Your search keyword '"Joel Kindem"' showing total 6 results

1. Transparent Ceramic Garnet Gamma-Ray Spectrometer With Directionality

Author

P. R. Beck, Steven L. Hunter, B. M. Wihl, E. L. Swanberg, Nerine J. Cherepy, Stephen A. Payne, S. E. Fisher, Zachary M. Seeley, and Joel Kindem

Subjects

Physics, Nuclear and High Energy Physics, Thermoelectric cooling, Pixel, Spectrometer, business.industry, Detector, Resolution (electron density), Scintillator, 030218 nuclear medicine & medical imaging, Photodiode, law.invention, 03 medical and health sciences, 0302 clinical medicine, Optics, Nuclear Energy and Engineering, law, 030220 oncology & carcinogenesis, Electrical and Electronic Engineering, business, Energy (signal processing)

Abstract

We have developed a handheld $\gamma $ -ray spectrometer based on 1024 pixels, $2.8\,\,\text {mm} \times 2.8\,\,\text {mm} \times 6$ mm in size, of gadolinium–yttrium–gallium–aluminum garnet (GYGAG) ((Gd,Y,Ce)3(Ga,Al)5O12) ceramic scintillator (total of 48-cm3 detector volume) coupled to silicon photodiode (SiPD) arrays. The SiPD arrays and readout ASIC, originally developed for medical imaging applications, have been adapted for portability in a lightweight box with heatsink and thermoelectric cooling. Custom readout firmware for $\gamma $ -ray spectroscopy has been implemented, and a system user interface was developed that runs on an Android tablet. We have optimized the processing of the GYGAG(Ce), the pixel optical coupling, and electronics readout parameters to obtain single pixel energy resolution as good as $R (662\,\,\text {keV}) = 3.1$ % full-width at half-maximum and full device resolution with singles events from all pixels summed of 4.5%. When Compton-summed events are included, full-energy peak efficiency increases by $\sim 2\times $ , and $R (662\,\,\text {keV}) = 4.7$ % is obtained for the full device. The pixelated architecture is leveraged to locate point sources of radiological materials using Compton imaging and active masking techniques. Directional detection of a 1 mCi Cs-137 source at 10 m can be made to ±10° in ~2 s.

Published

2018

2. Development of Transparent Ceramic Ce-Doped Gadolinium Garnet Gamma Spectrometers

Author

Larry Ahle, P. A. Thelin, Zachary M. Seeley, K. M. Figueroa, Nerine J. Cherepy, Owen B. Drury, Sean O'Neal, S.A. Payne, S. Hunter, P. R. Beck, Joel Kindem, and T. Stefanik

Subjects

Nuclear and High Energy Physics, Scintillation, Materials science, Physics::Instrumentation and Detectors, business.industry, Photodetector, Scintillator, Photodiode, law.invention, Nuclear physics, Nuclear Energy and Engineering, law, visual_art, visual_art.visual_art_medium, Optoelectronics, Gamma spectroscopy, Ceramic, Electrical and Electronic Engineering, Spectroscopy, business, Radiation hardening

Abstract

Transparent polycrystalline ceramic scintillators based on the garnet structure and incorporating gadolinium for high stopping power are being developed for use in gamma spectrometers. Optimization of energy resolution for gamma spectroscopy involves refining the material composition for high stopping and high light yield, developing ceramics fabrication methodology for material homogeneity, as well as selecting the size and geometry of the scintillator to match the photodetector characteristics and readout electronics. We have demonstrated energy resolution of 4% at 662 keV for 0.05 cm3 GYGAG(Ce) ceramics with photodiode readout, and 4.9% resolution at 662 keV for 18 cm 3 GYGAG(Ce) ceramics and PMT readout. Comparative gamma spectra acquired with GYGAG(Ce) and NaI(Tl) depict the higher resolution of GYGAG(Ce) for radioisotope identification applications. Light yield non-proportionality of garnets fabricated following different methods reveal that the fundamental shapes of the light yield dependence on energy are not intrinsic to the crystal structure, but may instead depend on trap state distributions. With exposure to 9 MeV Brehmsstrahlung radiation, we also find that GYGAG(Ce) ceramics exhibit excellent radiation hardness.

Published

2013

3. Development and evaluation of a new fully automatic motion detection and correction technique in cardiac SPECT imaging

Author

Rex Old, Jamshid Maddahi, Richard Conwell, Joel Kindem, Michael Gurley, and Chuanyong Bai

Subjects

Image quality, Perfusion Imaging, Cardiology, Perfusion scanning, Image processing, image artifacts, Automation, Software, Spect imaging, Image Interpretation, Computer-Assisted, Image Processing, Computer-Assisted, Medicine & Public Health, Humans, image quality, Medicine, Radiology, Nuclear Medicine and imaging, Computer vision, motion correction, Observer Variation, Tomography, Emission-Computed, Single-Photon, Phantoms, Imaging, Myocardial perfusion imaging, business.industry, Myocardium, Imaging / Radiology, Reproducibility of Results, Heart, Motion detection, Equipment Design, Radiology Nuclear Medicine and imaging, SPECT, Original Article, Tomography, Noise (video), Artificial intelligence, Nuclear Medicine, Artifacts, Cardiology and Cardiovascular Medicine, business, Nuclear medicine

