Preclinical evaluation of a low-frequency transcranial MRI-guided focused ultrasound system in a primate model.

This study investigated thermal ablation and skull-induced heating with a 230 kHz transcranial MRI-guided focused ultrasound (TcMRgFUS) system in nonhuman primates. We evaluated real-time acoustic feedback and aimed to understand whether cavitation contributed to the heating and the lesion formation. In four macaques, we sonicated thalamic targets at acoustic powers of 34-560 W (896-7590 J). Tissue effects evaluated with MRI and histology were compared to MRI-based temperature and thermal dose measurements, acoustic emissions recorded during the experiments, and acoustic and thermal simulations. Peak temperatures ranged from 46 to 57 °C, and lesions were produced in 5/8 sonicated targets. A linear relationship was observed between the applied acoustic energy and both the focal and brain surface heating. Thermal dose thresholds were 15-50 cumulative equivalent minutes at 43 °C, similar to prior studies at higher frequencies. Histology was also consistent with earlier studies of thermal effects in the brain. The system successfully controlled the power level and maintained a low level of cavitation activity. Increased acoustic emissions observed in 3/4 animals occurred when the focal temperature rise exceeded approximately 16 °C. Thresholds for thermally-significant subharmonic and wideband emissions were 129 and 140 W, respectively, corresponding to estimated pressure amplitudes of 2.1 and 2.2 MPa. Simulated focal heating was consistent with the measurements for sonications without thermally-significant acoustic emissions; otherwise it was consistently lower than the measurements. Overall, these results suggest that the lesions were produced by thermal mechanisms. The detected acoustic emissions, however, and their association with heating suggest that cavitation might have contributed to the focal heating. Compared to earlier work with a 670 kHz TcMRgFUS system, the brain surface heating was substantially reduced and the focal heating was higher with this 230 kHz system, suggesting that a reduced frequency can increase the treatment envelope for TcMRgFUS and potentially reduce the risk of skull heating.

Introduction

Purpose Transcranial ultrasound stimulation

Study Objective To evaluate thermal ablation and skull-induced heating using a 230 kHz transcranial MRI-guided focused ultrasound system in macaques and to assess whether cavitation (acoustic emissions) contributes to focal heating and lesion formation while comparing measurements to MRI-based thermal dose, acoustic recordings, and simulations.

Animal model / Human subject Macaques (4 total, 2 male, 2 female, 9.5-14kg)

Disease model healthy (nonhuman primates; no specific disease model)

MRI or image guidance method MRI-guided focused ultrasound (TcMRgFUS)

Targeted brain region(s) Thalamus

Target coordinates Not provided

Cargo name and characteristics Transcranial MRI-guided focused ultrasound (TcMRgFUS) — 230 kHz ultrasound system used for thermal ablation in nonhuman primates; delivered acoustic powers of 34–560 W (energies 896–7590 J) to thalamic targets, produced peak focal temperatures 46–57°C and lesions in some targets, monitored with MRI thermometry and real-time acoustic emission feedback (cavitation indicators: subharmonic and wideband emissions with thresholds ~129–140 W, estimated pressures ~2.1–2.2 MPa).

Route of administration None (no drug or cargo administered)

Outcomes and Safety

Summary of Outcomes Transcranial MR-guided focused ultrasound (230 kHz) produced focal thermal lesions in macaque thalamus (lesions in 5/8 targets) with peak focal temperatures of 46–57°C. Focal and brain-surface heating scaled linearly with applied acoustic energy; thermal dose thresholds for tissue damage were ~15–50 cumulative equivalent minutes at 43°C (CEM43). Histology matched expected thermal injury. The system maintained low cavitation overall, but increased acoustic emissions (subharmonic and wideband) were observed when focal temperature rise exceeded ~16°C (thresholds ~129–140 W, ~2.1–2.2 MPa), suggesting cavitation may have contributed to additional focal heating in some sonications. Compared with higher-frequency (670 kHz) systems, the 230 kHz system produced higher focal heating and substantially reduced brain-surface/skull heating, indicating an expanded treatment envelope and potentially lower skull-heating risk.

Duration of biological effect 15–50 cumulative equivalent minutes at 43°C

Safety-related matter Peak temperatures reached 46–57°C and lesions were produced in 5/8 sonicated targets; histology was consistent with thermal effects in the brain. Thermal dose thresholds were 15–50 cumulative equivalent minutes at 43°C. The system successfully controlled power and maintained a low level of cavitation activity, but increased acoustic emissions were observed in 3/4 animals when focal temperature rise exceeded ≈16°C; thresholds for thermally-significant subharmonic and wideband emissions were 129 W and 140 W (estimated pressures 2.1 and 2.2 MPa). Detected acoustic emissions and their association with heating suggest cavitation might have contributed to focal heating. Compared to a 670 kHz system, brain surface heating was substantially reduced and focal heating was higher with the 230 kHz system, suggesting a reduced frequency can increase the treatment envelope and potentially reduce the risk of skull heating.

Brain Region

Ultrasound Parameters

Ultrasound instrument 230 kHz transcranial MRI-guided focused ultrasound (TcMRgFUS) system

FUS Frequency 230 kHz; 670 kHz (earlier work)

FUS Intensity Acoustic power: 34–560 W (896–7590 J); Thermally-significant emission thresholds: 129 W (subharmonic), 140 W (wideband); Estimated pressure amplitudes: 2.1 MPa and 2.2 MPa; Frequency: 230 kHz

FUS Pressure 2.1 MPa and 2.2 MPa (estimated; thresholds corresponding to 129 W and 140 W)

FUS Mode continuous

Pulse duration Approximately 13.6–26.4 s

Duration of a single FUS session Sonication: 40-86 s

Focal Characteristics Focal width 3.0mm; lengrh: 5.8mm

Treatment frequency multiple sessions

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