Your search keyword '"Murayama, Hideo"' showing total 15 results

1. Improvement of a PET Detector Performance by Setting Reflectors in Parallel With PMT Face.

Author

Inadama, Naoko, Murayama, Hideo, Nishikido, Fumihiko, Ohi, Junichi, and Yamaya, Taiga

Subjects

*POSITRON emission tomography, *PHOTOMULTIPLIERS, *WHOLE body imaging systems (Security screening), *SCINTILLATORS, *CRYSTAL structure

Abstract

A whole-body positron emission tomography scanner must be equipped with many detectors so that they are often composed of low-cost photomultiplier tubes (PMTs), that is, large anode-type PMTs. The general detector structure has a scintillation crystal element array coupled on an array of the large anode PMTs, and for crystal element identification, the method is needed to get sufficient spread of scintillation light for distribution among distant PMT anodes. Besides the common method of using a light guide, some methods have been proposed for better element identification performance. In this paper, we introduce a new method, in which the scintillation light spread is promoted not only by removing reflectors between crystal elements but also by restricting light exit to the PMTs by placing additional reflectors at the bottom of the crystal element array. Because the additional reflectors are parallel to the PMT surface, we call them parallel reflectors. We verified our method with a detector consisting of the 2.45 mm $\times \,\, 5$ mm $\times \,\,15$ mm Lu2xGd2(1–x)SiO5:Ce crystal elements and two dual-photocathode PMTs. Each photocathode was 8 mm $\times \,\,18$ mm in size. We set a $9 \times 10$ crystal element array on the two PMTs and tried to identify the elements by the $2\times 2$ PMT signals. Detector performance was evaluated with 137Cs point sources (662-keV gamma rays). The results showed that despite a significant decrease in light output at the boundary of the two PMTs, the method made crystal element identification possible. We measured energy resolutions of 13.1% and 17.8% for the elements on the PMT photocathode area and the PMT boundary, respectively. Our method is applicable to the depth-of-interaction detector consisting of multilayer crystal element arrays. By inserting parallel reflectors between the layers, we would be able to control the path of scintillation light originating in the upper layer. The effect was first examined in a basic study with two layers of a $2 \times 5$ crystal element array. Then, the array of each layer was increased to $9\times 9$ for performance evaluation. It was difficult to identify all 162 crystal elements with four PMT signals; however, results suggest the possibility of scintillation light path control in each layer separately by the parallel reflectors and the potential for better performance by more precise adjustment of parallel reflectors. [ABSTRACT FROM AUTHOR]

Published

2019

2. Development of a DOI PET Detector Having the Structure of the X’tal Cube Extended in One Direction.

Author

Inadama, Naoko, Hirano, Yoshiyuki, Nishikido, Fumihiko, Murayama, Hideo, and Yamaya, Taiga

Subjects

POSITRON emission tomography, PHOTON detectors, GAMMA ray detectors, OPTICAL sensors, LUTETIUM compounds, PERFORMANCE evaluation

