Monte Carlo simulation of scintillation photons for the design of a high-resolution SPECT detector dedicated to human brain

• Published in: Annals of nuclear medicine Vol. 26; no. 3; pp. 214 - 221
• Main Authors: Hirano, Yoshiyuki, Zeniya, Tsutomu, Iida, Hidehiro
• Format: Journal Article
• Language: English
• Published: Japan Springer Japan 01.04.2012; Springer Nature B.V
• Subjects: Brain; Brain - diagnostic imaging; Cameras; Computed tomography; Energy; Equipment Design; Humans; Imaging; Medicine; Medicine & Public Health; Monte Carlo Method; Monte Carlo simulation; Nuclear Medicine; Organ Specificity; Original Article; Photons; Radiology; Reproducibility of Results; Scintillation; Single photon emission computed tomography; spatial discrimination; Tomography, Emission-Computed, Single-Photon - instrumentation; LaBr; Ce; Monte Carlo simulation; Geant4; SPECT; Scintillation photon
• ISSN: 0914-7187; 1864-6433
• DOI: 10.1007/s12149-011-0561-4

Objective In a typical single photon emission computed tomography (SPECT) system, intrinsic spatial resolution depends on the accuracy of the identification of an interacting point, which is dominated by propagation of the scintillation photons in the detector block. This study was intended to establish a Monte Carlo simulation-based evaluation tool taking into account the propagation of scintillation photons to estimate the intrinsic spatial and energy resolutions of the position-sensitive scintillator block in a SPECT detector. Methods We employed Geant4 Monte Carlo simulation library which incorporated the optical photon processes for two different designs of the position-sensitive scintillator blocks. The validation of the simulation code was performed for a monolithic NaI(Tl) scintillator (251 × 147 × 6.4 mm 3 ) coupled to 15 flat-panel type multi-anode photo multiplier tubes (PMT) (H8500: Hamamatsu) and results were compared with those obtained experimentally. The code was then applied to a LaBr 3 (Ce) scintillator of 120 mm square with varied thicknesses for designing high-resolution detector. Results The simulation resulted in 2.6 mm full width at half maximum (FWHM) of spatial resolution and 9.0% FWHM of energy resolution for the NaI(Tl)-based detector, which were in a good agreement of the experimental results, i.e., 2.7 mm and 10%, respectively. These findings suggest that Geant4 simulation including optical photon processes enables to predict the spatial and energy resolutions of a SPECT detector block accurately. The simulation also demonstrated that 2 mm spatial resolution can be obtained for a 6 mm thickness of the LaBr 3 (Ce), which is a significant improvement in performance as compared to existing gamma camera system that employs the scintillation detector fitted with PMTs. Conclusions The Monte Carlo simulation-based evaluation tool was established to estimate the intrinsic spatial and energy resolutions of SPECT detector with position sensitive PMTs. This simulation may be useful to provide an optimal design of a SPECT detector without physical experiments.