Bypassing absorbing objects in focused ultrasound using computer generated holographic technique

Purpose: Focused ultrasound (FUS) technology is based on heating a small volume of tissue, while keeping the temperature outside the focus region with minimal heating only. Several FUS applications, such as brain and liver, suffer from the existence of ultrasound absorbers in the acoustic path betwe...

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Veröffentlicht in:	Medical physics (Lancaster) 2011-12, Vol.38 (12), p.6407-6415
Hauptverfasser:	Hertzberg, Y., Navon, G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustic pattern recognition Acoustic transducers biological tissues Biomedical instrumentation and transducers, including micro‐electro‐mechanical systems (MEMS) biomedical transducers brain Cell processes cellular biophysics Computer‐generated holograms computer‐generated holography fast Fourier transforms Focal points focused ultrasound therapy High-Energy Shock Waves Holography Holography - methods Imaging, Three-Dimensional - methods iterative methods liver medical image processing Medical imaging MRI neurophysiology Numerical approximation and analysis phase aberration Sound pressure Surgery, Computer-Assisted - instrumentation Temperature measurement Therapeutic applications Transducers Ultrasonic Surgical Procedures - methods ultrasonic therapy Ultrasonic transducers Ultrasonics Ultrasonography ultrasound holograms ultrasound phased-array
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description	Purpose: Focused ultrasound (FUS) technology is based on heating a small volume of tissue, while keeping the temperature outside the focus region with minimal heating only. Several FUS applications, such as brain and liver, suffer from the existence of ultrasound absorbers in the acoustic path between the transducer and the focus. These absorbers are a potential risk for the FUS therapy since they might cause to unwanted heating outside the focus region. An acoustic simulation based solution for reducing absorbers’ heating is proposed, demonstrated, and compared to the standard geometrical solution. The proposed solution uses 3D continuous acoustic holograms, generated by the Gerchberg–Saxton (GS) algorithm, which are described and demonstrated for the first time using ultrasound planar phased-array transducer. Methods: Holograms were generated using the iterative GS algorithm and fast Fourier transform (FFT) acoustic simulation. The performances of the holograms are demonstrated by temperature elevation images of the absorber, acquired by GE 1.5T MRI scanner equipped with InSightec FUS planar phased-array transducer built out of 986 transmitting elements. Results: The acoustic holographic technology is demonstrated numerically and experimentally using the three letters patterns, “T,” “A,” and “U,” which were manually built into 1 × 1 cm masks to represent the requested target fields. 3D holograms of a focused ultrasound field with a hole in intensity at the absorber region were generated and compared to the standard geometrical solution. The proposed holographic solution results in 76% reduction of heating on absorber, while keeping similar heating at the focus. Conclusions: In the present work we show for the first time the generation of efficient and uniform continuous ultrasound holograms in 3D. We use the holographic technology to generate a FUS beams that bypasses an absorber in the acoustic path to reduce unnecessary heating and potential clinical risk. The developed technique is superior in performance and flexibility compared to the intuitive geometrical technique that is being used in clinical practice.
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Several FUS applications, such as brain and liver, suffer from the existence of ultrasound absorbers in the acoustic path between the transducer and the focus. These absorbers are a potential risk for the FUS therapy since they might cause to unwanted heating outside the focus region. An acoustic simulation based solution for reducing absorbers’ heating is proposed, demonstrated, and compared to the standard geometrical solution. The proposed solution uses 3D continuous acoustic holograms, generated by the Gerchberg–Saxton (GS) algorithm, which are described and demonstrated for the first time using ultrasound planar phased-array transducer. Methods: Holograms were generated using the iterative GS algorithm and fast Fourier transform (FFT) acoustic simulation. The performances of the holograms are demonstrated by temperature elevation images of the absorber, acquired by GE 1.5T MRI scanner equipped with InSightec FUS planar phased-array transducer built out of 986 transmitting elements. Results: The acoustic holographic technology is demonstrated numerically and experimentally using the three letters patterns, “T,” “A,” and “U,” which were manually built into 1 × 1 cm masks to represent the requested target fields. 3D holograms of a focused ultrasound field with a hole in intensity at the absorber region were generated and compared to the standard geometrical solution. The proposed holographic solution results in 76% reduction of heating on absorber, while keeping similar heating at the focus. Conclusions: In the present work we show for the first time the generation of efficient and uniform continuous ultrasound holograms in 3D. We use the holographic technology to generate a FUS beams that bypasses an absorber in the acoustic path to reduce unnecessary heating and potential clinical risk. 