Abstract

X’tal cube is the cubic depth of interaction (DOI) PET detector which our research group developed. In this work, aiming to get higher sensitivity, we developed the long rectangular shape X’tal cube (long-XC) by extending the cubic X’tal cube structure in one direction. We verified performance of this long-XC and also studied detector parameters for optimization. The same as the X’tal cube, the crystal block of the long-XC is composed of a 3D array of cubic scintillation crystal elements. Reflectors are not inserted between these crystal elements. The scintillation light then spreads without being obstructed by reflectors and is detected by multiple numbers of the multi-pixel photon counters (MPPCs) coupled on all six sides of the crystal block. For crystal element identification, a simple Anger-type calculation is used. In this study, we arranged 3.0 mm \times 3.0 mm \times 3.0 mm LGSO crystal elements in a 6\times 6\times 14 array for the long-XC. In a previous study, we had already confirmed that for the X’tal cube consisting of a 6\times 6\times 6 or 50\,\,\mu \text {m}\,\,\times 50\,\,\mu \text {m} pixel sizes; the material between the crystal elements, an air gap or an optical glue having a closer refractive index to that of LGSO than air has; and the MPPC signals used in the Anger-type calculation. Results of the crystal element identification performance showed that reducing the number of the edge MPPCs caused performance degradation only at the part near the edge. For the MPPC type, the 50~\mu \text {m} type was better than the 25~\mu \text m type, and for the material, air was much better than the optical glue. We found that the choice of MPPC signals for the Anger-type calculation was effective in the optical glue condition. For the long-XC in the air gap condition and using the 50~\mu \text m type MPPCs, we observed it had good performance and there was no significant degradation at the central part which is far from the edge MPPCs. For irradiation of 662 keV gamma-rays, we measured approximately 11 - 13 % energy resolution for each crystal element and there was only a small difference in light outputs between crystal elements at the central part and at the edges. These results at the central part suggested the possibility of further extension of the long-XC for higher sensitivity. [ABSTRACT FROM AUTHOR]

Published

2016

3. Optimization of the Refractive Index of a Gap Material Used for the 4-layer DOI Detector.

Author

Nishikido, Fumihiko, Inadama, Naoko, Yoshida, Eiji, Murayama, Hideo, and Yamaya, Taiga

Subjects

REFRACTIVE index, CRYSTALS, CRYSTALLOGRAPHY, DETECTORS, SCINTILLATION counters, NUCLEAR counters, PARTICLE detectors

Abstract

We have developed a 4-layer depth-of-interaction (DOI) detector which consists of four layers of scintillation crystal arrays and a position sensitive photomultiplier tube (PS-PMT). To control the behavior of scintillation light in each DOI crystal array, some reflectors between crystals are removed so that all crystal responses in the four layers are expressed in one two-dimensional (2D) position histogram by implementing an Anger-type calculation of the PS-PMT signals. Since the method utilizes spread of scintillation light through the boundary of the crystals with no reflectors, positioning performance in the 2D position histogram depends on the crystal dimensions, the crystal surface finish, and gap materials. In this work, we propose an adjustment method for crystal identification performance of the 4-layer DOI detector by selecting the optimal refractive index for the gap materials between the crystals in which the reflectors are removed. We fabricated single-layer detectors and 4-layer detectors using LYSO scintillators and evaluated the crystal identification performance, while varying the refractive index of the gap materials (by using different optical cements). As a result, we found the 2D position histogram changes as a function of the refractive index of the optical cement between crystals and the optimal refractive indices can be determined for the detector using the LYSO crystals. We concluded that the crystal response of the 2D position histograms can be adjusted and crystal identification performance can be optimized by changing the refractive index of the gap materials. [ABSTRACT FROM AUTHOR]

Published

2014

4. X’tal Cube PET Detector Composed of a Stack of Scintillator Plates Segmented by Laser Processing.

Author

Inadama, Naoko, Moriya, Takahiro, Hirano, Yoshiyuki, Nishikido, Fumihiko, Murayama, Hideo, Yoshida, Eiji, Tashima, Hideaki, Nitta, Munetaka, Ito, Hiroshi, and Yamaya, Taiga

