Nonlinear Contrast Imaging with an Array-Based Micro-Ultrasound System

Abstract The main goal of this study was to determine the optimal strategy for a real-time nonlinear contrast mode for small-animal imaging at high frequencies, on a new array-based micro-ultrasound system. Previously reported contrast imaging at frequencies above 15 MHz has primarily relied on subt...

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Veröffentlicht in:	Ultrasound in medicine & biology 2010-12, Vol.36 (12), p.2097-2106
Hauptverfasser:	Needles, A, Arditi, M, Rognin, N.G, Mehi, J, Coulthard, T, Bilan-Tracey, C, Gaud, E, Frinking, P, Hirson, D, Foster, F.S
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal models Animals Biological and medical sciences Blood Blood perfusion Contrast Media Contrast media. Radiopharmaceuticals Contrast-enhanced ultrasound Data processing High frequency imaging Intravenous administration Inversion Kidney Kidney - diagnostic imaging Kinetics Medical sciences Mice Micro-ultrasound Microbubble Miniaturization Mouse Nonlinear microbubble detection Parametric imaging Perfusion Pharmacology. Drug treatments Radiology Renal Circulation Small animal Ultrasonics Ultrasonography - instrumentation Ultrasound
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container_title	Ultrasound in medicine & biology
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creator	Needles, A Arditi, M Rognin, N.G Mehi, J Coulthard, T Bilan-Tracey, C Gaud, E Frinking, P Hirson, D Foster, F.S
description	Abstract The main goal of this study was to determine the optimal strategy for a real-time nonlinear contrast mode for small-animal imaging at high frequencies, on a new array-based micro-ultrasound system. Previously reported contrast imaging at frequencies above 15 MHz has primarily relied on subtraction schemes involving B-mode image data. These approaches provide insufficient contrast to tissue ratios under many imaging conditions. In this work, pulse inversion, amplitude modulation and combinations of these were systematically investigated for the detection of nonlinear fundamental and subharmonic signal components to maximize contrast-to-tissue ratio (CTR) in the 18–24 MHz range. From in vitro and in vivo measurements, nonlinear fundamental detection with amplitude modulation provided optimal results, allowing an improvement in CTR of 13 dB compared with fundamental imaging. Based on this detection scheme, in vivo parametric images of murine kidneys were generated using sequences of nonlinear contrast images after intravenous bolus injections of microbubble suspensions. Initial parametric images of peak enhancement (PE), wash-in rate (WiR) and rise time (RT) are presented. The parametric images are indicative of blood perfusion kinetics, which, in the context of preclinical imaging with small animals, are anticipated to provide valuable insights into the progression of human disease models, where blood perfusion plays a critical role in either the diagnosis or treatment of the disease. (E-mail: aneedles@visualsonics.com )
doi_str_mv	10.1016/j.ultrasmedbio.2010.08.012
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Previously reported contrast imaging at frequencies above 15 MHz has primarily relied on subtraction schemes involving B-mode image data. These approaches provide insufficient contrast to tissue ratios under many imaging conditions. In this work, pulse inversion, amplitude modulation and combinations of these were systematically investigated for the detection of nonlinear fundamental and subharmonic signal components to maximize contrast-to-tissue ratio (CTR) in the 18–24 MHz range. From in vitro and in vivo measurements, nonlinear fundamental detection with amplitude modulation provided optimal results, allowing an improvement in CTR of 13 dB compared with fundamental imaging. Based on this detection scheme, in vivo parametric images of murine kidneys were generated using sequences of nonlinear contrast images after intravenous bolus injections of microbubble suspensions. Initial parametric images of peak enhancement (PE), wash-in rate (WiR) and rise time (RT) are presented. The parametric images are indicative of blood perfusion kinetics, which, in the context of preclinical imaging with small animals, are anticipated to provide valuable insights into the progression of human disease models, where blood perfusion plays a critical role in either the diagnosis or treatment of the disease. (E-mail: aneedles@visualsonics.com )</description><subject>Animal models</subject><subject>Animals</subject><subject>Biological and medical sciences</subject><subject>Blood</subject><subject>Blood perfusion</subject><subject>Contrast Media</subject><subject>Contrast media. Radiopharmaceuticals</subject><subject>Contrast-enhanced ultrasound</subject><subject>Data processing</subject><subject>High frequency</subject><subject>imaging</subject><subject>Intravenous administration</subject><subject>Inversion</subject><subject>Kidney</subject><subject>Kidney - diagnostic imaging</subject><subject>Kinetics</subject><subject>Medical sciences</subject><subject>Mice</subject><subject>Micro-ultrasound</subject><subject>Microbubble</subject><subject>Miniaturization</subject><subject>Mouse</subject><subject>Nonlinear microbubble detection</subject><subject>Parametric imaging</subject><subject>Perfusion</subject><subject>Pharmacology. 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Radiopharmaceuticals</topic><topic>Contrast-enhanced ultrasound</topic><topic>Data processing</topic><topic>High frequency</topic><topic>imaging</topic><topic>Intravenous administration</topic><topic>Inversion</topic><topic>Kidney</topic><topic>Kidney - diagnostic imaging</topic><topic>Kinetics</topic><topic>Medical sciences</topic><topic>Mice</topic><topic>Micro-ultrasound</topic><topic>Microbubble</topic><topic>Miniaturization</topic><topic>Mouse</topic><topic>Nonlinear microbubble detection</topic><topic>Parametric imaging</topic><topic>Perfusion</topic><topic>Pharmacology. 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Previously reported contrast imaging at frequencies above 15 MHz has primarily relied on subtraction schemes involving B-mode image data. These approaches provide insufficient contrast to tissue ratios under many imaging conditions. In this work, pulse inversion, amplitude modulation and combinations of these were systematically investigated for the detection of nonlinear fundamental and subharmonic signal components to maximize contrast-to-tissue ratio (CTR) in the 18–24 MHz range. From in vitro and in vivo measurements, nonlinear fundamental detection with amplitude modulation provided optimal results, allowing an improvement in CTR of 13 dB compared with fundamental imaging. Based on this detection scheme, in vivo parametric images of murine kidneys were generated using sequences of nonlinear contrast images after intravenous bolus injections of microbubble suspensions. Initial parametric images of peak enhancement (PE), wash-in rate (WiR) and rise time (RT) are presented. 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subjects	Animal models Animals Biological and medical sciences Blood Blood perfusion Contrast Media Contrast media. Radiopharmaceuticals Contrast-enhanced ultrasound Data processing High frequency imaging Intravenous administration Inversion Kidney Kidney - diagnostic imaging Kinetics Medical sciences Mice Micro-ultrasound Microbubble Miniaturization Mouse Nonlinear microbubble detection Parametric imaging Perfusion Pharmacology. Drug treatments Radiology Renal Circulation Small animal Ultrasonics Ultrasonography - instrumentation Ultrasound
title	Nonlinear Contrast Imaging with an Array-Based Micro-Ultrasound System
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