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Several FUS applications, such as brain and liver, suffer from the existence of ultrasound absorbers in the acoustic path between the transducer and the focus. These absorbers are a potential risk for the FUS therapy since they might cause to unwanted heating outside the focus region. An acoustic simulation based solution for reducing absorbers’ heating is proposed, demonstrated, and compared to the standard geometrical solution. The proposed solution uses 3D continuous acoustic holograms, generated by the Gerchberg–Saxton (GS) algorithm, which are described and demonstrated for the first time using ultrasound planar phased-array transducer. Methods: Holograms were generated using the iterative GS algorithm and fast Fourier transform (FFT) acoustic simulation. The performances of the holograms are demonstrated by temperature elevation images of the absorber, acquired by GE 1.5T MRI scanner equipped with InSightec FUS planar phased-array transducer built out of 986 transmitting elements. Results: The acoustic holographic technology is demonstrated numerically and experimentally using the three letters patterns, “T,” “A,” and “U,” which were manually built into 1 × 1 cm masks to represent the requested target fields. 3D holograms of a focused ultrasound field with a hole in intensity at the absorber region were generated and compared to the standard geometrical solution. The proposed holographic solution results in 76% reduction of heating on absorber, while keeping similar heating at the focus. Conclusions: In the present work we show for the first time the generation of efficient and uniform continuous ultrasound holograms in 3D. We use the holographic technology to generate a FUS beams that bypasses an absorber in the acoustic path to reduce unnecessary heating and potential clinical risk. The developed technique is superior in performance and flexibility compared to the intuitive geometrical technique that is being used in clinical practice.</description><subject>Acoustic pattern recognition</subject><subject>Acoustic transducers</subject><subject>biological tissues</subject><subject>Biomedical instrumentation and transducers, including micro‐electro‐mechanical systems (MEMS)</subject><subject>biomedical transducers</subject><subject>brain</subject><subject>Cell processes</subject><subject>cellular biophysics</subject><subject>Computer‐generated holograms</subject><subject>computer‐generated holography</subject><subject>fast Fourier transforms</subject><subject>Focal points</subject><subject>focused ultrasound therapy</subject><subject>High-Energy Shock Waves</subject><subject>Holography</subject><subject>Holography - methods</subject><subject>Imaging, Three-Dimensional - methods</subject><subject>iterative methods</subject><subject>liver</subject><subject>medical image processing</subject><subject>Medical imaging</subject><subject>MRI</subject><subject>neurophysiology</subject><subject>Numerical approximation and analysis</subject><subject>phase aberration</subject><subject>Sound pressure</subject><subject>Surgery, Computer-Assisted - instrumentation</subject><subject>Temperature measurement</subject><subject>Therapeutic applications</subject><subject>Transducers</subject><subject>Ultrasonic Surgical Procedures - methods</subject><subject>ultrasonic therapy</subject><subject>Ultrasonic transducers</subject><subject>Ultrasonics</subject><subject>Ultrasonography</subject><subject>ultrasound holograms</subject><subject>ultrasound phased-array</subject><issn>0094-2405</issn><issn>2473-4209</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2011</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNp9kUtPwzAQhC0EglI48AdQbgikgF9x6gMHQLwkEBx6N7Zjt0ZpHOwE1H-PoaVCQuW0e_hmVjsDwAGCpwih0Rk6JaxAlNENMMC0JDnFkG-CAYSc5pjCYgfsxvgKIWSkgNtgB2NE-QjTAXi5nLcyRtdMMqmiD-pr8-rV6C5mrsms1300VdbXXZDR901av2ntZ23fmZBNTGOC7BIz9bWfBNlOnc46o6eNe-vNHtiyso5mfzmHYHxzPb66yx-ebu-vLh5yXSBM81ITS7mVtMRcVZIoKwvCRliXEjFCCWeswAlSDBouixJhhVkFKYcWK8vIEBwtbNvg09XYiZmL2tS1bIzvo-AI8fQ7w4k8XpA6-BiDsaINbibDXCAovuIUSCzjTOzh0rVXM1OtyJ_8EpAvgA9Xm_l6J_H4vDQ8X_BRu052zjfrNatmxKqZpD9Zp3_34de9trL_wX9f_QSRCa9z</recordid><startdate>201112</startdate><enddate>201112</enddate><creator>Hertzberg, Y.</creator><creator>Navon, G.</creator><general>American Association of Physicists in Medicine</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope></search><sort><creationdate>201112</creationdate><title>Bypassing absorbing objects in focused ultrasound using computer generated holographic technique</title><author>Hertzberg, Y. ; Navon, G.