Title :
A 3-D High-Frequency Array Based 16 Channel Photoacoustic Microscopy System for In Vivo Micro-Vascular Imaging
Author :
Bitton, Rachel ; Zemp, Roger ; Yen, Jesse ; Wang, Lihong V. ; Shung, K. Kirk
Author_Institution :
Univ. of Southern California, Los Angeles, CA, USA
Abstract :
This paper discusses the design of a novel photoacoustic microscopy imaging system with promise for studying the structure of tissue microvasculature for applications in visualizing angiogenesis. A new 16 channel analog and digital high-frequency array based photoacoustic microscopy system (PAM) was developed using an Nd: YLF pumped tunable dye laser, a 30 MHz piezo composite linear array transducer, and a custom multichannel receiver electronics system. Using offline delay and sum beam- forming and beamsteering, phantom images were obtained from a 6 mum carbon fiber in water at a depth of 8 mm. The measured -6 dB lateral and axial spatial resolution of the system was 100 plusmn 5 mum and 45 plusmn 5 mum, respectively. The dynamic focusing capability of the system was demonstrated by imaging a composite carbon fiber matrix through a 12.5 mm imaging depth. Next, 2-D in vivo images were formed of vessels around 100 mum in diameter in the human hand. Three-dimensional in vivo images were also formed of micro-vessels 3 mm below the surface of the skin in two Sprague Dawley rats.
Keywords :
array signal processing; bioacoustics; biomedical electronics; biomedical transducers; blood vessels; carbon fibres; composite materials; dye lasers; laser applications in medicine; medical signal processing; photoacoustic effect; piezoelectric transducers; 2D in vivo images; 3D high frequency array; 3D in vivo images; Nd-YLF pumped tunable dye laser; Sprague Dawley rats; angiogenesis visualisation; beamforming; beamsteering; composite carbon fiber matrix; depth 12.5 mm; depth 3 mm; depth 8 mm; dynamic focusing capability; frequency 30 MHz; high frequency array based PAM system; in vivo microvascular imaging; multichannel receiver electronics system; offline delay; phantom images; photoacoustic microscopy system; piezocomposite linear array transducer; size 6 mum; tissue microvasculature structure; water immersed carbon fiber; Electron microscopy; Fiber lasers; In vivo; Laser excitation; Neodymium; Optical arrays; Pump lasers; Transducers; Tunable circuits and devices; Visualization; High-frequency ultrasound; multichannel receiver electronics; photoacoustic imaging; transducer array; Algorithms; Animals; Hand; Humans; Image Processing, Computer-Assisted; Microscopy, Acoustic; Microvessels; Phantoms, Imaging; Rats; Rats, Sprague-Dawley; Skin;
Journal_Title :
Medical Imaging, IEEE Transactions on
DOI :
10.1109/TMI.2008.2011899
