Development of a small prototype for a proof-of-concept of OpenPET imaging

Yamaya, Taiga; Yoshida, Eiji; Inaniwa, Taku; Sato, Shinji; Nakajima, Yasunori; Wakizaka, Hidekatsu; Kokuryo, Daisuke; Tsuji, Atsushi B.; Mitsuhashi, Takayuki; Kawai, H.; Tashima, Hideaki; Nishikido, Fumihiko; Inadama, Naoko; Murayama, Hideo; Haneishi, Hideaki; Suga, Mikio; Kinouchi, Shoko

doi:10.1088/0031-9155/56/4/015

Cited by 121 publications

(82 citation statements)

References 26 publications

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“…The DOI detector was designed with the high priority for optimization of in-beam PET. As a result, the small OpenPET prototype has operated of a stable condition during the 11 C irradiation [13].…”

Section: Discussionmentioning

confidence: 99%

“…In a previous report [13], the coincidence window of the small OpenPET prototype was set at 60 ns, because the timing histogram had a broad distribution. However, random coincidences give a nearly undetectable count rate for in-beam PET experiments, because the activity due to irradiation is low.…”

Section: Discussionmentioning

confidence: 99%

“…We have developed and evaluated a small OpenPET prototype that uses 4-layer DOI detectors [10], which offers the promise of high sensitivity (6.5% system sensitivity) and high spatial resolution (about 2 mm full width at half maximum (FWHM)) [13]. The system design of the small OpenPET prototype has been optimized for in-beam PET experiments.…”

Section: Introductionmentioning

confidence: 99%

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System design of a small OpenPET prototype with 4-layer DOI detectors

Yoshida¹,

Kinouchi

Tashima³

et al. 2011

Radiol Phys Technol

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We have proposed an OpenPET geometry which consists of two axially separated detector rings. The open gap is suitable for in-beam PET. We have developed the small prototype of the OpenPET especially for a proof of concept of in-beam imaging. This paper presents an overview of the main features implemented in this prototype. We also evaluated the detector performance. This prototype was designed with 2 detector rings having 8 depth-of-interaction detectors. Each detector consisted of 784 Lu(2x)Gd(2(1-x))SiO₅:Ce (LGSO) which were arranged in a 4-layer design, coupled to a position-sensitive photomultiplier tube (PS-PMT). The size of the LGSO array was smaller than the sensitive area of the PS-PMT, so that we could obtain sufficient LGSO identification. Peripheral LGSOs near the open gap directly detect the gamma rays on the side face in the OpenPET geometry. Output signals of two detectors stacked axially were projected onto one 2-dimensional position histogram for reduction of the scale of a coincidence processor. Front-end circuits were separated from the detector head by 1.2-m coaxial cables for the protection of electronic circuits from radiation damage. The detectors had sufficient crystal identification capability. Cross talk between the combined two detectors could be ignored. The timing and energy resolutions were 3.0 ns and 14%, respectively. The coincidence window was set 20 ns, because the timing histogram showed that not only the main peak, but also two small shifted peaks were caused by the coaxial cable. However, the detector offers the promise of sufficient performance, because random coincidences are at a nearly undetectable level for in-beam PET experiments.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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System design of a small OpenPET prototype with 4-layer DOI detectors

Yoshida¹,

Kinouchi

Tashima³

et al. 2011

Radiol Phys Technol

Self Cite

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“…Furthermore, physiological processes such as blood flow cause some of the positron emitters to diffuse away from the treatment area over time and thus spoil the physical correlation between treatment delivery and measured activity. Researchers are working to develop both modern in-beam PET instrumentation tailored to in vivo beam-range verification 7,8 and computerassisted tools for adjusting the treatment plan when PET detects an offset between the delivered and intended beam ranges.…”

Section: In Vivo Imagingmentioning

confidence: 99%

Imaging particle beams for cancer treatment

Polf¹,

Parodi²

2015

Physics Today

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“…Recently, PSD analysis has been applied for a depth-of-interaction (DOI) detector in a small positron emission tomography (PET) device aiming at the improvement of image quality. 9 The DOI detector consists of a multilayered scintillator with different scintillation properties. 10,11 Moreover, a phoswich (phosphor sandwich) detector which consists of a few scintillators identifies an incident particle type by PSD analysis in a common readout, 12 and applies a background rejection method using anti-Compton analysis.…”

Section: Introductionmentioning

confidence: 99%

Signal pulse emulation for scintillation detectors using Geant4 Monte Carlo with light tracking simulation

Ogawara

Ishikawa

2016

Review of Scientific Instruments

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The anode pulse of a photomultiplier tube (PMT) coupled with a scintillator is used for pulse shape discrimination (PSD) analysis. We have developed a novel emulation technique for the PMT anode pulse based on optical photon transport and a PMT response function. The photon transport was calculated using Geant4 Monte Carlo code and the response function with a BC408 organic scintillator. The obtained percentage RMS value of the difference between the measured and simulated pulse with suitable scintillation properties using GSO:Ce (0.4, 1.0, 1.5 mol%), LaBr3:Ce and BGO scintillators were 2.41%, 2.58%, 2.16%, 2.01%, and 3.32%, respectively. The proposed technique demonstrates high reproducibility of the measured pulse and can be applied to simulation studies of various radiation measurements

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Development of a small prototype for a proof-of-concept of OpenPET imaging

Cited by 121 publications

References 26 publications

System design of a small OpenPET prototype with 4-layer DOI detectors

System design of a small OpenPET prototype with 4-layer DOI detectors

Imaging particle beams for cancer treatment

Signal pulse emulation for scintillation detectors using Geant4 Monte Carlo with light tracking simulation

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