Carpenter Colin M, Ma Xiaowei, Liu Hongguang, Sun Conroy, Pratx Guillem, Wang Jing, Gambhir Sanjiv S, Xing Lei, Cheng Zhen
Department of Radiation Oncology, Stanford University, Stanford, California.
Canary Center at Stanford for Cancer Early Detection, Molecular Imaging Program at Stanford (MIPS), Department of Radiology and Bio-X Program, Stanford University, Stanford, California; and Department of Nuclear Medicine, Xijing Hospital, Fourth Military Medical University, Xi'an, Shaanxi, China
J Nucl Med. 2014 Nov;55(11):1905-9. doi: 10.2967/jnumed.114.139105. Epub 2014 Oct 9.
Cerenkov luminescence endoscopy (CLE) is an optical technique that captures the Cerenkov photons emitted from highly energetic moving charged particles (β(+) or β(-)) and can be used to monitor the distribution of many clinically available radioactive probes. A main limitation of CLE is its limited sensitivity to small concentrations of radiotracer, especially when used with a light guide. We investigated the improvement in the sensitivity of CLE brought about by using a β(-) radiotracer that improved Cerenkov signal due to both higher β-particle energy and lower γ noise in the imaging optics because of the lack of positron annihilation.
The signal-to-noise ratio (SNR) of (90)Y was compared with that of (18)F in both phantoms and small-animal tumor models. Sensitivity and noise characteristics were demonstrated using vials of activity both at the surface and beneath 1 cm of tissue. Rodent U87MG glioma xenograft models were imaged with radiotracers bound to arginine-glycine-aspartate (RGD) peptides to determine the SNR.
γ noise from (18)F was demonstrated by both an observed blurring across the field of view and a more pronounced fall-off with distance. A decreased γ background and increased energy of the β particles resulted in a 207-fold improvement in the sensitivity of (90)Y compared with (18)F in phantoms. (90)Y-bound RGD peptide produced a higher tumor-to-background SNR than (18)F in a mouse model.
The use of (90)Y for Cerenkov endoscopic imaging enabled superior results compared with an (18)F radiotracer.
切伦科夫发光内镜检查(CLE)是一种光学技术,可捕获高能移动带电粒子(β⁺或β⁻)发射的切伦科夫光子,并可用于监测许多临床可用放射性探针的分布。CLE的一个主要局限性是其对低浓度放射性示踪剂的敏感性有限,尤其是在与光导一起使用时。我们研究了使用β⁻放射性示踪剂带来的CLE灵敏度的提高,由于β粒子能量更高以及成像光学系统中因缺乏正电子湮灭而产生的γ噪声更低,这种示踪剂改善了切伦科夫信号。
在体模和小动物肿瘤模型中比较⁹⁰Y与¹⁸F的信噪比(SNR)。使用表面和组织下方1 cm处的活性小瓶展示灵敏度和噪声特征。用与精氨酸 - 甘氨酸 - 天冬氨酸(RGD)肽结合的放射性示踪剂对啮齿动物U87MG胶质瘤异种移植模型进行成像,以确定SNR。
¹⁸F产生的γ噪声表现为整个视野中观察到的模糊以及随距离更明显的衰减。γ本底降低和β粒子能量增加导致体模中⁹⁰Y的灵敏度比¹⁸F提高了207倍。在小鼠模型中,与¹⁸F相比,结合了⁹⁰Y的RGD肽产生了更高的肿瘤与本底SNR。
与¹⁸F放射性示踪剂相比,使用⁹⁰Y进行切伦科夫内镜成像能获得更好的结果。