Intracranial inertial cavitation threshold and thermal ablation lesion creation using MRI-guided 220-kHz focused ultrasound surgery: preclinical investigation

Zhiyuan Xu Departments of Neurosurgery,

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Carissa Carlson Focused Ultrasound Foundation, Charlottesville, Virginia; and

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John Snell Focused Ultrasound Foundation, Charlottesville, Virginia; and

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Matt Eames Focused Ultrasound Foundation, Charlottesville, Virginia; and

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Arik Hananel Focused Ultrasound Foundation, Charlottesville, Virginia; and

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M. Beatriz Lopes Pathology (Neuropathology), and

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Prashant Raghavan Neuroradiology,

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Cheng-Chia Lee Departments of Neurosurgery,

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Chun-Po Yen Departments of Neurosurgery,

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David Schlesinger Departments of Neurosurgery,
Radiation Oncology, University of Virginia Health System;

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Neal F. Kassell Focused Ultrasound Foundation, Charlottesville, Virginia; and

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Jean-Francois Aubry Radiation Oncology, University of Virginia Health System;
Institut Langevin, CNRS UMR 7587, INSERM U979, ESPCI Paris Tech, Paris, France

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Jason Sheehan Departments of Neurosurgery,
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Page Range:
152–161
Volume/Issue:
Volume 122: Issue 1
DOI link:
https://doi.org/10.3171/2014.9.JNS14541
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OBJECT

In biological tissues, it is known that the creation of gas bubbles (cavitation) during ultrasound exposure is more likely to occur at lower rather than higher frequencies. Upon collapsing, such bubbles can induce hemorrhage. Thus, acoustic inertial cavitation secondary to a 220-kHz MRI-guided focused ultrasound (MRgFUS) surgery is a serious safety issue, and animal studies are mandatory for laying the groundwork for the use of low-frequency systems in future clinical trials. The authors investigate here the in vivo potential thresholds of MRgFUS-induced inertial cavitation and MRgFUS-induced thermal coagulation using MRI, acoustic spectroscopy, and histology.

METHODS

Ten female piglets that had undergone a craniectomy were sonicated using a 220-kHz transcranial MRgFUS system over an acoustic energy range of 5600–14,000 J. For each piglet, a long-duration sonication (40-second duration) was performed on the right thalamus, and a short sonication (20-second duration) was performed on the left thalamus. An acoustic power range of 140–300 W was used for long-duration sonications and 300–700 W for short-duration sonications. Signals collected by 2 passive cavitation detectors were stored in memory during each sonication, and any subsequent cavitation activity was integrated within the bandwidth of the detectors. Real-time 2D MR thermometry was performed during the sonications. T1-weighted, T2-weighted, gradient-recalled echo, and diffusion-weighted imaging MRI was performed after treatment to assess the lesions. The piglets were killed immediately after the last series of posttreatment MR images were obtained. Their brains were harvested, and histological examinations were then performed to further evaluate the lesions.

RESULTS

Two types of lesions were induced: thermal ablation lesions, as evidenced by an acute ischemic infarction on MRI and histology, and hemorrhagic lesions, associated with inertial cavitation. Passive cavitation signals exhibited 3 main patterns identified as follows: no cavitation, stable cavitation, and inertial cavitation. Low-power and longer sonications induced only thermal lesions, with a peak temperature threshold for lesioning of 53°C. Hemorrhagic lesions occurred only with high-power and shorter sonications. The sizes of the hemorrhages measured on macroscopic histological examinations correlated with the intensity of the cavitation activity (R2 = 0.74). The acoustic cavitation activity detected by the passive cavitation detectors exhibited a threshold of 0.09 V·Hz for the occurrence of hemorrhages.

CONCLUSIONS

This work demonstrates that 220-kHz ultrasound is capable of inducing a thermal lesion in the brain of living swines without hemorrhage. Although the same acoustic energy can induce either a hemorrhage or a thermal lesion, it seems that low-power, long-duration sonication is less likely to cause hemorrhage and may be safer. Although further study is needed to decrease the likelihood of ischemic infarction associated with the 220-kHz ultrasound, the threshold established in this work may allow for the detection and prevention of deleterious cavitations.

ABBREVIATIONS

FUS = focused ultrasound; MRgFUS = MRI-guided FUS; TcMRgFUS = transcranial MRgFUS.
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Contributor Notes

Correspondence Jason Sheehan, Department of Neurological Surgery, University of Virginia, Box 800212, Charlottesville, VA 22908. email: jsheehan@virginia.edu.

INCLUDE WHEN CITING Published online November 7, 2014; DOI: 10.3171/2014.9.JNS14541.

DISCLOSURE This work was funded by a grant from the Focused Ultrasound Foundation. Drs. Hananel and Kassell have shares in InSightec, the company that manufactures the ExAblate device. Drs. Snell, Hananel, Eames, and Kassell and Ms. Carlson are paid employees of the Focused Ultrasound Foundation. Dr. Aubrey is a consultant for the Focused Ultrasound Foundation.

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