_version_ 1866908590231519232
author Pan, Weiyan
Chen, Lingyue
Huang, Guorui
Hu, Jun
Hou, Wei
Huang, Xianchao
Han, Xiaorou
Jiang, Xiaoshan
Jin, Zhen
Li, Daowu
Li, Jingwen
Liu, Shulin
Liang, Zehong
Ma, Lishuang
Ning, Zhe
Qian, Sen
Ren, Ling
Sun, Jianning
Si, Shuguang
Sun, Yunhua
Wei, Long
Wang, Ning
Wei, Qing
Wu, Qi
Wang, Tianyi
Wang, Xin
Wang, Xingchao
Wang, Yangfu
Wang, Yifang
Wang, Yingjie
Wang, Zhi
Yuan, Hang
Ye, Jingbo
Yan, Xiongbo
Zhu, Meiling
Zhang, Zhiming
author_facet Pan, Weiyan
Chen, Lingyue
Huang, Guorui
Hu, Jun
Hou, Wei
Huang, Xianchao
Han, Xiaorou
Jiang, Xiaoshan
Jin, Zhen
Li, Daowu
Li, Jingwen
Liu, Shulin
Liang, Zehong
Ma, Lishuang
Ning, Zhe
Qian, Sen
Ren, Ling
Sun, Jianning
Si, Shuguang
Sun, Yunhua
Wei, Long
Wang, Ning
Wei, Qing
Wu, Qi
Wang, Tianyi
Wang, Xin
Wang, Xingchao
Wang, Yangfu
Wang, Yifang
Wang, Yingjie
Wang, Zhi
Yuan, Hang
Ye, Jingbo
Yan, Xiongbo
Zhu, Meiling
Zhang, Zhiming
contents Improving the coincidence time resolution (CTR) of time-of-flight positron emission tomography (TOF-PET) systems to achieve a higher signal-to-noise ratio (SNR) gain or even direct positron emission imaging (dPEI) is of paramount importance for many advanced new clinical applications of PET imaging. This places higher demands on the timing performance of all aspects of PET systems. One effective approach is to use microchannel plate photomultiplier tubes (MCP-PMTs) for prompt Cherenkov photon detection. In this study, we developed a dual-module Cherenkov PET imaging experimental platform, utilising our proprietary 8 * 8-anode Cherenkov radiator-integrated window MCP-PMTs in combination with custom-designed multi-channel electronics, and designed a specific calibration and correction method for the platform. Using this platform, a CTR of 103 ps FWHM was achieved. We overcame the limitations of single-anode detectors in previous experiments, significantly enhanced imaging efficiency and achieved module-level Cherenkov PET imaging for the first time. Imaging experiments involving radioactive sources and phantoms of various shapes and types were conducted, which preliminarily validated the feasibility and advancement of this imaging method. In addition, the effects of normalisation correction and the interaction probability between the gamma rays and the MCP on the images and experimental results were analysed and verified.
format Preprint
id arxiv_https___arxiv_org_abs_2502_07195
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle First experimental proof of PET imaging based on multi-anode MCP-PMTs with Cherenkov radiator-integrated window
Pan, Weiyan
Chen, Lingyue
Huang, Guorui
Hu, Jun
Hou, Wei
Huang, Xianchao
Han, Xiaorou
Jiang, Xiaoshan
Jin, Zhen
Li, Daowu
Li, Jingwen
Liu, Shulin
Liang, Zehong
Ma, Lishuang
Ning, Zhe
Qian, Sen
Ren, Ling
Sun, Jianning
Si, Shuguang
Sun, Yunhua
Wei, Long
Wang, Ning
Wei, Qing
Wu, Qi
Wang, Tianyi
Wang, Xin
Wang, Xingchao
Wang, Yangfu
Wang, Yifang
Wang, Yingjie
Wang, Zhi
Yuan, Hang
Ye, Jingbo
Yan, Xiongbo
Zhu, Meiling
Zhang, Zhiming
Instrumentation and Detectors
Improving the coincidence time resolution (CTR) of time-of-flight positron emission tomography (TOF-PET) systems to achieve a higher signal-to-noise ratio (SNR) gain or even direct positron emission imaging (dPEI) is of paramount importance for many advanced new clinical applications of PET imaging. This places higher demands on the timing performance of all aspects of PET systems. One effective approach is to use microchannel plate photomultiplier tubes (MCP-PMTs) for prompt Cherenkov photon detection. In this study, we developed a dual-module Cherenkov PET imaging experimental platform, utilising our proprietary 8 * 8-anode Cherenkov radiator-integrated window MCP-PMTs in combination with custom-designed multi-channel electronics, and designed a specific calibration and correction method for the platform. Using this platform, a CTR of 103 ps FWHM was achieved. We overcame the limitations of single-anode detectors in previous experiments, significantly enhanced imaging efficiency and achieved module-level Cherenkov PET imaging for the first time. Imaging experiments involving radioactive sources and phantoms of various shapes and types were conducted, which preliminarily validated the feasibility and advancement of this imaging method. In addition, the effects of normalisation correction and the interaction probability between the gamma rays and the MCP on the images and experimental results were analysed and verified.
title First experimental proof of PET imaging based on multi-anode MCP-PMTs with Cherenkov radiator-integrated window
topic Instrumentation and Detectors
url https://arxiv.org/abs/2502.07195