Subjects

NUCLEAR counters, PHOTON detectors, DETECTORS, CRYSTALS, LASERS

Abstract

We have developed a three-dimensional (3-D) position-sensitive radiation detector named X’tal cube, which can be applied to a PET detector. The X’tal cube is composed of a scintillation crystal block and multi-pixel photon counters (MPPCs). The crystal block is segmented three-dimensionally into small cubes by optical discontinuity (3-D segmentation) and no reflector is inserted inside. Scintillation light originating in a segment then spreads three-dimensionally so that the MPPCs are set on all six surfaces of the crystal block to detect the light. Regarding the 3-D segmentation of the crystal block, we have already succeeded in getting the segmentation inside of a monolithic scintillator block by a laser processing technique instead of the general way, arranging small cubic scintillator elements into a 3-D array. We have confirmed that utilizing the laser processing technique not only eliminates the difficulty of handling the small scintillator elements but also improves detector performance. As a new trial, we considered fabrication of the crystal block by stacking the scintillator plates which were segmented two-dimensionally by the laser processing technique (2-D segmentation). Plates are also easier to handle and for the laser processing, 2-D segmentation is simpler than 3-D segmentation. In this study, we prepared the X’tal cube with the scintillator plates (Plate-XC) and evaluated its performance to confirm its technical feasibility. For the Plate-XC, we segmented 18 mm \times 18 mm \times 2.0 mm LYSO plates two-dimensionally by laser processing so as to make a 9 \times 9 array of 2.0 mm \times 2.0 mm segments. The crystal block was composed of 9 stacked LYSO plates without using coupling material but with air gaps. The Plate-XC showed sufficient crystal identification performance when 662 keV gamma-rays were irradiated. Furthermore, to understand the characteristics of the Plate-XC, we also analyzed the scintillation light distribution in the crystal block. Results indicated that light spread from outer segments was influenced by the segment boundary conditions, air gaps or laser-processed gaps, while the spread from the center segment did not seem to have such an influence. Regarding energy performance, we obtained around 10% energy resolution for the outer segments as well as for the center segment. [ABSTRACT FROM PUBLISHER]

Published

2014

5. Impact of Laser-Processed X'tal Cube Detectors on PET Imaging in a One-Pair Prototype System.

Author

Yoshida, Eiji, Hirano, Yoshiyuki, Tashima, Hideaki, Inadama, Naoko, Nishikido, Fumihiko, Moriya, Takahiro, Omura, Tomohide, Watanabe, Mitsuo, Murayama, Hideo, and Yamaya, Taiga

Subjects

MEDICAL lasers, PHOTODETECTORS, POSITRON emission tomography, OPTICAL resolution, DATA acquisition systems, DECONVOLUTION (Mathematics)

Abstract

The X'tal cube is our original PET detector, which is being developed to achieve isotropic 3D positioning detectability. The X'tal cube is based on a 3D segmented crystal block for which all surfaces are covered with photo-detectors. Previously, instead of our initial approach of gluing segmented pieces of crystals, we successfully constructed a crystal block segmented by laser processing, and we developed the X'tal cube with the laser-processed 3D square grids of 2 mm length. In this paper, we extend the laser processing to 3D square grids of 1 mm length. The volume of a 1-mm crystal segment is 1/8 of that of a 2-mm crystal segment. We also evaluate imaging resolution performance with a newly developed one-pair prototype system to simulate a ring-type scanner, while our previous reports were limited to development and evaluation of a single detector. In particular, we compare 1-mm X'tal cube detectors to 2-mm X'tal cube detectors. The one-pair prototype system consisted of two X'tal cubes, two rotating stages, and a 192-channel data acquisition system. Each X'tal cube consisted of the LYSO cubic crystal block of 18\,\times\,18\,\times\,18 mm^3 in which the 3D grids of 1 mm pitch were fabricated by internal laser processing. The 4\,\times\,4 arrays of multi pixel photon counters were optically coupled to each surface of the crystal block. The detector positions were automatically controlled to simulate a ring-type PET with a 14.6 cm diameter. Data were collected for all assumed detector positions and then a sinogram was obtained. The data were reconstructed using filtered backprojection. The average spatial resolution of the 2-mm X'tal cube was 1.9 mm full width at half maximum (FWHM) over the field-of-view (FOV). On the other hand, the average spatial resolution of the 1-mm X'tal cube was 1.3 mm FWHM over the FOV. By applying deconvolution with the assumption that the point source was a Gaussian function of 1.0 mm FWHM, we estimated the average spatial resolution of the 2-mm X'tal cube and the 1-mm X'tal cube as 1.6 mm FWHM and 0.83 mm FWHM, respectively. The average spatial resolution of the 1-mm X'tal cube was improved approximately 48% compared to the 2-mm X'tal cube. In conclusion, we confirmed the potential of the X'tal cube for uniform and high resolution imaging. [ABSTRACT FROM AUTHOR]