Abstract

Background In cardiac SPECT perfusion imaging, motion correction of the data is critical to the minimization of motion introduced artifacts in the reconstructed images. Software-based (data-driven) motion correction techniques are the most convenient and economical approaches to fulfill this purpose. However, the accuracy is significantly affected by how the data complexities, such as activity overlap, non-uniform tissue attenuation, and noise are handled. Methods We developed STASYS, a new, fully automatic technique, for motion detection and correction in cardiac SPECT. We evaluated the performance of STASYS by comparing its effectiveness of motion correcting patient studies with the current industry standard software (Cedars-Sinai MoCo) through blind readings by two readers independently. Results For 204 patient studies from multiple clinical sites, the first reader identified (1) 69 studies with medium to large axial motion, of which STASYS perfectly or significantly corrected 86.9% and MoCo 72.5%; and (2) 20 studies with medium to large lateral motion, of which STASYS perfectly or significantly corrected 80.0% and MoCo 60.0%. The second reader identified (1) 84 studies with medium to large axial motion, of which STASYS perfectly or significantly corrected 82.2% and MoCo 76.2%; and (2) 34 studies with medium to large lateral motion, of which STASYS perfectly or significantly corrected 58.9% and MoCo 50.0%. Conclusions We developed a fully automatic software-based motion correction technique, STASYS, for cardiac SPECT. Clinical studies showed that STASYS was effective and corrected a larger percent of cardiac SPECT studies than the current industrial standard software.

Published

2009

4. Transparent ceramic scintillators for gamma spectroscopy and MeV imaging

Author

P. A. Thelin, R L Perry, Daniel J. Schneberk, P. R. Beck, Nerine J. Cherepy, S.A. Payne, B. M. Wihl, R. R. Thompson, Nicholas M. Harvey, S. E. Fisher, Zachary M. Seeley, T. Stefanik, E. L. Swanberg, Joel Kindem, S. Hunter, and Gary Stone

Subjects

Materials science, Optics, Yield (engineering), Transparent ceramics, Gamma ray spectrometer, business.industry, visual_art, visual_art.visual_art_medium, Gamma spectroscopy, Ceramic, Scintillator, Spectroscopy, business

Abstract

We report on the development of two new mechanically rugged, high light yield transparent ceramic scintillators: (1) Ce-doped Gd-garnet for gamma spectroscopy, and (2) Eu-doped Gd-Lu-bixbyite for radiography. GYGAG(Ce) garnet transparent ceramics offer ρ = 5.8g/cm3, Zeff = 48, principal decay of 8 lp/mm.

Published

2015

5. High energy resolution with transparent ceramic garnet scintillators

Author

Charles L. Melcher, Hua Wei, S. Hunter, E. L. Swanberg, Joel Kindem, Zachary M. Seeley, S. E. Fisher, Nerine J. Cherepy, Larry Ahle, S.A. Payne, Y.-S. Chung, P. R. Beck, and T. Stefanik

Subjects

Scintillation, Materials science, Dopant, Transparent ceramics, business.industry, Photodetector, Scintillator, Thermoluminescence, visual_art, visual_art.visual_art_medium, Optoelectronics, Gamma spectroscopy, Ceramic, business

Abstract

Breakthrough energy resolution, R(662keV) < 4%, has been achieved with an oxide scintillator, Cerium-doped Gadolinium Yttrium Gallium Aluminum Garnet, or GYGAG(Ce). Transparent ceramic GYGAG(Ce), has a peak emission wavelength of 550 nm that is better matched to Silicon photodetectors than to standard PMTs. We are therefore developing a spectrometer based on pixelated GYGAG(Ce) on a Silicon photodiode array that can provide R(662 keV) = 3.6%. In comparison, with large 1-2 in3 size GYGAG(Ce) ceramics we obtain R(662 keV) = 4.6% with PMT readout. We find that ceramic GYGAG(Ce) of a given stoichiometric chemical composition can exhibit very different scintillation properties, depending on sintering conditions and post-anneal treatments. Among the characteristics of transparent ceramic garnet scintillators that can be controlled by fabrication conditions are: scintillation decay components and their amplitudes, intensity and duration of afterglow, thermoluminescence glow curve peak positions and amplitudes, integrated light yield, light yield non-proportionality - as measured in the Scintillator Light Yield Non-Proportionality Characterization Instrument (SLYNCI), and energy resolution for gamma spectroscopy. Garnet samples exhibiting a significant fraction of Cerium dopant in the tetravalent valence also exhibit: faster overall scintillation decay, very low afterglow, high light yield, but poor light yield proportionality and degraded energy resolution.

Published

2014

6. Phantom evaluation of a cardiac SPECT/VCT system that uses a common set of solid-state detectors for both emission and transmission scans

Author

Chuanyong Bai, Richard Conwell, Joel Kindem, Hetal Babla, Mike Gurley, Romer De Los Santos, Rex Old, Randy Weatherhead, Samia Arram, and Jamshid Maddahi

Subjects

Attenuation correction, Image quality, Cardiology, Image processing, Imaging phantom, Collimated light, Cardiac SPECT, Image Processing, Computer-Assisted, Medicine & Public Health, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Tomography, Emission-Computed, Single-Photon, business.industry, Attenuation, Imaging / Radiology, Myocardial Perfusion Imaging, Heart, equipment and supplies, Solid-state detector, Radiology Nuclear Medicine and imaging, Attenuation coefficient, Fluorescence x-ray transmission source, Original Article, Tomography, Nuclear Medicine, Cardiology and Cardiovascular Medicine, business, Nuclear medicine, Correction for attenuation, Biomedical engineering

Abstract

Background We developed a cardiac SPECT system (X-ACT) with low dose volume CT transmission-based attenuation correction (AC). Three solid-state detectors are configured to form a triple-head system for emission scans and reconfigured to form a 69-cm field-of-view detector arc for transmission scans. A near mono-energetic transmission line source is produced from the collimated fluorescence x-ray emitted from a lead target when the target is illuminated by a narrow polychromatic x-ray beam from an x-ray tube. Transmission scans can be completed in 1 min with insignificant patient dose (deep dose equivalent

Published

2010