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c5124-7c3f49fa4729bda3bfa53682c7a16343966527c3b60e9a5712b26d0490f2bf63</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2011</creationdate><topic>Acoustic pattern recognition</topic><topic>Acoustic transducers</topic><topic>biological tissues</topic><topic>Biomedical instrumentation and transducers, including micro‐electro‐mechanical systems (MEMS)</topic><topic>biomedical transducers</topic><topic>brain</topic><topic>Cell processes</topic><topic>cellular biophysics</topic><topic>Computer‐generated holograms</topic><topic>computer‐generated holography</topic><topic>fast Fourier transforms</topic><topic>Focal points</topic><topic>focused ultrasound therapy</topic><topic>High-Energy Shock Waves</topic><topic>Holography</topic><topic>Holography - methods</topic><topic>Imaging, Three-Dimensional - methods</topic><topic>iterative methods</topic><topic>liver</topic><topic>medical image processing</topic><topic>Medical imaging</topic><topic>MRI</topic><topic>neurophysiology</topic><topic>Numerical approximation and analysis</topic><topic>phase aberration</topic><topic>Sound pressure</topic><topic>Surgery, Computer-Assisted - instrumentation</topic><topic>Temperature measurement</topic><topic>Therapeutic applications</topic><topic>Transducers</topic><topic>Ultrasonic Surgical Procedures - methods</topic><topic>ultrasonic therapy</topic><topic>Ultrasonic transducers</topic><topic>Ultrasonics</topic><topic>Ultrasonography</topic><topic>ultrasound holograms</topic><topic>ultrasound phased-array</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Hertzberg, Y.</creatorcontrib><creatorcontrib>Navon, G.</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><jtitle>Medical physics (Lancaster)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Hertzberg, Y.</au><au>Navon, G.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Bypassing absorbing objects in focused ultrasound using computer generated holographic technique</atitle><jtitle>Medical physics (Lancaster)</jtitle><addtitle>Med Phys</addtitle><date>2011-12</date><risdate>2011</risdate><volume>38</volume><issue>12</issue><spage>6407</spage><epage>6415</epage><pages>6407-6415</pages><issn>0094-2405</issn><eissn>2473-4209</eissn><coden>MPHYA6</coden><abstract>Purpose: Focused ultrasound (FUS) technology is based on heating a small volume of tissue, while keeping the temperature outside the focus region with minimal heating only. Several FUS applications, such as brain and liver, suffer from the existence of ultrasound absorbers in the acoustic path between the transducer and the focus. These absorbers are a potential risk for the FUS therapy since they might cause to unwanted heating outside the focus region. An acoustic simulation based solution for reducing absorbers’ heating is proposed, demonstrated, and compared to the standard geometrical solution. The proposed solution uses 3D continuous acoustic holograms, generated by the Gerchberg–Saxton (GS) algorithm, which are described and demonstrated for the first time using ultrasound planar phased-array transducer. Methods: Holograms were generated using the iterative GS algorithm and fast Fourier transform (FFT) acoustic simulation. The performances of the holograms are demonstrated by temperature elevation images of the absorber, acquired by GE 1.5T MRI scanner equipped with InSightec FUS planar phased-array transducer built out of 986 transmitting elements. Results: The acoustic holographic technology is demonstrated numerically and experimentally using the three letters patterns, “T,” “A,” and “U,” which were manually built into 1 × 1 cm masks to represent the requested target fields. 3D holograms of a focused ultrasound field with a hole in intensity at the absorber region were generated and compared to the standard geometrical solution. The proposed holographic solution results in 76% reduction of heating on absorber, while keeping similar heating at the focus. Conclusions: In the present work we show for the first time the generation of efficient and uniform continuous ultrasound holograms in 3D. We use the holographic technology to generate a FUS beams that bypasses an absorber in the acoustic path to reduce unnecessary heating and potential clinical risk. The developed technique is superior in performance and flexibility compared to the intuitive geometrical technique that is being used in clinical practice.</abstract><cop>United States</cop><pub>American Association of Physicists in Medicine</pub><pmid>22149824</pmid><doi>10.1118/1.3651464</doi><tpages>9</tpages></addata></record>
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subjects	Acoustic pattern recognition Acoustic transducers biological tissues Biomedical instrumentation and transducers, including micro‐electro‐mechanical systems (MEMS) biomedical transducers brain Cell processes cellular biophysics Computer‐generated holograms computer‐generated holography fast Fourier transforms Focal points focused ultrasound therapy High-Energy Shock Waves Holography Holography - methods Imaging, Three-Dimensional - methods iterative methods liver medical image processing Medical imaging MRI neurophysiology Numerical approximation and analysis phase aberration Sound pressure Surgery, Computer-Assisted - instrumentation Temperature measurement Therapeutic applications Transducers Ultrasonic Surgical Procedures - methods ultrasonic therapy Ultrasonic transducers Ultrasonics Ultrasonography ultrasound holograms ultrasound phased-array
title	Bypassing absorbing objects in focused ultrasound using computer generated holographic technique
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