Transducer modeling for accurate acoustic simulations of transcranial focused ultrasound stimulation

Pasquinelli, Cristina; Montanaro, Hazael; Lee, Hyunjoo J; Hanson, Lars G.; Kim, Hyung Kook; Kuster, Niels; Siebner, Hartwig R.; Neufeld, Esra; Thielscher, Axel

doi:10.1088/1741-2552/ab98dc

Cited by 20 publications

(27 citation statements)

References 44 publications

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“…S11, Table S4), and the wave mechanics within and without the cranial cavity require more extensive numerical modeling, simulations, and preliminary human trials. A complete acoustic model for human skull simulations does not yet exist as far as we know, and research on clinical ultrasound stimulation generally rely on partial ex-vivo skull samples and numerical simulations for accurate targeting through the cranial barrier [43,54,55]. Thus, while the concept of our system can theoretically be modified for clinical applications, significant preliminary experiments and simulations with excised skull samples would be required.…”

Section: Discussionmentioning

confidence: 99%

“…As a preliminary study, the clinical applicability of our dualcrossed transducer concept was tested with high fidelity acoustic simulations on five human head models using the Sim4Life (ZMT Zurich MedTech AG, Zurich, Switzerland) software, as described in Refs. [43,44]. We modeled the transducer as a single curved element focused transducer with a radius of curvature of 85 mm and an aperture width of 50 mm, working at a center frequency of 500 kHz, which resulted in an elliptical beam of 42 mm by 5 mm in a water background.…”

Section: Human Skull Simulationsmentioning

confidence: 99%

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Transcranial focused ultrasound stimulation with high spatial resolution

Kim

Kook

et al. 2021

Brain Stimulation

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Background: Low-intensity transcranial focused ultrasound stimulation is a promising candidate for noninvasive brain stimulation and accurate targeting of brain circuits because of its focusing capability and long penetration depth. However, achieving a sufficiently high spatial resolution to target small animal sub-regions is still challenging, especially in the axial direction. Objective: To achieve high axial resolution, we designed a dual-crossed transducer system that achieved high spatial resolution in the axial direction without complex microfabrication, beamforming circuitry, and signal processing. Methods: High axial resolution was achieved by crossing two ultrasound beams of commercially available piezoelectric curved transducers at the focal length of each transducer. After implementation of the fixture for the dual-crossed transducer system, three sets of in vivo animal experiments were conducted to demonstrate high target specificity of ultrasound neuromodulation using the dual-crossed transducer system (n ¼ 38). Results: The full-width at half maximum (FWHM) focal volume of our dual-crossed transducer system was under 0.52 mm 3 . We report a focal diameter in both lateral and axial directions of 1 mm. To demonstrate successful in vivo brain stimulation of wild-type mice, we observed the movement of the forepaws. In addition, we targeted the habenula and verified the high spatial specificity of our dualcrossed transducer system. Conclusions: Our results demonstrate the ability of the dual-crossed transducer system to target highly specific regions of mice brains using ultrasound stimulation. The proposed system is a valuable tool to study the complex neurological circuitry of the brain noninvasively.

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Section: Discussionmentioning

confidence: 99%

Section: Human Skull Simulationsmentioning

confidence: 99%

Transcranial focused ultrasound stimulation with high spatial resolution

Kim

Kook

et al. 2021

Brain Stimulation

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“…Results can be recorded as phasors (at the base frequency and, if relevant, higher harmonics) or transient 3 + 1D fields, and the solver has been verified and validated, 73 also for transcranial focused ultrasound modeling. 74,75 The original hard sources (imposed pressure; sinusoidal with rise-time, or user-defined transient profiles) were extended for the purpose of this work by soft sources (cosine function to avoid slowly decaying low frequency components).…”

Section: K Sim4lifementioning

confidence: 99%

Benchmark problems for transcranial ultrasound simulation: Intercomparison of compressional wave models

Aubry¹,

Bates²,

Boehm³

et al. 2022

Preprint

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“…Depending on the employed physical model, either given pressures or displacements or velocities are applied, which are not equivalent and complicate comparison. Furthermore, it can be important to model the internal structure of transducers [86], which often contain impedance matching and lens elements and can be affected by mechanical factors, such as fixation and friction.…”

Section: Source Modelingmentioning

confidence: 99%

ESHO benchmarks for computational modeling and optimization in hyperthermia therapy

Paulides

Rodrigues

Bellizzi

et al. 2021

International Journal of Hyperthermia

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Background: The success of cancer hyperthermia (HT) treatments is strongly dependent on the temperatures achieved in the tumor and healthy tissues as it correlates with treatment efficacy and safety, respectively. Hyperthermia treatment planning (HTP) simulations have become pivotal for treatment optimization due to the possibility for pretreatment planning, optimization and decision making, as well as real-time treatment guidance. Materials and methods: The same computational methods deployed in HTP are also used for in silico studies. These are of great relevance for the development of new HT devices and treatment approaches. To aid this work, 3 D patient models have been recently developed and made available for the HT community. Unfortunately, there is no consensus regarding tissue properties, simulation settings, and benchmark applicators, which significantly influence the clinical relevance of computational outcomes. Results and discussion: Herein, we propose a comprehensive set of applicator benchmarks, efficacy and safety optimization algorithms, simulation settings and clinical parameters, to establish benchmarks for method comparison and code verification, to provide guidance, and in view of the 2021 ESHO Grand Challenge (Details on the ESHO grand challenge on HTP will be provided at https://www. esho.info/). Conclusion:We aim to establish guidelines to promote standardization within the hyperthermia community such that novel approaches can quickly prove their benefit as quickly as possible in clinically relevant simulation scenarios. This paper is primarily focused on radiofrequency and microwave hyperthermia but, since 3 D simulation studies on heating with ultrasound are now a reality, guidance as well as a benchmark for ultrasound-based hyperthermia are also included.

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Transducer modeling for accurate acoustic simulations of transcranial focused ultrasound stimulation

Cited by 20 publications

References 44 publications

Transcranial focused ultrasound stimulation with high spatial resolution

Transcranial focused ultrasound stimulation with high spatial resolution

Benchmark problems for transcranial ultrasound simulation: Intercomparison of compressional wave models

ESHO benchmarks for computational modeling and optimization in hyperthermia therapy

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