A dual-mode hemispherical sparse array for three-dimensional passive acoustic mapping and skull localization within a clinical MRI guided focused ultrasound device

Previous work has demonstrated that passive acoustic imaging may be used alongside MRI for monitoring of focused ultrasound therapy. However, past implementations have generally made use of either linear arrays originally designed for diagnostic imaging or custom narrowband arrays specific to in-house therapeutic transducer designs, neither of which is fully compatible with clinical MR-guided focused ultrasound devices. Here we have designed an array which is suitable for use within an FDA-approved MR-guided transcranial focused ultrasound device, within the bore of a 3 Tesla clinical MRI scanner. The array is constructed from 5 × 0.4 mm piezoceramic disc elements arranged in pseudorandom fashion on a low-profile laser-cut acrylic frame designed to fit between the therapeutic elements of a 230 kHz InSightec ExAblate 4000 transducer. By exploiting thickness and radial resonance modes of the piezo discs the array is capable of both B-mode imaging at 5 MHz for skull localization, as well as passive reception at the second harmonic of the therapy array for detection of cavitation and three-dimensional passive acoustic imaging. In active mode, the array was able to perform B-mode imaging of a human skull, showing the outer skull surface with good qualitative agreement with MR imaging. Extension to 3D showed the array was able to locate the skull within ±2mm/2° of reference points derived from MRI, which could potentially allow registration of a patient to the therapy system without the expense of real-time MRI. In passive mode, the array was able to resolve a point source in 3D within a ±10mm region about each axis from the focus, detect cavitation (SNR ~12dB) at burst lengths from 10 cycles to continuous wave, and produce 3D acoustic maps in a flow phantom. Finally, the array was used to detect and map cavitation associated with microbubble activity in the brain in nonhuman primates. the array was able to perform B-mode imaging and 3D localization of a human skull with close agreement to MR imaging. In passive mode, the array was able to locate a point source in 3D, produce 3-dimensional passive acoustic maps of cavitation in a flow phantom, and detect cavitation associated with microbubble activity in the brain in nonhuman primates. These results demonstrate a dual-mode array which is compatible with a clinical MRgFUS device and suggests such a device could be useful for planning, monitoring and assessment of cavitation-enhanced transcranial focused ultrasound therapy.

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