Yi Minseok, Lee Daehee, Gola Alberto, Merzi Stefano, Penna Michele, Lee Jae Sung, Cherry Simon R, Kwon Sun Il
Department of Biomedical Engineering, University of California, Davis, One Shields Avenue, Davis, California 95616, United States.
Interdisciplinary Program in Bioengineering, Seoul National University College of Engineering, Seoul 03080, Republic of Korea.
ACS Photonics. 2025 Feb 6;12(2):1125-1136. doi: 10.1021/acsphotonics.4c02265. eCollection 2025 Feb 19.
Positron emission tomography (PET) is the most sensitive biomedical imaging modality for noninvasively detecting and visualizing positron-emitting radiopharmaceuticals within a subject. In PET, measuring the time-of-flight (TOF) information for each pair of 511 keV annihilation photons improves effective sensitivity but requires high timing resolution. Hybrid materials that emit both scintillation and Cherenkov photons, such as bismuth germanate, recently offer the potential for more precise timing information from Cherenkov photons while maintaining adequate energy resolution from scintillation photons. However, a significant challenge in using such hybrid materials for TOF PET applications lies in the event-dependent timing spread caused by the mixed detection of Cherenkov and scintillation photons due to relatively lower production of Cherenkov photons. This study introduces an innovative approach by segmenting silicon photomultiplier (SiPM) pixels coupled to a single crystal, rather than using traditional SiPMs that are as large as or larger than the crystals they read. We demonstrated that multiple timestamps and photon counts obtained from the segmented SiPM can classify events by providing temporal photon density, effectively addressing this challenge. The approach and findings would lead to new opportunities in applications that require precise timing and photon counting.
正电子发射断层扫描(PET)是用于在受试者体内非侵入性检测和可视化发射正电子的放射性药物的最灵敏的生物医学成像方式。在PET中,测量每对511 keV湮灭光子的飞行时间(TOF)信息可提高有效灵敏度,但需要高时间分辨率。最近,诸如锗酸铋之类的既发射闪烁光子又发射切伦科夫光子的混合材料,在保持来自闪烁光子的足够能量分辨率的同时,提供了从切伦科夫光子获得更精确时间信息的潜力。然而,将此类混合材料用于TOF PET应用的一个重大挑战在于,由于切伦科夫光子产量相对较低,切伦科夫光子和闪烁光子的混合检测会导致与事件相关的时间扩散。本研究引入了一种创新方法,即将耦合到单晶的硅光电倍增管(SiPM)像素进行分割,而不是使用尺寸与它们所读取的晶体一样大或更大的传统SiPM。我们证明,从分割后的SiPM获得的多个时间戳和光子计数可以通过提供时间光子密度来对事件进行分类,从而有效应对这一挑战。该方法和研究结果将为需要精确计时和光子计数的应用带来新机遇。