (PAM). By using a high resolution dual linear array setup in conjunction with adaptive beamformers, we demonstrate that the average 'maximum distance' of a PAM pixel to an extravasated particle across experiments is [Formula: see text] mm. Although the primary objective of the paper is to show that extravascular cavitation can be used as evidence of successful drug extravasation in a tissue-mimicking phantom, we also recognise the physical and computational limitations of using a high resolution dual array setup with adaptive beamformers. Thus as a secondary objective, we evaluate tradeoffs between adaptive and non-adaptive beamformers, as well as between dual and single array geometries. When compared to a conventional beamformer, adaptive beamformers reduce the maximum distance of PAM pixels to extravasated particles from an average of [Formula: see text] mm to [Formula: see text] mm in the single array case. The distance is further reduced to [Formula: see text] mm using the dual array configuration, thereby demonstrating that increasing the solid angle spanned by the PAM array aperture significantly improves drug delivery localisation. Future work will test the applicability of PAM-based monitoring of ultrasound-enhanced drug delivery in vivo.

Published

2019

2. Nonlinear acoustic properties of ex vivo bovine liver and the effects of temperature and denaturation.

Author

Jackson EJ, Coussios CC, and Cleveland RO

Subjects

Animals, Cattle, Time Factors, Transducers, Acoustics, High-Intensity Focused Ultrasound Ablation instrumentation, Liver cytology, Nonlinear Dynamics, Temperature

Abstract

Thermal ablation by high intensity focused ultrasound (HIFU) has a great potential for the non-invasive treatment of solid tumours. Due to the high pressure amplitudes involved, nonlinear acoustic effects must be understood and the relevant medium property is the parameter of nonlinearity B/A. Here, B/A was measured in ex vivo bovine liver, over a heating/cooling cycle replicating temperatures reached during HIFU ablation, adapting a finite amplitude insertion technique, which also allowed for measurement of sound-speed and attenuation. The method measures the nonlinear progression of a plane wave through liver and B/A was chosen so that numerical simulations matched the measured waveforms. To create plane-wave conditions, sinusoidal bursts were transmitted by a 100 mm diameter 1.125 MHz unfocused transducer and measured using a 15 mm diameter 2.25 MHz broadband transducer in the near field. Attenuation and sound-speed were calculated using a reflected pulse from the smaller transducer using the larger transducer as the reflecting interface. Results showed that attenuation initially decreased with heating then increased after denaturation, the sound-speed initially increased with temperature and then decreased, and B/A showed an increase with temperature but no significant post-heating change. The B/A data disagree with other reports that show a significant change and we suggest that any nonlinear enhancement in the received ultrasound signal post-treatment is likely due to acoustic cavitation rather than changes in tissue nonlinearity.

Published

2014

3. Real-time temperature estimation and monitoring of HIFU ablation through a combined modeling and passive acoustic mapping approach.

Author

Jensen CR, Cleveland RO, and Coussios CC

Subjects

Time Factors, Acoustics, High-Intensity Focused Ultrasound Ablation, Models, Biological, Temperature

Abstract

Passive acoustic mapping (PAM) has been recently demonstrated as a method of monitoring focused ultrasound therapy by reconstructing the emissions created by inertially cavitating bubbles (Jensen et al 2012 Radiology 262 252-61). The published method sums energy emitted by cavitation from the focal region within the tissue and uses a threshold to determine when sufficient energy has been delivered for ablation. The present work builds on this approach to provide a high-intensity focused ultrasound (HIFU) treatment monitoring software that displays both real-time temperature maps and a prediction of the ablated tissue region. This is achieved by determining heat deposition from two sources: (i) acoustic absorption of the primary HIFU beam which is calculated via a nonlinear model, and (ii) absorption of energy from bubble acoustic emissions which is estimated from measurements. The two sources of heat are used as inputs to the bioheat equation that gives an estimate of the temperature of the tissue as well as estimates of tissue ablation. The method has been applied to ex vivo ox liver samples and the estimated temperature is compared to the measured temperature and shows good agreement, capturing the effect of cavitation-enhanced heating on temperature evolution. In conclusion, it is demonstrated that by using PAM and predictions of heating it is possible to produce an evolving estimate of cell death during exposure in order to guide treatment for monitoring ablative HIFU therapy.

Published

2013

4. Role of acoustic cavitation in the delivery and monitoring of cancer treatment by high-intensity focused ultrasound (HIFU).

