Simple theory predicts that adding time-of-flight (TOF) information reduces the noise in PET images. This noise reduction can improve image quality, decrease imaging time, decrease injected dose, or achieve a combination of these benefits. The potential impact on translational medicine is large, especially for oncology studies in large patients, where improvement is sorely needed. Thus, time-of-flight PET has received considerable interest, with commercialization of TOF PET cameras in the last five years. All of these commercial TOF PET cameras achieve ~555 ps fwhm timing resolution, but as the noise variance in the image is proportional to the timing resolution (i.e., reducing the timing resolutio by a factor of two implies a factor of two reduction in either the imaging time or dose), there is desire to obtain the best timing resolution possible. In addition, the way in which this noise reduction translates into clinical benefit is not well understood. The purpose of this proposal is o build a prototype PET camera whose timing resolution is ~150 ps fwhm (almost four times better than what commercial TOF PET cameras achieve), devise methods to quantify how the noise reduction afforded by time-of-flight translates into clinical benefit, and then measure (usin the prototype camera) how image improvement depends on the timing resolution. By devising methods for obtaining better timing resolution and by quantifying the TOF benefits as a function of timing resolution, we will guide future commercial and academic TOF PET camera designers by allowing them to make informed choices, as our technical developments have been and will continue to be """"""""open source."""""""" We plan three main developments. In the previous funding cycle, we constructed a single-ring """"""""demonstration"""""""" TOF PET camera with LSO scintillator crystals that achieves 326 ps coincidence timing resolution. While simple estimates predict that it will reduce the noise variance by a factor of roughly two in whole-body imaging compared to commercial TOF PET cameras, the first task is to perform a thorough analysis to better characterize its clinical utility. Specifically, we will quantify the improvement in noise as a function of timing resolution using a combination of simulation, phantom, and human subject studies, including the clinically relevant tasks of tumor detection and staging. Our second task is to rebuild the camera with a newly developed scintillator (LaBr3:Ce) that has exceptional PET performance (high sensitivity, 3% energy resolution, and 150 ps timing resolution), which will provide another factor of two improvement in timing resolution over our LSO camera. This timing resolution is nearly four times better than commercial TOF PET cameras, and we predict it will give an enormous noise variance reduction (16-fold, when imaging a 35 cm diameter patient) compared to conventional (non-TOF) PET cameras! The final task is to analyze the performance of this camera by using the same methods as in the first task.

Public Health Relevance

Accurate diagnosis of cancer (and other diseases) using PET will be improved if the noise in the image is reduced. Accurately measuring the time that radiation is detected by the PET camera reduces this noise by an amount predicted to be proportional to the time measurement accuracy. This proposal will construct a PET camera that has a factor of four better timing resolution than existing commercial PET cameras, and then will use the camera to evaluate (using clinically relevant tasks) the improvement in image quality afforded by the better timing resolution.

National Institute of Health (NIH)
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Research Project (R01)
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Biomedical Imaging Technology Study Section (BMIT)
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Sastre, Antonio
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Lawrence Berkeley National Laboratory
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Abu-Nimeh, Faisal T; Ito, Jennifer; Moses, William W et al. (2016) Architecture and Implementation of OpenPET Firmware and Embedded Software. IEEE Trans Nucl Sci 63:620-629
Choong, W-S; Abu-Nimeh, F; Moses, W W et al. (2015) A front-end readout Detector Board for the OpenPET electronics system. J Instrum 10:
Peng, Q; Choong, W-S; Vu, C et al. (2015) Performance of the Tachyon Time-of-Flight PET Camera. IEEE Trans Nucl Sci 62:111-119
Shi, Han; Du, Dong; Xu, JianFeng et al. (2015) A fast method for optical simulation of flood maps of light-sharing detector modules. Nucl Instrum Methods Phys Res A 802:48-59
Derenzo, Stephen E; Choong, Woon-Seng; Moses, William W (2015) Monte Carlo calculations of PET coincidence timing: single and double-ended readout. Phys Med Biol 60:7309-38
Derenzo, Stephen E; Choong, Woon-Seng; Moses, William W (2014) Fundamental limits of scintillation detector timing precision. Phys Med Biol 59:3261-86
Gola, Alberto; Ferri, Alessandro; Tarolli, Alessandro et al. (2014) SiPM optical crosstalk amplification due to scintillator crystal: effects on timing performance. Phys Med Biol 59:3615-35
Zhou, Jian; Qi, Jinyi (2014) Efficient fully 3D list-mode TOF PET image reconstruction using a factorized system matrix with an image domain resolution model. Phys Med Biol 59:541-59
Moses, W W; Peng, Q (2014) Artifacts in digital coincidence timing. Phys Med Biol 59:N181-5
Kim, H; Chen, C-T; Eclov, N et al. (2014) A New Time Calibration Method for Switched-capacitor-array-based Waveform Samplers. Nucl Instrum Methods Phys Res A 767:67-74

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