DocumentCode
687381
Title
Multiple scattering imager for photon therapy
Author
Taewoong Lee ; Changyeon Yoon ; Wonho Lee
Author_Institution
Bioconvergence Dept., Korea Univ., Seoul, South Korea
fYear
2013
fDate
Oct. 27 2013-Nov. 2 2013
Firstpage
1
Lastpage
4
Abstract
During radiation therapy, it is necessary to monitor the irradiated position and energy deposited in the patient. In general, calculations before photon exposure or 2D measurement of transmitted photons have been widely used for dose estimation. In this research, we propose real-time 3D dose measurement using Compton imaging technology. On the basis of the Monte-Carlo method, we designed a multiple scattering Compton camera system (MSCC) with semiconductor and scintillation detectors. The MSCC was constructed with two semiconductor detectors as scatter detectors and a CWO scintillator detector as an absorber detector. The two planar semiconductor arrays consisted of 40 × 40 pixels, each with a size of 1 × 1× thickness mm3, and the other CWO array consisted of 40 × 40 pixels, each with a size of 1 × 1 × thickness mm3. The design parameters such as the types of semiconductors, detector thicknesses and distances between detectors were optimized on the basis of the detection efficiency and angular resolution of reconstructed images for a point source. Under the optimized conditions, uncertainty factors in geometry and energy were estimated for various the inter-detector distances. We used a source corresponding to photons scattered from a water phantom exposed to the 6-MeV peak X-ray. According to our simulation results, the figure of merit (FOM) reached its maximum value when the inter-detector distance is 3 cm. In order to achieve a high FOM, we chose 1 cm as the optimum thickness for scattering detectors. The position uncertainty caused by the pixelization effect was the major factor to degrade the angular resolution of the reconstructed images and the degradation caused by energy broadening was less than expected. The angular uncertainties caused by Doppler broadening and incorrect sequencing were minimal compared with that of pixelization. Our simulation showed the feasibility of using the semic- nductor based Compton camera to monitor the exposed dose in 3D radiation therapy.
Keywords
Doppler broadening; Monte Carlo methods; biomedical optical imaging; cameras; dosimetry; image reconstruction; image sequences; medical image processing; phantoms; radiation therapy; semiconductor counters; solid scintillation detectors; 2D transmitted photon measurement; 3D radiation therapy; CWO array; CWO scintillator detector; Compton imaging; Doppler broadening; FOM; MSCC; Monte-Carlo method; absorber detector; angular resolution; angular uncertainty; figure-of-merit; image reconstruction; image sequence; inter-detector distances; multiple scattering Compton camera system; multiple scattering imager; photon exposure; photon scattering; photon therapy; pixelization effect; planar semiconductor arrays; real-time 3D dose measurement; scatter detectors; semiconductor detectors; semiconductor-based Compton camera; uncertainty factors; water phantom; Cameras; Detectors; Energy resolution; Image reconstruction; Image resolution; Photonics; Uncertainty;
fLanguage
English
Publisher
ieee
Conference_Titel
Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC), 2013 IEEE
Conference_Location
Seoul
Print_ISBN
978-1-4799-0533-1
Type
conf
DOI
10.1109/NSSMIC.2013.6829836
Filename
6829836
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