Author

Coussios CC, Farny CH, Haar GT, and Roy RA

Subjects

Humans, Treatment Outcome, Acoustics, Microbubbles, Neoplasms diagnosis, Neoplasms therapy, Ultrasonic Therapy methods, Ultrasonography

Abstract

Acoustic cavitation has been shown to play a key role in a wide array of novel therapeutic ultrasound applications. This paper presents a brief discussion of the physics of thermally relevant acoustic cavitation in the context of high-intensity focussed ultrasound (HIFU). Models for how different types of cavitation activity can serve to accelerate tissue heating are presented, and results suggest that the bulk of the enhanced heating effect can be attributed to the absorption of broadband acoustic emissions generated by inertial cavitation. Such emissions can be readily monitored using a passive cavitation detection (PCD) scheme and could provide a means for real-time treatment monitoring. It is also shown that the appearance of hyperechoic regions (or bright-ups) on B-mode ultrasound images constitutes neither a necessary nor a sufficient condition for inertial cavitation activity to have occurred during HIFU exposure. Once instigated at relatively large HIFU excitation amplitudes, bubble activity tends to grow unstable and to migrate toward the source transducer, causing potentially undesirable pre-focal damage. Potential means of controlling inertial cavitation activity using pulsed excitation so as to confine it to the focal region are presented, with the intention of harnessing cavitation-enhanced heating for optimal HIFU treatment delivery. The role of temperature elevation in mitigating bubble-enhanced heating effects is also discussed, along with other bubble-field effects such as multiple scattering and shielding.

Published

2007

5. Effects of human tissue acoustic properties, abdominal wall shape, and respiratory motion on ultrasound-mediated hyperthermia for targeted drug delivery to pancreatic tumors

Author

Gray, M, Spiers, L, and Coussios, C

Subjects

Pancreatic Neoplasms, Cancer Research, Drug Delivery Systems, Clinical Trials, Phase I as Topic, Physiology, Physiology (medical), Abdominal Wall, High-Intensity Focused Ultrasound Ablation, Humans, Hyperthermia, Acoustics, Hyperthermia, Induced

Abstract

Background PanDox is a Phase-1 trial of chemotherapeutic drug delivery to pancreatic tumors using ultrasound-mediated hyperthermia to release doxorubicin from thermally sensitive liposomes. This report describes trial-related hyperthermia simulations featuring: (i) new ultrasonic properties of human pancreatic tissues, (ii) abdomen deflections imposed by a water balloon, and (iii) respiration-driven organ motion. MethodsPancreas heating simulations were carried out using three patient body models. Pancreas acoustic properties were varied between values found in the literature and those determined from our human tissue study. Acoustic beam distortion was assessed with and without balloon-induced abdomen deformation. Target heating was assessed for static, normal respiratory, and jet-ventilation-controlled pancreas motion. Results Human pancreatic tumor attenuation is 63% of the literature values, so that pancreas treatments require commensurately higher input intensity to achieve adequate hyperthermia. Abdominal wall deformation decreased the peak field pressure by as much as 3.5 dB and refracted the focal spot by as much as 4.5 mm. These effects were thermally counteracted by sidelobe power deposition, so the net impact on achieving mild hyperthermia was small. Respiratory motion during moving beam hyperthermia produced localized regions overheated by more than 8.0 °C above the 4.0 °C volumetric goal. The use of jet ventilation reduced this excess to 0.7 °C and yielded temperature field uniformity that was nearly identical to having no respiratory motion. Conclusion Realistic modeling of the ultrasonic propagation environment is critical to achieving adequate mild hyperthermia without the use of real time thermometry for targeted drug delivery in pancreatic cancer patients.

Published

2022

6. Use of passive arrays for characterization and mapping of cavitation activity during HIFU exposure

Author

Gyoengy, M, Arora, M, Noble, J, Coussios, C, and IEEE

Subjects

Materials science, business.industry, Acoustics, medicine.medical_treatment, Ultrasound, Context (language use), Ablation, Signal, Transducer, Acoustic emission, Cavitation, medicine, Radio frequency, business

Abstract

Inertial cavitation occurring during HIFU exposure can act both as a promoter and as a marker of heat deposition, because bubbles re-radiate part of the incident field as broadband noise emissions that are detectable over a frequency range far removed from the main HIFU excitation frequency. In the present work, a commercially available ultrasound scanning system (with the transmit signal turned off) and linear array are used to detect the emissions emanating from cavitating bubbles passively on 64 independent channels during HIFU exposure. A novel algorithm is presented that enables localization and mapping of cavitation activity, both for the case of a single bubble and in the context of contiguous, disjoint cavitating regions. By contrast to B-mode hyperechogenicity imaging that is widely used in ultrasound-guided HIFU systems but can only operate whilst the HIFU is off, the passive imaging technique presented here can be implemented during HIFU exposure, thus providing a potential means of real-time treatment monitoring during ablation.

Published

2008