Published

2013

6. Feasibility Study of an Axially Extendable Multiplex Cylinder PET.

Author

Yoshida, Eiji, Hirano, Yoshiyuki, Tashima, Hideaki, Inadama, Naoko, Nishikido, Fumihiko, Murayama, Hideo, Ito, Hiroshi, and Yamaya, Taiga

Subjects

POSITRON emission tomography, PHOTODETECTORS, PHOTOMULTIPLIERS, DETECTORS, MONTE Carlo method, MEDICAL imaging systems

Abstract

Current clinical PET scanners have a 15–22 cm axial field-of-view (FOV). These scanners image the whole body using six or more bed positions. We designed an axially extendable multiplex cylinder (AEMC) PET scanner to provide high versatility for clinical and research studies using semiconductor photo-sensor based, depth-of-interaction (DOI) detectors. Since silicon-photomultipliers (Si-PMs) have high gain like conventional photomultiplier tubes and a compact design, the Si-PM-based detector is particularly expected to enable various new detector arrangements. The AEMC-PET scanner consists of multiple independent and laminated detector rings using the DOI detectors. The AEMC-PET scanner can extend the axial FOV as each stacked detector ring can be slid sideways. When this PET scanner is used for the four-layer DOI detector, its minimum axial FOV is 24 cm and its maximum crystal thickness is 3 cm. On the other hand, the axial FOV can be extended to 96 cm when laminated detector rings are slid sideways, but the crystal thickness must be 1/4 of 3 cm. In this work, we evaluated performance characteristics of the PET scanner with a variable axial FOV using Monte Carlo simulation. From the simulation of the 180-cm line source, the 96-cm axial FOV was found to have two-fold better sensitivity compared to the 24-cm axial FOV. For extension of the axial FOV, scatter and attenuation of oblique lines-of-response reduced the yield of true coincidences, but effects of scatter and attenuation were small. Conclusive results were obtained showing the 52.8-cm axial FOV yielded an increase in the noise equivalent count rate of approximately 30% relative to the 24-cm axial FOV. We expect the designed AEMC-PET scanner will provide high versatility in applications such as for measuring whole-body tracer uptakes while keeping the continuous axial FOV; as well, the scan time for static images will be reduced for a comparable number of detectors as conventional PET scanners. [ABSTRACT FROM AUTHOR]

Published

2013

7. Potential for reducing the numbers of SiPM readout surfaces of laser-processed X'tal cube PET detectors.

Author

Hirano, Yoshiyuki, Inadama, Naoko, Yoshida, Eiji, Nishikido, Fumihiko, Murayama, Hideo, Watanabe, Mitsuo, and Yamaya, Taiga

Subjects

PHOTON detectors, CRYSTALS, POSITRON emission tomography, THREE-dimensional imaging, HISTOGRAMS

