Abstract:
The prototype of a high-resolution PET (positron emission tomography) camera consisting of two opposite arrays of detectors with independent solid-state readout was built...Show MoreMetadata
Abstract:
The prototype of a high-resolution PET (positron emission tomography) camera consisting of two opposite arrays of detectors with independent solid-state readout was built and tested. The basic detector unit is the RCA C30994 detector module consisting of two 3-mm*5-mm*20-mm BGO scintillators, each coupled to one silicon avalanche photodiode. The two-dimensional stacking capability of the module allows a high-resolution multiring detection system to be assembled without crystal coding. The prototype was used to simulate a 31-cm-diameter dual ring tomograph suitable for animal studies. Coincident detector pair resolution was measured, and the contributions to resolution loss were estimated using a platinum-sheathed 0.75 mm /sup 68/Ge line source. The intrinsic resolution is 1.9 mm FWHM (full width at half maximum), 3.5 mm FWTM at the center of the field. The reconstructed point spread function resolution in a stationary mode is 2.3 mm FWHM at the center and 3.1 mm FWHM (tangential), 3.9 mm FWHM (radial) 5 cm from the center. The axial resolution is less than 3.5 mm FWHM throughout the field. The ring sensitivity for an animal system is 67 kcps/mCi in air for an axial line source and 3.3 kcps/ mu Ci/ml for a 10-cm-diameter cylinder of /sup 22/Na solution.<>
Published in: IEEE Transactions on Nuclear Science ( Volume: 37, Issue: 2, April 1990)
DOI: 10.1109/23.106719
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1.
A. W. Lightstone, R. J. McIntyre, R. Lecomte and D. Schmitt, "A bismuth germanate-avalanche photodiode module designed for used in high resolution positron emission tomography", IEEE Trans. Nucl. Sci., vol. NS-33, pp. 456-459, 1986.
2.
R. Lecomte, C. Martel and C. Carrier, "Status of BGO-avalanche photodiode detectors for spectroscopic and timing measurements", Nucl. Instrum. & Meth. Phys. Res., vol. A278, pp. 585-597, 1989.
3.
D. Schmitt, R. Lecomte, M. Lapointe, C. Martel, C. Carrier, B. Karuta, et al., "Ultra-low noise charge sensitive preamplifier for scintillation detection with avalanche photodiode in PET applications", IEEE Trans. Nucl. Sci., vol. NS-34, pp. 91-96, 1987.
4.
G. A. Petrillo, R. J. McIntyre, R. Lecomte, G. Lamoureux and D. Schmitt, "Scintillation detection with large-area reach-through avalanche photodiodes", IEEE Trans. Nucl. Sci., vol. NS-31, pp. 417-423, 1984.
5.
R. Lecomte, D. Schmitt, A. W. Light-stone and R. J. McIntyre, "Performance characteristics of BGO-silicon avalanche photodiode detectors for PET", IEEE Trans. Nucl. Sci., vol. NS-32, pp. 482-486, 1985.
6.
R. Lecomte and C. Martel, "Study of the resolution performance of an array of discrete detectors with independent readouts for positron emission tomo- graphy", IEEE Trans. Med. Imag..
7.
M. Dahlbom and E. J. Hoffman, "An evaluation of a two-dimensional array detector for high resolution PET", IEEE Trans. Med. Imag., vol. MI-7, pp. 264-272, 1988.
8.
S. E. Derenzo, R. H. Huesman, J. L. Cahoon, A. Geyer, D. Uber, T. Vuletich, et al., "Initial results from the Donner 600 crystal positron tomograph", IEEE Trans. Nucl. Sci., vol. NS-34, pp. 321-325, 1987.
9.
R. Lecomte, D. Schmitt and G. Lamoureux, "Geometry study of a high resolution PET detection system using small detectors", IEEE Trans. Nucl. Sci., vol. NS-31, pp. 556-561, 1984.
10.
D. Schmitt, R. Lecomte and E. LeBel, "Wedge-shaped scintillation crystals for positron emission tomography", J. Nucl. Med., vol. 27, pp. 99-104, 1986.
11.
R. Bracewell, The Fourier Transform and its applications, McGraw-Hill, pp. 154, 1965.
