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使用光学-正电子发射断层扫描(OPET)组合系统的断层生物发光成像:计算机模拟可行性研究。

Tomographic bioluminescence imaging by use of a combined optical-PET (OPET) system: a computer simulation feasibility study.

作者信息

Alexandrakis George, Rannou Fernando R, Chatziioannou Arion F

机构信息

David Geffen School of Medicine at UCLA, Crump Institute for Molecular Imaging, University of California, 700 Westwood Plaza, Los Angeles, CA 90095, USA.

出版信息

Phys Med Biol. 2005 Sep 7;50(17):4225-41. doi: 10.1088/0031-9155/50/17/021. Epub 2005 Aug 24.

DOI:10.1088/0031-9155/50/17/021
PMID:16177541
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1317109/
Abstract

The feasibility and limits in performing tomographic bioluminescence imaging with a combined optical-PET (OPET) system were explored by simulating its image formation process. A micro-MRI based virtual mouse phantom was assigned appropriate tissue optical properties to each of its segmented internal organs at wavelengths spanning the emission spectrum of the firefly luciferase at 37 degrees C. The TOAST finite-element code was employed to simulate the diffuse transport of photons emitted from bioluminescence sources in the mouse. OPET measurements were simulated for single-point, two-point and distributed bioluminescence sources located in different organs such as the liver, the kidneys and the gut. An expectation maximization code was employed to recover the intensity and location of these simulated sources. It was found that spectrally resolved measurements were necessary in order to perform tomographic bioluminescence imaging. The true location of emission sources could be recovered if the mouse background optical properties were known a priori. The assumption of a homogeneous optical property background proved inadequate for describing photon transport in optically heterogeneous tissues and led to inaccurate source localization in the reconstructed images. The simulation results pointed out specific methodological challenges that need to be addressed before a practical implementation of OPET-based bioluminescence tomography is achieved.

摘要

通过模拟其图像形成过程,探索了使用光学 - 正电子发射断层扫描(OPET)组合系统进行断层生物发光成像的可行性和局限性。基于微型磁共振成像的虚拟小鼠模型在37摄氏度下,为其每个分割的内部器官在萤火虫荧光素酶发射光谱的波长范围内赋予了适当的组织光学特性。使用TOAST有限元代码模拟小鼠体内生物发光源发射光子的扩散传输。对位于肝脏、肾脏和肠道等不同器官中的单点、两点和分布式生物发光源进行了OPET测量模拟。使用期望最大化代码来恢复这些模拟源的强度和位置。发现为了进行断层生物发光成像,光谱分辨测量是必要的。如果事先知道小鼠的背景光学特性,则可以恢复发射源的真实位置。事实证明,假设光学特性背景均匀不足以描述光子在光学异质组织中的传输,并且会导致重建图像中源定位不准确。模拟结果指出了在基于OPET的生物发光断层扫描实际应用之前需要解决的特定方法学挑战。

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