Abstract

We are developing a three-dimensional (3D) position-sensitive detector with isotropic spatial resolution, the X'tal cube. Originally, our design consisted of a crystal block for which all six surfaces were covered with arrays of multipixel photon counters (MPPCs). In this paper, we examined the feasibility of reducing the number of surfaces on which a MPPC array must be connected with the aim of reducing the complexity of the system. We evaluated two kinds of laser-processed X'tal cubes of 3 mm and 2 mm pitch segments while varying the numbers of the 4 × 4 MPPC arrays down to two surfaces. The sub-surface laser engraving technique was used to fabricate 3D grids into a monolithic crystal block. The 3D flood histograms were obtained by the Angertype calculation. Two figures of merit, peak-to-valley ratios and distance-towidth ratios, were used to evaluate crystal identification performance. Clear separation was obtained even in the 2-surface configuration for the 3 mm X'tal cube, and the average peak-to-valley ratios and the distance-to-width ratios were 6.7 and 2.6, respectively. Meanwhile, in the 2 mm X'tal cube, the 6- surface configuration could separate all crystals and even the 2-surface case could also, but the flood histogramswere relatively shrunk in the 2-surface case, especially on planes parallel to the sensitive surfaces. However, the minimum peak-to-valley ratio did not fall below 3.9. We concluded that reducing the numbers of MPPC readout surfaces was feasible for both the 3 mm and the 2 mm X'tal cubes. [ABSTRACT FROM AUTHOR]

Published

2013

8. Development of the X'tal Cube: A 3D Position-Sensitive Radiation Detector With All-Surface MPPC Readout.

Author

Yazaki, Yujiro, Inadama, Naoko, Nishikido, Fumihiko, Mitsuhashi, Takayuki, Suga, Mikio, Shibuya, Kengo, Watanabe, Mitsuo, Yamashita, Takaji, Yoshida, Eiji, Murayama, Hideo, and Yamaya, Taiga

Subjects

SCINTILLATORS, PHOTON detectors, GAMMA ray sources, NUCLEAR counters, PIXELS, POSITION sensitive particle detectors

Abstract

We have developed a new three-dimensional (3D) position sensitive radiation detector, called the X'tal cube. The X'tal cube is composed of a scintillation crystal block and a number of multi-pixel photon counters (MPPCs) which are coupled on all six sides of the block. The block is segmented into cubes and no reflector is used between the segments. Scintillation light originating in a crystal segment accordingly propagates three-dimensionally along the alignment of the crystal segments and is efficiently detected by the MPPCs. The X'tal cube could be used as the detector element of a PET system, for instance. [ABSTRACT FROM AUTHOR]

Published

2012

9. 8-Layer DOI Encoding of 3-Dimensional Crystal Array.

Author

Inadama, Naoko, Murayama, Hideo, Hamamoto, Manabu, Tsuda, Tomoaki, Ono, Yusuke, Yamaya, Taiga, Yoshida, Eiji, Shibuya, Kengo, and Nishikido, Fumihiko

Subjects

*DETECTORS, *CRYSTALS, *OPTICAL reflection, *LIGHTING, *PHOTOMULTIPLIERS, *PARTICLES (Nuclear physics), *ANODES, *SCINTILLATION cameras, *GAMMA rays, *IRRADIATION

Abstract

An 8-layer depth of interaction (DOI) detector was designed based on the technique we have developed for 4-layer DOI detectors. The new detector achieves 8-layer DOI encoding by pulse shape discrimination (2-layer DOI encoding) and an optimized reflector arrangement in a 3-dimensional crystal array (4-layer DOI encoding). Its capability was proved with an 8-layer 10 × 10 Gd2SiO5 (GSO) crystal array coupled to a 256-channel flat panel position sensitive photomultiplier tube (256ch FP-PMT). The dimensions of each crystal element were 2.90 mm × 2.90 mm × 3.75 mm and the interval between 16 × 16 multi anodes in the 256ch FP-PMT was 3.04 mm. Two different dopant concentrations in GSO were chosen for pulse shape discrimination: GSO crystals of 0.5 mol% and 1.5 mol% Ce dopant that have 60 ns and 35 ns scintillation decay times, respectively. In the crystal array, Layer-1, the farthest from the 256ch FP-PMT, and Layers-3, -5 and -7 were composed of GSO crystals of 0.5 mol% Ce dopant. All other layers were composed of GSO crystals of 1.5 mol% Ce dopant. Performance of the 8-layer DOI detector was evaluated by irradiating with 662 keV uniform gamma-rays and the capability was judged to be good. To prove the validity of the layer encoding, a fan-beam of 662 keV gamma-rays was irradiated onto the side face of each layer. The obtained 2-dimensional position histograms showed the right structure in each corresponding layer clearly. Light output uniformity among DOI layers and energy resolutions were measured on the pulse height distributions of the central crystal in each layer. The crystals in Layer-2 and Layer-3 showed the smallest light output and their full energy peak channels were 62 % to the largest peak channel of the Layer-8 crystal distribution. Energy resolutions were about 15 % for all eight layers. [ABSTRACT FROM AUTHOR]

