High resolution image reconstruction method for a double-plane PET system with changeable spacing

Xiao-Yue Gu; Wei Zhou; Lin Li; Long Wei; Peng-Fei Yin; Lei-Min Shang; Ming-Kai Yun; Zhen-Rui Lu; Xian-Chao Huang

doi:10.1088/1674-1137/40/5/058201

Chinese Physics C> 2016, Vol. 40> Issue(5) : 058201 DOI: 10.1088/1674-1137/40/5/058201

High resolution image reconstruction method for a double-plane PET system with changeable spacing

Xiao-Yue Gu ^1,2,, ,
Wei Zhou ^1,2 ,
Lin Li ^1,2 ,
Long Wei ^1,2 ,
Peng-Fei Yin ^1,2 ,
Lei-Min Shang ^1,2 ,
Ming-Kai Yun ^1,2 ,
Zhen-Rui Lu ^1,2 ,
Xian-Chao Huang ^1,2

1.
Key Laboratory of Nuclear Radiation and Nuclear Energy Technology, Institute of High Energy Physics, Chinese Academy of Sciences, Beijing 100049, China
2.
Beijing Engineering Research Center of Radiographic Techniques and Equipment, Beijing 100049, China

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Abstract：
Breast-dedicated positron emission tomography(PET) imaging techniques have been developed in recent years. Their capacities to detect millimeter-sized breast tumors have been the subject of many studies. Some of them have been confirmed with good results in clinical applications. With regard to biopsy application, a double-plane detector arrangement is practicable, as it offers the convenience of breast immobilization. However, the serious blurring effect of the double-plane PET, with changeable spacing for different breast sizes, should be studied. We investigated a high resolution reconstruction method applicable for a double-plane PET. The distance between the detector planes is changeable. Geometric and blurring components were calculated in real-time for different detector distances, and accurate geometric sensitivity was obtained with a new tube area model. Resolution recovery was achieved by estimating blurring effects derived from simulated single gamma response information. The results showed that the new geometric modeling gave a more finite and smooth sensitivity weight in the double-plane PET. The blurring component yielded contrast recovery levels that could not be reached without blurring modeling, and improved visual recovery of the smallest spheres and better delineation of the structures in the reconstructed images were achieved with the blurring component. Statistical noise had lower variance at the voxel level with blurring modeling at matched resolution, compared to without blurring modeling. In distance-changeable double-plane PET, finite resolution modeling during reconstruction achieved resolution recovery, without noise amplification.
- breast PET ,
- double-plane PET ,
- reconstruction

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[1]	M. C. Abreu, et al, Nuclear Science, IEEE Transactions on, 53(1):71-77(2006)
[2]	S. L. Bowen, et al, Journal of Nuclear Medicine, 50(9):1401-1408(2009)
[3]	M. Furuta, et al, Basic evaluation of a C-shaped breast PET scanner, Of the 2009 Nuclear Science Symposium and Medical Imaging Conference Record(NSS/MIC), 2009
[4]	P. Lecoq, and J. Varela, Nuclear Instruments and Methods in Physics Research Section A:Accelerators, Spectrometers, Detectors and Associated Equipment, 486(1):1-6(2002)
[5]	L. MacDonald, et al, Journal of Nuclear Medicine, 50(10):1666-1675(2009)
[6]	R. R. Raylman, et al, Physics in Medicine and Biology, 53(3):637(2008)
[7]	C. Thompson, et al, Medical physics, 21(4), 529-538(1994)
[8]	B. Koolen, et al, Molecular Imaging in Breast Cancer:from whole-body PET/CT to dedicated breast PET, Journal of oncology, 2012
[9]	R. R. Raylman et al, Journal of medical imaging and radiation oncology, 55(1):58-64(2011)
[10]	M. Iima, et al, Journal of Nuclear Medicine, 53(10):1534-1542(2012)
[11]	J. S. Eo et al, The Breast, 21(1), 66-71(2012)
[12]	C. M. Kao, Y. Dong and Q. Xie, Evaluation of 3D image reconstruction methods for a dual-head small-animal PET scanner, Of the 2007 Nuclear Science Symposium and Medical Imaging Conference Record(NSS/MIC), 2007
[13]	A. Saoudi, et al, Nuclear Science, IEEE Transactions on, 46(3):462-467(1999)
[14]	J. Seidel et al, Nuclear Science, IEEE Transactions on, 46(3):485-490(1999)
[15]	W. Moses, and S.E. Derenzo, Nuclear Science, IEEE Transactions on, 41(4):1441-1445(1994)
[16]	G. Boning, et al, Implementation of Monte Carlo Coincident Functions in Image Generation of a High Resolution Animal Positron Tomograph, Of the 2000 Nuclear Science Symposium and Medical Imaging Conference Record(NSS/MIC),(2000)
[17]	C. M. Kao, and C. T. Chen, Nuclear Science, IEEE Transactions on, 49(1):208-214(2002)
[18]	V. Y. Panin, et al, Medical Imaging, IEEE Transactions on, 25(7):907-921(2006)
[19]	J. Qi et al, Physics in Medicine and Biology, 43(4):1001.(1998)
[20]	P. M. Joseph, Medical Imaging, IEEE Transactions on, 1(3), 192-196(1982)
[21]	A. Terstegge, et al. High resolution and better quantification by tube of response modelling in 3D PET reconstruction,Of the 1996 Nuclear Science Symposium and Medical Imaging Conference Record(NSS/MIC),(1996)
[22]	C. Johnson, et al, Nuclear Science, IEEE Transactions on, 42(4):1223-1227(1995)
[23]	C. Chen, S. Y. Lee and Z. Cho, Medical Imaging, IEEE Transactions on, 10(4):513-522(1991)
[24]	A. Rahmim, J. Qi and V. Sossi, Medical physics, 40(6):064301(2013)
[25]	V. Y. Panin, et al, PET reconstruction with system matrix derived from point source measurements, Of the 2004 Nuclear Science Symposium and Medical Imaging Conference Record(NSS/MIC), 2004
[26]	F. C. Sureau et al, Journal of Nuclear Medicine, 49(6):1000-1008(2008)
[27]	X. Y. Gu et al, Chinese Physics C, 10(22):108-202(2015)
[28]	R. M. Leahy, and J. Qi, Statistics and Computing, 10(2):147-165(2000)
[29]	F. Xin et al, Chinese Physics B, 24(1):018702(2015)
[30]	S. R. Cherry, and M. Dahlbom, in PET:Physics, Instrumation, and Scanners, ed. M. E. Phelps,(Springer, 2006)

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Xiao-Yue Gu, Wei Zhou, Lin Li, Long Wei, Peng-Fei Yin, Lei-Min Shang, Ming-Kai Yun, Zhen-Rui Lu and Xian-Chao Huang. High resolution image reconstruction method for a double-plane PET system with changeable spacing[J]. Chinese Physics C, 2016, 40(5): 058201. doi: 10.1088/1674-1137/40/5/058201

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Received: 2015-07-27

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Supported by Knowledge Innovation Project of The Chinese Academy of Sciences(KJCX2-EW-N06)

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沈阳化工大学材料科学与工程学院沈阳 110142

High resolution image reconstruction method for a double-plane PET system with changeable spacing

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High resolution image reconstruction method for a double-plane PET system with changeable spacing

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