A simulation study on the sensitivity of transcranial ray-tracing ultrasound modeling to skull properties

In transcranial focused ultrasound therapies, such as treating essential tremor via thermal ablation in the thalamus, acoustic energy is focused through the skull using a phased-array transducer. Ray tracing is a computationally efficient method that can correct skull-induced phase aberrations via p...

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Veröffentlicht in:	The Journal of the Acoustical Society of America 2023-08, Vol.154 (2), p.1211-1225
Hauptverfasser:	Drainville, Robert Andrew, Chatillon, Sylvain, Moore, David, Snell, John, Padilla, Frederic, Lafon, Cyril
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Sprache:	eng
Schlagworte:	Computer Science Mathematical Physics Modeling and Simulation Physics
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creator	Drainville, Robert Andrew Chatillon, Sylvain Moore, David Snell, John Padilla, Frederic Lafon, Cyril
description	In transcranial focused ultrasound therapies, such as treating essential tremor via thermal ablation in the thalamus, acoustic energy is focused through the skull using a phased-array transducer. Ray tracing is a computationally efficient method that can correct skull-induced phase aberrations via per-element phase delay calculations using patient-specific computed tomography (CT) data. However, recent studies show that variations in CT-derived Hounsfield unit may account for only 50% of the speed of sound variability in human skull specimens, potentially limiting clinical transcranial ultrasound applications. Therefore, understanding the sensitivity of treatment planning methods to material parameter variations is essential. The present work uses a ray-tracing simulation model to explore how imprecision in model inputs, arising from clinically significant uncertainties in skull properties or considerations of acoustic phenomena, affects acoustic focusing quality through the skull. We propose and validate new methods to optimize ray-tracing skull simulations for clinical treatment planning, relevant for predicting intracranial target's thermal rise, using experimental data from ex-vivo human skulls.
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subjects	Computer Science Mathematical Physics Modeling and Simulation Physics
title	A simulation study on the sensitivity of transcranial ray-tracing ultrasound modeling to skull properties
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