Published

2006

10. Preliminary Evaluation of Four-Layer BGO DOl-Detector for PET.

Author

Inadama, Naoko, Murayama, Hideo, Yamaya, Taiga, Kitamura, Keishi, Yamashita, Takaji, Kawai, Hideyuki, Tsuda, Tomoaki, Sato, Masanobu, Ono, Yusuke, and Hamamoto, Manabu

Subjects

*SCINTILLATORS, *DETECTORS, *POSITRON emission tomography, *CRYSTALS, *GAMMA rays, *DIAGNOSTIC imaging, *MEDICAL equipment, *SCIENTIFIC apparatus & instruments, *ENGINEERING instruments

Abstract

We found that Bi4Ge3O12 (BGO) scintillator can be elements of a four-layer depth of interaction (DOI) detector and it was proved with a 12 × 12 × 4 array of BGO crystals in dimensions of 2.9 mm × 2.9 mm × 7.5 mm coupled to a 256-channel flat panel position sensitive photomultiplier tube. Appropriate reflector insertion in the array makes all crystal identification possible on one position histogram. Despite the large refractivity and small light output of BGO, the four-layer BGO detector showed no significant variation in the full energy peaks among all crystal elements. When no optical grease was used in the construction of the BGO DOI-block and irradiated with gamma-rays from 137Cs, a top layer crystal has 80% of light output relative to the bottom layer. The obtained two-dimensional position histogram by the irradiation was clear enough to allow identification of the crystals of interaction. Profiles of the histogram show peak-to-valley ratio of 1.9:1 for the top layer crystals and larger ratio for other layer crystals in the experiment. [ABSTRACT FROM AUTHOR]

Published

2006

11. Performance Evaluation of a Subset of a Four-Layer LSO Detector for a Small Animal DOl PET Scanner: jPET-RD.

Author

Tsuda, Tomoaki, Murayama, Hideo, Kitamura, Keishi, Inadama, Naoko, Yamaya, Taiga, Yoshida, Eiji, Nishikido, Fumihiko, Hamamoto, Manabu, Kawai, Hideyuki, and Ono, Yusuke

Subjects

*DIAGNOSTIC imaging, *MEDICAL radiography, *MEDICAL imaging systems, *CRYSTALS, *SCANNING systems, *POSITRON emission tomography, *SCINTILLATORS, *MEDICAL equipment, *SCIENTIFIC apparatus & instruments

Abstract

Previously, we proposed a new depth of interaction (DOI) encoding method and proved that it worked successfully with four-layered Gd2SiO5 crystals for a small animal positron emission tomography (PET) detector. We are now planning to develop a small animal PET scanner, jPET-RD (for rodents with DOI detectors), which has both high resolution and high sensitivity by the use of a DOI detector with a 32 × 32 × 4 crystal array. The scintillator for the detector will be Lu2(1-x) Y2xSiO5 (LYSO). !n this work, we evaluated performance of a DOI detector composed of four layers of a 12 × 12 LYSO (Lu: 98%, Y: 2%) crystal array by irradiating 511 keV gamma rays uniformly. The new encoding method was used for crystal identification. The size of each crystal was 1.46 mm × 1.46 mm × 4.5 mm. The crystal block was coupled to a 256-channel flat panel position sensitive photomultiplier tube, which has 16 × 16 multi anodes at intervals of 3.04 mm. As we expected, all crystals are expressed on a single two-dimensional position histogram without overlapping. Energy resolution of all events is 21.8% and time resolution of all events is 0.69 as in FWHM. When layers are counted from the top, the energy resolutions of the first, second, third, and fourth layer events are 11.6%, 12.3%, 13.3%, and 19.1% and the time resolutions are 0.60 ns, 0.59 ns, 0.60 ns, and 0.66 ns, respectively. [ABSTRACT FROM AUTHOR]

