T. Taya scite author profile

In the field of nuclear medicine, single photon emission tomography and positron emission tomography are the two most common techniques in molecular imaging, but the available radioactive tracers have been limited either by energy range or difficulties in production and delivery. Thus, the use of a Compton camera, which features gamma-ray imaging of arbitrary energies from a few hundred keV to more than MeV, is eagerly awaited along with potential new tracers which have never been used in current modalities. In this paper, we developed an ultra-compact Compton camera that weighs only 580 g. The camera consists of fine-pixelized Ce-doped Gd3Al2Ga3O12 scintillators coupled with multi-pixel photon counter arrays. We first investigated the 3-D imaging capability of our camera system for a diffuse source of a planar geometry, and then conducted small animal imaging as pre-clinical evaluation. For the first time, we successfully carried out the 3-D color imaging of a live mouse in just 2 h. By using tri-color gamma-ray fusion images, we confirmed that 131I, 85Sr, and 65Zn can be new tracers that concentrate in each target organ.

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Recent progress of MPPC-based scintillation detectors in high precision X-ray and gamma-ray imaging

Kataoka

Kishimoto

Fujita

et al. 2015

Nuclear Instruments and Methods in Physics Research Section A:

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Development of a compact scintillator-based high-resolution Compton camera for molecular imaging

Kishimoto

Kataoka

Koide

et al. 2017

Nuclear Instruments and Methods in Physics Research Section A:

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Precision imaging of 4.4 MeV gamma rays using a 3-D position sensitive Compton camera

Koide

Kataoka

Masuda

et al. 2018

Sci Rep

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Imaging of nuclear gamma-ray lines in the 1–10 MeV range is far from being established in both medical and physical applications. In proton therapy, 4.4 MeV gamma rays are emitted from the excited nucleus of either 12C* or 11B* and are considered good indicators of dose delivery and/or range verification. Further, in gamma-ray astronomy, 4.4 MeV gamma rays are produced by cosmic ray interactions in the interstellar medium, and can thus be used to probe nucleothynthesis in the universe. In this paper, we present a high-precision image of 4.4 MeV gamma rays taken by newly developed 3-D position sensitive Compton camera (3D-PSCC). To mimic the situation in proton therapy, we first irradiated water, PMMA and Ca(OH)2 with a 70 MeV proton beam, then we identified various nuclear lines with the HPGe detector. The 4.4 MeV gamma rays constitute a broad peak, including single and double escape peaks. Thus, by setting an energy window of 3D-PSCC from 3 to 5 MeV, we show that a gamma ray image sharply concentrates near the Bragg peak, as expected from the minimum energy threshold and sharp peak profile in the cross section of 12C(p,p)12C*.

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First demonstration of real-time gamma imaging by using a handheld Compton camera for particle therapy

Taya

Kataoka

Kishimoto

et al. 2016

Nuclear Instruments and Methods in Physics Research Section A:

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T. Taya

First demonstration of multi-color 3-D in vivo imaging using ultra-compact Compton camera

Recent progress of MPPC-based scintillation detectors in high precision X-ray and gamma-ray imaging

Development of a compact scintillator-based high-resolution Compton camera for molecular imaging

Precision imaging of 4.4 MeV gamma rays using a 3-D position sensitive Compton camera

First demonstration of real-time gamma imaging by using a handheld Compton camera for particle therapy

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