Integrated ultrasound and magnetic resonance imaging for simultaneous temperature and cavitation monitoring during focused ultrasound therapies

Purpose: Ultrasound can be used to noninvasively produce different bioeffects via viscous heating, acoustic cavitation, or their combination, and these effects can be exploited to develop a wide range of therapies for cancer and other disorders. In order to accurately localize and control these diff...

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Bibliographic Details
Published in:Medical physics (Lancaster) 2013-11, Vol.40 (11), p.112901-n/a
Main Authors: Arvanitis, Costas D., McDannold, Nathan
Format: Article
Language:English
Subjects:
Acoustic cavitation
Acoustic emission
Acoustical effects
Acoustics
Anatomic imaging
Biological effects of acoustic and ultrasonic energy
Biological material, e.g. blood, urine
Haemocytometers
biomedical MRI
biomedical ultrasonics
biothermics
brain
Brain Neoplasms - diagnostic imaging
Brain Neoplasms - therapy
bubbles
cancer
cavitation
cavitation enhanced ablation
cavitation mapping
Clinical applications
Diagnosis using ultrasonic, sonic or infrasonic waves
Digital computing or data processing equipment or methods, specially adapted for specific applications
Electrical, thermal, and mechanical properties of biological matter
Fluid bubbles
Hot Temperature
Humans
Image data processing or generation, in general
image guided FUS
image registration
Involving electronic [emr] or nuclear [nmr] magnetic resonance, e.g. magnetic resonance imaging
Magnetic Resonance Imaging
medical disorders
medical image processing
Medical imaging
Microbubbles
MR thermometry
Neoplasms - therapy
optimisation
phantoms
Phantoms, Imaging
Registration
Skull - diagnostic imaging
Sonication
tumours
Ultrasonic effects
Ultrasonic Therapy
Ultrasonographic imaging
Ultrasonography
Ultrasound Physics
Ultrasound therapy
Viscosity
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Summary:Purpose: Ultrasound can be used to noninvasively produce different bioeffects via viscous heating, acoustic cavitation, or their combination, and these effects can be exploited to develop a wide range of therapies for cancer and other disorders. In order to accurately localize and control these different effects, imaging methods are desired that can map both temperature changes and cavitation activity. To address these needs, the authors integrated an ultrasound imaging array into an MRI-guided focused ultrasound (MRgFUS) system to simultaneously visualize thermal and mechanical effects via passive acoustic mapping (PAM) and MR temperature imaging (MRTI), respectively. Methods: The system was tested with an MRgFUS system developed for transcranial sonication for brain tumor ablation in experiments with a tissue mimicking phantom and a phantom-filledex vivo macaque skull. In experiments on cavitation-enhanced heating, 10 s continuous wave sonications were applied at increasing power levels (30–110 W) until broadband acoustic emissions (a signature for inertial cavitation) were evident. The presence or lack of signal in the PAM, as well as its magnitude and location, were compared to the focal heating in the MRTI. Additional experiments compared PAM with standard B-mode ultrasound imaging and tested the feasibility of the system to map cavitation activity produced during low-power (5 W) burst sonications in a channel filled with a microbubble ultrasound contrast agent. Results: When inertial cavitation was evident, localized activity was present in PAM and a marked increase in heating was observed in MRTI. The location of the cavitation activity and heating agreed on average after registration of the two imaging modalities; the distance between the maximum cavitation activity and focal heating was −3.4 ± 2.1 mm and −0.1 ± 3.3 mm in the axial and transverse ultrasound array directions, respectively. Distortions and other MRI issues introduced small uncertainties in the PAM/MRTI registration. Although there was substantial variation, a nonlinear relationship between the average intensity of the cavitation maps, which was relatively constant during sonication, and the peak temperature rise was evident. A fit to the data to an exponential had a correlation coefficient (R2) of 0.62. The system was also found to be capable of visualizing cavitation activity with B-mode imaging and of passively mapping cavitation activity transcranially during cavitation-enhanced h
ISSN:0094-2405
2473-4209
0094-2405
DOI:10.1118/1.4823793