Published

2006

12. Three-Dimensional Array of Scintillation Crystals With Proper Reflector Arrangement for a Depth of Interaction Detector.

Author

Orita, Narimichi, Murayama, Hideo, Kawai, Hideyuki, Inadama, Naoko, and Tsuda, Tomoaki

Subjects

*SCINTILLATION counters, *MEDICAL imaging systems, *POSITRON emission tomography, *CRYSTALS, *PHOTOMULTIPLIERS, *GAMMA rays

Abstract

A new method to acquire four-layer depth of interaction (DOI) information is proposed for the next generation positron emission tomography scanner (jPET-D4) that realizes high resolution and high sensitivity. The detector module of the jPET-D4 is a 16 × 16 × 4 Gd2 SiO5: Ce (GSO) multicrystal array coupled with a 256 ch flat panel position sensitive photomultiplier tube (256 ch FP-PMT) having large opening area. The first challenge to encode DO! information was carried out with 8 × 8 array of units consisted of 2 × 2 × 4 crystal elements. The unit is developed for four-layer DOI encoding in previous report. Its crystal identification performance is evaluated by uniform gamma ray irradiation. The measured scintillation events are mapped on a two-dimensional (2-D) position histogram according to the relative ratio of the multianode output of the FP-PMT. However, peaks corresponding to the crystal elements of one unit form a colony in the resultant 2-D position histogram and there is large space between adjacent colonies. In the new method, the reflector arrangement which makes proper light sharing in the multicrystal array decreases such wasted space. Consequently, peak-to-valley on the 2-D position histogram was improved to 3.3:1 from 1.8:1. We found energy performance was also enhanced by the new method. [ABSTRACT FROM AUTHOR]

Published

2005

13. Performance of a PET Detector With a 256ch Flat Panel PS-PMT.

Author

Inadama, Naoko, Murayama, Hideo, Watanabe, Mitsuo, Omura, Tomohide, Yamashita, Takaji, Kawai, Hideyuki, Umehara, Takaya, Kasahara, Takehiro, Orita, Narimichi, and Tsuda, Tomoaki

Subjects

*DETECTORS, *POSITRON emission tomography, *MEDICAL imaging systems, *DIAGNOSTIC imaging, *PHOTOMULTIPLIERS, *CRYSTALS

Abstract

A 256ch flat panel position sensitive photomultiplier tube (FP-PMT) is a promising device for a PET detector because of its large opening area, 52 mm × 52 mm, and small dead space. The useful area of the 256ch FP-PMT is 89% to the opening area. The 256ch FP-PMT contains 16 × 16 matrix anodes with 3.04mm intervals between them so that the 256ch FP-PMT affords optical coupling with a 16 × 16 array of scintillation crystals having 3 mm pact volume and less weight for the PET apparatus. Using a prototype 256ch FP-PMT, we measured light spread function of a central anode and crystal identification ability with 2.9 mm × 2.9 mm × 7.5 mm Gd2SiO5 (GSO) crystals. The full width at half maximum of the light spread function was found to be 4.6 mm. As regards positioning performance, the resultant positioning image map assures its capability for crystal identification in a 16 × 16 array of the GSO crystals. For the use of a 256ch FP-PMT having a large useful area, we made a new proposal for easier construction of an array with many crystal elements. The way utilizing multilayer polymer mirrors, a reflector, properly processed by laser can be applied to other various shaped detectors. [ABSTRACT FROM AUTHOR]

Published

2004

14. The X'tal cube PET detector with a monolithic crystal processed by the 3D sub-surface laser engraving technique: Performance comparison with glued crystal elements.

