Design of a High Frequency Array Based Photoacoustic Microscopy System for Micro-Vascular Imaging

The rapidly expanding field of photoacoustic imaging includes a technique called photoacoustic microscopy. Photoacoustic microscopy is a hybrid imaging modality with sub-millimeter resolution that possesses the contrast benefit of optical imaging and the resolution benefit of ultrasonic imaging. Thi...

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Hauptverfasser:	Bitton, R., Zemp, R., Yen, J., Wang, L.H., Shung, K.K.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Animals Biological tissues Carbon - chemistry Equipment Design Frequency Hand - pathology High-resolution imaging Humans Image Enhancement Image resolution Laser excitation Lasers Microcirculation - pathology Microscopy, Acoustic - instrumentation Microscopy, Acoustic - methods Models, Statistical Optical arrays Optical imaging Optical microscopy Rats Rats, Sprague-Dawley Skin - pathology Tomography, Optical - instrumentation Tomography, Optical - methods Tunable circuits and devices Ultrasonic imaging Ultrasonography - instrumentation Ultrasonography - methods
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creator	Bitton, R. Zemp, R. Yen, J. Wang, L.H. Shung, K.K.
description	The rapidly expanding field of photoacoustic imaging includes a technique called photoacoustic microscopy. Photoacoustic microscopy is a hybrid imaging modality with sub-millimeter resolution that possesses the contrast benefit of optical imaging and the resolution benefit of ultrasonic imaging. This technique can be used to image the structure and dynamics of microvessels involved in angiogenesis within biological tissue. In this paper we present results of a new high frequency array based photoacoustic microscopy system (PAM) using an Nd:YLF pumped tunable dye laser, a 30 MHz piezo composite linear array and a custom multi-channel receiver system. Using offline delay and sum beamforming and beamsteering, phantom images were obtained from a 6 mum carbon fiber in water at a depth of 8 mm. The measured axial and lateral spatial resolution of the system was 103 plusmn 5 mum and 45+5 mum, respectively. In vivo B-scans were obtained from vessels within a human hand as well as 3D photoacoustic images of vessels 3 mm below the skin surface in a Sprague Dawley Rat.
doi_str_mv	10.1109/IEMBS.2007.4352754
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Photoacoustic microscopy is a hybrid imaging modality with sub-millimeter resolution that possesses the contrast benefit of optical imaging and the resolution benefit of ultrasonic imaging. This technique can be used to image the structure and dynamics of microvessels involved in angiogenesis within biological tissue. In this paper we present results of a new high frequency array based photoacoustic microscopy system (PAM) using an Nd:YLF pumped tunable dye laser, a 30 MHz piezo composite linear array and a custom multi-channel receiver system. Using offline delay and sum beamforming and beamsteering, phantom images were obtained from a 6 mum carbon fiber in water at a depth of 8 mm. The measured axial and lateral spatial resolution of the system was 103 plusmn 5 mum and 45+5 mum, respectively. 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subjects	Animals Biological tissues Carbon - chemistry Equipment Design Frequency Hand - pathology High-resolution imaging Humans Image Enhancement Image resolution Laser excitation Lasers Microcirculation - pathology Microscopy, Acoustic - instrumentation Microscopy, Acoustic - methods Models, Statistical Optical arrays Optical imaging Optical microscopy Rats Rats, Sprague-Dawley Skin - pathology Tomography, Optical - instrumentation Tomography, Optical - methods Tunable circuits and devices Ultrasonic imaging Ultrasonography - instrumentation Ultrasonography - methods
title	Design of a High Frequency Array Based Photoacoustic Microscopy System for Micro-Vascular Imaging
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