Comparison of Piezoelectric and Optical Projection Imaging for Three-Dimensional In Vivo Photoacoustic Tomography

Comparison of Piezoelectric and Optical Projection Imaging for Three-Dimensional In Vivo Photoacoustic Tomography

Ultrasound sensor arrays for photoacoustic tomography (PAT) are investigated that create line projections of the pressure generated in an object by pulsed light illumination. Projections over a range of viewing angles enable the reconstruction of a three-dimensional image. Two line-integrating array...

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Bibliographic Details
Published in:Journal of imaging Vol. 5; no. 1; p. 15
Main Authors: Nuster, Robert, Paltauf, Günther
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 11-01-2019
MDPI
Subjects:
Acoustics
Arrays
Back propagation
Cameras
Delay time
Fluorides
Image reconstruction
in vivo imaging
In vivo methods and tests
Lasers
Optics
optoacoustic imaging
Phase contrast
Photoacoustic effect
photoacoustic imaging
piezoelectric polymer
Piezoelectricity
Polymer films
Pressure distribution
Projection
projection imaging
Radiation
Sensor arrays
Sensors
Three dimensional imaging
Tomography
Ultrasonic imaging
ultrasound array
piezoelectric polymer
in vivo imaging
optoacoustic imaging
projection imaging
photoacoustic imaging
ultrasound array
phase contrast
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Summary:Ultrasound sensor arrays for photoacoustic tomography (PAT) are investigated that create line projections of the pressure generated in an object by pulsed light illumination. Projections over a range of viewing angles enable the reconstruction of a three-dimensional image. Two line-integrating arrays are compared in this study for the in vivo imaging of vasculature, a piezoelectric array, and a camera-based setup that captures snapshots of the acoustic field emanating from the sample. An array consisting of 64 line-shaped sensors made of piezoelectric polymer film, which was arranged on a half-cylindrical area, was used to acquire spatiotemporal data from a human finger. The optical setup used phase contrast to visualize the acoustic field generated in the leg of a mouse after a selected delay time. Time-domain back projection and frequency-domain back propagation were used for image reconstruction from the piezoelectric and optical data, respectively. The comparison yielded an about threefold higher resolution for the optical setup and an about 13-fold higher sensitivity of the piezoelectric array. Due to the high density of data in the camera images, the optical technique gave images without streak artifacts, which were visible in the piezo array images due to the discrete detector positions. Overall, both detection concepts are suited for almost real-time projection imaging and three-dimensional imaging with a data acquisition time of less than a minute without averaging, which was limited by the repetition rate of the laser.
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ISSN:2313-433X
2313-433X
DOI:10.3390/jimaging5010015