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Cavitation monitoring, treatment strategy, and acoustic simulations of focused ultrasound blood-brain barrier disruption in patients with glioblastoma.

Authors :
McDannold, Nathan
Wen, Patrick Y.
Reardon, David A.
Fletcher, Stecia-Marie
Golby, Alexandra J.
Source :
Journal of Controlled Release. Aug2024, Vol. 372, p194-208. 15p.
Publication Year :
2024

Abstract

We report our experience disrupting the blood-brain barrier (BBB) to improve drug delivery in glioblastoma patients receiving temozolomide chemotherapy. The goals of this retrospective analysis were to compare MRI-based measures of BBB disruption and vascular damage to the exposure levels, acoustic emissions data, and acoustic simulations. We also simulated the cavitation detectors. Monthly BBB disruption (BBBD) was performed using a 220 kHz hemispherical phased array focused ultrasound system (Exablate Neuro, InSightec) and Definity microbubbles (Lantheus) over 38 sessions in nine patients. Exposure levels were actively controlled via the cavitation dose obtained by monitoring subharmonic acoustic emissions. The acoustic field and sensitivity profile of the cavitation detection system were simulated. Exposure levels and cavitation metrics were compared to the level of BBBD evident in contrast-enhanced MRI and to hypointense regions in T2*-weighted MRI. Our treatment strategy evolved from using a relatively high cavitation dose goal to a lower goal and longer sonication duration and ultimately resulted in BBBD across the treatment volume with minimal petechiae. Subsonication-level feedback control of the exposure using acoustic emissions also improved consistency. Simulations of the acoustic field suggest that reflections and standing waves appear when the focus is placed near the skull, but their effects can be mitigated with aberration correction. Simulating the cavitation detectors suggest variations in the sensitivity profile across the treatment volume and between patients. A correlation was observed with the cavitation dose, BBBD and petechial hemorrhage in 8/9 patients, but substantial variability was evident. Analysis of the cavitation spectra found that most bursts did not contain wideband emissions, a signature of inertial cavitation, but biggest contribution to the cavitation dose – the metric used to control the procedure – came from bursts with wideband emissions. Using a low subharmonic cavitation dose with a longer duration resulted in BBBD with minimal petechiae. The correlation between cavitation dose and outcomes demonstrates the benefits of feedback control based on acoustic emissions, although more work is needed to reduce variability. Acoustic simulations could improve focusing near the skull and inform our analysis of acoustic emissions. Monitoring additional frequency bands and improving the sensitivity of the cavitation detection could provide signatures of microbubble activity associated with BBB disruption that were undetected here and could improve our ability to achieve BBB disruption without vascular damage. A hemispherical ultrasound phased array was used to disrupt the BBB in glioblastoma patients. Left: targeted and disrupted volumes. Right: treatment plan and post-ultrasound contrast-enhanced MRI. [Display omitted] • We used focused ultrasound to disrupt the blood-brain barrier in glioma patients. • We found parameters that produced effective disruption with minimal side effects. • We demonstrated the potential utility of acoustic modeling of the treatments. • We show how acoustic emissions were related to the disruption and vascular damage. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
01683659
Volume :
372
Database :
Academic Search Index
Journal :
Journal of Controlled Release
Publication Type :
Academic Journal
Accession number :
178596384
Full Text :
https://doi.org/10.1016/j.jconrel.2024.06.036