Publications by authors named "Toru Tanimori"
Imaging was conducted using an electron tracking-Compton camera (ETCC), which measures γ-rays with energies in the range of 200-900 keV from 95mTc. 95mTc was produced by the 95Mo(p, n)95mTc reaction on a 95Mo-enriched target. A method for recycling 95Mo-enriched molybdenum trioxide was employed, and the recycled yield of 95Mo was 70%-90%.
View Article and Find Full Text PDFWe studied Tc and Tc as alternatives to the medical radioisotope Tc. Tc (Tc) can be produced by (p, n) reactions on an enriched Mo (Mo) target with a proton beam provided by a compact accelerator such as a medical cyclotron that generate radioisotopes for positron emission tomography (PET). The γ-rays are measured with an electron-tracking Compton camera (ETCC).
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- We developed an Electron Tracking Compton Camera (ETCC) that accurately measures the brightness and spectrum of MeV gamma-rays, achieving a defined Point Spread Function (PSF) for the first time.
- Our pilot gamma-imaging-spectroscopy tests at contaminated sites near Fukushima in 2014 showed that the brightness data could be converted into consistent dose distribution measurements compared to traditional dosimeter methods.
- The ETCC effectively identified complex radioactive features and a "micro hot spot" of caesium contamination, demonstrating its capabilities and potential applications in various fields such as nuclear safety, medicine, and astronomy.
Since the discovery of nuclear gamma-rays, its imaging has been limited to pseudo imaging, such as Compton Camera (CC) and coded mask. Pseudo imaging does not keep physical information (intensity, or brightness in Optics) along a ray, and thus is capable of no more than qualitative imaging of bright objects. To attain quantitative imaging, cameras that realize geometrical optics is essential, which would be, for nuclear MeV gammas, only possible via complete reconstruction of the Compton process.
View Article and Find Full Text PDFWe have developed an Electron-Tracking Compton Camera (ETCC) for medical imaging due to its wide energy dynamic range (200-1,500keV) and wide field of view (FOV, 3 str). This camera has a potential of developing the new reagents. We have carried out several imaging reagent studies as examples; (1) 18F-FDG and 131I-MIBG simultaneous imaging for double clinical tracer imaging, (2) imaging of some minerals (Mn-54, Zn-65, Fe-59) in mouse and plants.
View Article and Find Full Text PDFThe application of a two-dimensional photon-counting detector based on a micro-pixel gas chamber (micro-PIC) to high-resolution small-angle X-ray scattering (SAXS), and its performance, are reported. The micro-PIC is a micro-pattern gaseous detector fabricated by printed circuit board technology. This article describes the performance of the micro-PIC in SAXS experiments at SPring-8.
View Article and Find Full Text PDFThe application of a two-dimensional micro-pixel gas chamber (micro-PIC) to X-ray diffraction studies, and its performance, are reported. micro-PIC has a 10 cm x 10 cm detection area, and a fast-readout system for real-time X-ray imaging has been developed. Using the timing of each incoming X-ray measured by micro-PIC, continuous rotation photograph measurements were carried out for a 400 microm-diameter spherical organic crystal of Ylid (C(11)H(10)O(2)S), and then diffraction spots were successfully obtained within 2theta of 49 degrees.
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