Investigation of Novel Preclinical Total Body PET Designed With J-PET Technology:A Simulation Study

arXiv - PHYS - Medical Physics Pub Date : 2024-08-01 DOI:arxiv-2408.00574

M. Dadgar, S. Parzych, F. Tayefi Ardebili, J. Baran, N. Chug, C. Curceanu, E. Czerwinski, K. Dulski, K. Eliyan, A. Gajos, B. C. Hiesmayr, K. Kacprzak, L. Kaplon, K. Klimaszewski, P. Konieczka, G. Korcyl, T. Kozik, W. Krzemien, D. Kumar, S. Niedzwiecki, D. Panek, E. Perez del Rio, L. Raczynski, S. Sharma, Shivani, R. Y. Shopa, M. Skurzok, K. Tayefi Ardebili, S. Vandenberghe, W. Wislicki, E. Stepien, P. Moskal

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Abstract

The growing interest in human-grade total body positron emission tomography (PET) systems has also application in small animal research. Due to the existing limitations in human-based studies involving drug development and novel treatment monitoring, animal-based research became a necessary step for testing and protocol preparation. In this simulation-based study two unconventional, cost-effective small animal total body PET scanners (for mouse and rat studies) have been investigated in order to inspect their feasibility for preclinical research. They were designed with the novel technology explored by the Jagiellonian-PET (J-PET) Collaboration. Two main PET characteristics: sensitivity and spatial resolution were mainly inspected to evaluate their performance. Moreover, the impact of the scintillator dimension and time-of-flight on the latter parameter was examined in order to design the most efficient tomographs. The presented results show that for mouse TB J-PET the achievable system sensitivity is equal to 2.35% and volumetric spatial resolution to 9.46 +- 0.54 mm3, while for rat TB J-PET they are equal to 2.6% and 14.11 +- 0.80 mm3, respectively. Furthermore, it was shown that the designed tomographs are almost parallax-free systems, hence, they resolve the problem of the acceptance criterion tradeoff between enhancing spatial resolution and reducing sensitivity.

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利用 J-PET 技术设计的新型临床前全身正电子发射计算机：模拟研究

人们对人体级全身正电子发射断层扫描（PET）系统的兴趣与日俱增，该系统在小动物研究中也有应用。由于涉及药物开发和新型治疗监测的人体研究存在局限性，基于动物的研究成为测试和方案准备的必要步骤。在这项基于模拟的研究中，对两台常规、经济高效的小动物全身 PET 扫描仪（用于小鼠和大鼠研究）进行了调查，以检验它们在临床前研究中的可行性。这些扫描仪的设计采用了 Jagiellonian-PET (J-PET) 协作组织探索的新技术。主要检查了 PET 的两个主要特性：灵敏度和空间分辨率，以评估其性能。此外，还研究了闪烁体尺寸和飞行时间对后一项参数的影响，以便设计出最高效的断层显像仪。研究结果表明，小鼠肺结核 J-PET 可达到的系统灵敏度为 2.35%，体积空间分辨率为 9.46 +- 0.54 立方毫米，而大鼠肺结核 J-PET 则分别为 2.6% 和 14.11 +- 0.80 立方毫米。此外，研究还表明，设计的断层成像仪几乎是无视差系统，因此解决了在提高空间分辨率和降低灵敏度之间权衡接受标准的问题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Medical Physics

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