Author

Yoshida, Eiji, Hirano, Yoshiyuki, Tashima, Hideaki, Inadama, Naoko, Nishikido, Fumihiko, Moriya, Takahiro, Omura, Tomohide, Watanabe, Mitsuo, Murayama, Hideo, and Yamaya, Taiga

Subjects

*POSITRON emission tomography, *CRYSTALS, *NUCLEAR counters, *PHOTONS, *DIGITAL readout systems, *PHOTON detectors

Abstract

The X'tal cube is a depth-of-interaction (DOI)-PET detector which is aimed at obtaining isotropic resolution by effective readout of scintillation photons from six sides of the crystal block. The X'tal cube is composed of a 3D crystal block with isotropic segments. Each face of the 3D crystal block is covered with a 4×4 array of multi-pixel photon counters (MPPCs). Previously, in order to fabricate the 3D crystal block efficiently and precisely, we applied a sub-surface laser engraving technique to a monolithic crystal block instead of gluing segmented small crystals. A dense arrangement of multiple micro-cracks carved by the laser beam works efficiently as a scattering wall for the scintillation photons. The X'tal cube with the laser-processed block showed excellent performance with respect to crystal identification and energy resolution. In this work, for characteristics comparison between the laser-processed block and the conventional segmented array block, we made the laser-processed block and two types of segmented array blocks, one with air gaps and the other with glued segmented small crystals. All crystal blocks had 3D grids of 2mm pitch. The 4×4 MPPC arrays were optically coupled to each surface of the crystal block. When performance was evaluated using a uniform irradiation of 511keV, we found that the X'tal cubes with the laser-processed block could easily achieve 2mm3 uniform crystal identification. Also, the average energy resolution of each 3D grid was 11.1±0.7%. On the other hand, the glued segmented array block had a pinched distribution and crystals could not be separated clearly. The segmented array block with air gaps had satisfactory crystal identification performance; however, the laser-processed block had higher crystal identification performance. Also, the energy resolution of the laser-processed block was better than for the segmented array blocks. In summary, we found the laser-processed X'tal cube had excellent crystal identification performance and high energy performance due to its effective dense arrangement of micro-cracks. [ABSTRACT FROM AUTHOR]

Published

2013

15. Energy spectra analysis of the four-layer DOI detector for the brain PET scanner: jPET-D4

Author

Yoshida, Eiji, Kitamura, Keishi, Tsuda, Tomoaki, Shibuya, Kengo, Yamaya, Taiga, Inadama, Naoko, Hasegawa, Tomoyuki, and Murayama, Hideo

Subjects

*DETECTORS, *PHYSICS instruments, *GAMMA rays, *CRYSTALS

Abstract

Abstract: A depth of interaction (DOI) detector is being developed for the brain PET scanner, jPET-D4. We introduce a light output correction procedure to compensate for variations among the crystal elements in the DOI detector. Under uniform irradiation with 511keV gamma rays, we estimate the light output of each crystal element by identifying each crystal element, and generate a look-up table (LUT) for light output correction. We evaluate the energy resolution of all crystal elements. The energy resolution of 16% is achieved after light output correction for all crystal elements. The DOI detector can correct light output variations that are related to the DOI. We analyze the crystal position dependence of the energy spectra due to inter-crystal scattering among the multiple crystal elements in the DOI detector. It is highly possible that gamma rays interacting with central crystal elements in the crystal array are absorbed by surrounding crystal elements and the Compton part of the energy spectrum is decreased. Inter-crystal scattering has less impact on the energy resolution of the DOI detector. [Copyright &y& Elsevier]

Published

2006