Literature DB >> 23743099

Creating brain lesions with low-intensity focused ultrasound with microbubbles: a rat study at half a megahertz.

Yuexi Huang1, Natalia I Vykhodtseva, Kullervo Hynynen.   

Abstract

Low-intensity focused ultrasound was applied with microbubbles (Definity, Lantheus Medical Imaging, North Billerica, MA, USA; 0.02 mL/kg) to produce brain lesions in 50 rats at 558 kHz. Burst sonications (burst length: 10 ms; pulse repetition frequency: 1 Hz; total exposure: 5 min; acoustic power: 0.47-1.3 W) generated ischemic or hemorrhagic lesions at the focal volume revealed by both magnetic resonance imaging and histology. Shorter burst time (2 ms) or shorter sonication time (1 min) reduced the probability of lesion production. Longer pulses (200 ms, 500 ms and continuous wave) caused significant near-field damage. Using microbubbles with focused ultrasound significantly reduced acoustic power levels and, therefore, avoided skull heating issues and potentially can extend the treatable volume of transcranial focused ultrasound to brain tissues close to the skull.
Copyright © 2013 World Federation for Ultrasound in Medicine & Biology. Published by Elsevier Inc. All rights reserved.

Entities:  

Keywords:  Brain lesion; Focused ultrasound; Hemorrhage; Microbubble; Transcranial ultrasound

Mesh:

Year:  2013        PMID: 23743099      PMCID: PMC4042243          DOI: 10.1016/j.ultrasmedbio.2013.03.006

Source DB:  PubMed          Journal:  Ultrasound Med Biol        ISSN: 0301-5629            Impact factor:   2.998


  53 in total

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2.  Spatiotemporal monitoring of high-intensity focused ultrasound therapy with passive acoustic mapping.

Authors:  Carl R Jensen; Robert W Ritchie; Miklós Gyöngy; James R T Collin; Tom Leslie; Constantin-C Coussios
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3.  Contrast-agent-enhanced ultrasound thermal ablation.

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4.  Magnetic resonance imaging of boiling induced by high intensity focused ultrasound.

Authors:  Tatiana D Khokhlova; Michael S Canney; Donghoon Lee; Kenneth I Marro; Lawrence A Crum; Vera A Khokhlova; Michael R Bailey
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5.  Simulations and measurements of transcranial low-frequency ultrasound therapy: skull-base heating and effective area of treatment.

Authors:  Aki Pulkkinen; Yuexi Huang; Junho Song; Kullervo Hynynen
Journal:  Phys Med Biol       Date:  2011-07-06       Impact factor: 3.609

6.  Ultrasound insertion loss of rat parietal bone appears to be proportional to animal mass at submegahertz frequencies.

Authors:  Meaghan A O'Reilly; Aidan Muller; Kullervo Hynynen
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7.  Influence of exposure time and pressure amplitude on blood-brain-barrier opening using transcranial ultrasound exposures.

Authors:  Rajiv Chopra; Natalia Vykhodtseva; Kullervo Hynynen
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8.  Transcranial magnetic resonance imaging- guided focused ultrasound surgery of brain tumors: initial findings in 3 patients.

Authors:  Nathan McDannold; Greg T Clement; Peter Black; Ferenc Jolesz; Kullervo Hynynen
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9.  Focused ultrasound for targeted delivery of siRNA and efficient knockdown of Htt expression.

Authors:  Alison Burgess; Yuexi Huang; William Querbes; Dinah W Sah; Kullervo Hynynen
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10.  An MRI-compatible system for focused ultrasound experiments in small animal models.

Authors:  Rajiv Chopra; Laura Curiel; Robert Staruch; Laetitia Morrison; Kullervo Hynynen
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  13 in total

1.  Experimental demonstration of passive acoustic imaging in the human skull cavity using CT-based aberration corrections.

Authors:  Ryan M Jones; Meaghan A O'Reilly; Kullervo Hynynen
Journal:  Med Phys       Date:  2015-07       Impact factor: 4.071

2.  Design of patient-specific focused ultrasound arrays for non-invasive brain therapy with increased trans-skull transmission and steering range.

Authors:  Alec Hughes; Kullervo Hynynen
Journal:  Phys Med Biol       Date:  2017-08-03       Impact factor: 3.609

3.  Intracranial Non-thermal Ablation Mediated by Transcranial Focused Ultrasound and Phase-Shift Nanoemulsions.

Authors:  Chenguang Peng; Tao Sun; Natalia Vykhodtseva; Chanikarn Power; Yongzhi Zhang; Nathan Mcdannold; Tyrone Porter
Journal:  Ultrasound Med Biol       Date:  2019-05-15       Impact factor: 2.998

Review 4.  Towards controlled drug delivery in brain tumors with microbubble-enhanced focused ultrasound.

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Journal:  Adv Drug Deliv Rev       Date:  2021-11-18       Impact factor: 15.470

5.  Cavitation-enhanced nonthermal ablation in deep brain targets: feasibility in a large animal model.

Authors:  Costas D Arvanitis; Natalia Vykhodtseva; Ferenc Jolesz; Margaret Livingstone; Nathan McDannold
Journal:  J Neurosurg       Date:  2015-09-18       Impact factor: 5.115

6.  Localised hyperthermia in rodent models using an MRI-compatible high-intensity focused ultrasound system.

Authors:  Chenchen Bing; Joris Nofiele; Robert Staruch; Michelle Ladouceur-Wodzak; Yonatan Chatzinoff; Ashish Ranjan; Rajiv Chopra
Journal:  Int J Hyperthermia       Date:  2015-11-05       Impact factor: 3.914

7.  Nonthermal ablation in the rat brain using focused ultrasound and an ultrasound contrast agent: long-term effects.

Authors:  Nathan McDannold; Yongzhi Zhang; Natalia Vykhodtseva
Journal:  J Neurosurg       Date:  2016-02-05       Impact factor: 5.115

8.  A High-Frequency Phased Array System for Transcranial Ultrasound Delivery in Small Animals.

Authors:  Saba Rahimi; Ryan Matthew Jones; Kullervo Hynynen
Journal:  IEEE Trans Ultrason Ferroelectr Freq Control       Date:  2020-12-23       Impact factor: 2.725

9.  Nonthermal ablation of deep brain targets: A simulation study on a large animal model.

Authors:  Can Barış Top; P Jason White; Nathan J McDannold
Journal:  Med Phys       Date:  2016-02       Impact factor: 4.071

10.  Three-dimensional transcranial microbubble imaging for guiding volumetric ultrasound-mediated blood-brain barrier opening.

Authors:  Ryan M Jones; Lulu Deng; Kogee Leung; Dallan McMahon; Meaghan A O'Reilly; Kullervo Hynynen
Journal:  Theranostics       Date:  2018-04-16       Impact factor: 11.556
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