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Main Authors: Gutierrez, Mario Ibrahin, Sellappan, Pathikumar, Penilla, Elias H., Poblete-Naredo, Irais, Vera, Arturo, Leija, Lorenzo, Garay, Javier E.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.13220
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author Gutierrez, Mario Ibrahin
Sellappan, Pathikumar
Penilla, Elias H.
Poblete-Naredo, Irais
Vera, Arturo
Leija, Lorenzo
Garay, Javier E.
author_facet Gutierrez, Mario Ibrahin
Sellappan, Pathikumar
Penilla, Elias H.
Poblete-Naredo, Irais
Vera, Arturo
Leija, Lorenzo
Garay, Javier E.
contents Therapeutic ultrasound for brain stimulation has increased in the last years. This energy has shown promising results for treating Alzheimers disease, Parkinsons disease, and traumatic brain injury, among other conditions. However, the application of ultrasound in the brain should trespass a natural but highly attenuating and distorting barrier, the cranium. Implantable ceramic materials can be used to replace part of the cranium as an alternate method to enhance ultrasound transmission. In this work, it is presented the acoustic characterization of alumina ceramic disks that can be employed as cranial implants for acoustic windows-to-the-brain. Alumina samples were prepared using current-activated pressure-assisted densification and were acoustically characterized. Acoustic impedance and attenuation of the samples were determined for different porosities. Additionally, measured and modeled acoustic fields are presented and analyzed in terms of the total ultrasound transmitted through the ceramics. Results indicate a resonant behavior in the alumina disks when the thickness corresponds to a half-wavelength of ultrasound; this resonance permits a total of 95.4% of ultrasound transmission; for thicknesses out of the resonant zone, transmission is 53.0%. Alumina proves to be an excellent medium for ultrasound transmission that, in conjunction with its mechanical and optical properties, can be useful for cranium replacement in mixed opto-acoustic applications.
format Preprint
id arxiv_https___arxiv_org_abs_2406_13220
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Acoustically Transparent Alumina-based Cranial Implants Enhance Ultrasound Transmission Through a Combined Mechano-Acoustic Resonant Effect
Gutierrez, Mario Ibrahin
Sellappan, Pathikumar
Penilla, Elias H.
Poblete-Naredo, Irais
Vera, Arturo
Leija, Lorenzo
Garay, Javier E.
Medical Physics
Materials Science
Therapeutic ultrasound for brain stimulation has increased in the last years. This energy has shown promising results for treating Alzheimers disease, Parkinsons disease, and traumatic brain injury, among other conditions. However, the application of ultrasound in the brain should trespass a natural but highly attenuating and distorting barrier, the cranium. Implantable ceramic materials can be used to replace part of the cranium as an alternate method to enhance ultrasound transmission. In this work, it is presented the acoustic characterization of alumina ceramic disks that can be employed as cranial implants for acoustic windows-to-the-brain. Alumina samples were prepared using current-activated pressure-assisted densification and were acoustically characterized. Acoustic impedance and attenuation of the samples were determined for different porosities. Additionally, measured and modeled acoustic fields are presented and analyzed in terms of the total ultrasound transmitted through the ceramics. Results indicate a resonant behavior in the alumina disks when the thickness corresponds to a half-wavelength of ultrasound; this resonance permits a total of 95.4% of ultrasound transmission; for thicknesses out of the resonant zone, transmission is 53.0%. Alumina proves to be an excellent medium for ultrasound transmission that, in conjunction with its mechanical and optical properties, can be useful for cranium replacement in mixed opto-acoustic applications.
title Acoustically Transparent Alumina-based Cranial Implants Enhance Ultrasound Transmission Through a Combined Mechano-Acoustic Resonant Effect
topic Medical Physics
Materials Science
url https://arxiv.org/abs/2406.13220