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一种用于在小动物PET扫描仪中同时扫描两只大鼠的大鼠头部固定器:设计、构造、可行性测试和动力学验证

A rat head holder for simultaneous scanning of two rats in small animal PET scanners: design, construction, feasibility testing and kinetic validation.

作者信息

Cheng Tee Ean, Yoder Karmen K, Normandin Marc D, Risacher Shannon L, Converse Alexander K, Hampel Joseph A, Miller Michael A, Morris Evan D

机构信息

Biomedical Engineering Department, Purdue School of Engineering & Technology, Indianapolis, IN 46202, USA.

出版信息

J Neurosci Methods. 2009 Jan 15;176(1):24-33. doi: 10.1016/j.jneumeth.2008.08.031. Epub 2008 Sep 7.

Abstract

UNLABELLED

To reduce imaging costs, we designed a head holder for scanning two rats simultaneously in small animal PET scanners. Our goals were (i) to maintain high sensitivity and (ii) to minimize repositioning error between scans.

METHODS

A semi-stereotaxic dual rat head holder was designed and constructed for dual rat scanning in our IndyPET-II scanner and the commercial microPET P4. It was also used for single rat scanning in a small-bore, high-resolution animal scanner ("ISAP"). Positional repeatability was validated via multiple [11C]Raclopride scans of a single rat on different days. Accuracy of repositioning was determined by visual comparison of images, and by metrics derived through image alignment. Kinetic validation was assessed via analysis of [18F]Fluorodeoxyglucose ([18F]FDG) dynamic PET studies of six rats. Each rat was scanned twice: once individually, with brain positioned at the center of field of view (CFOV), and once with a partner, with brain away from CFOV. Both rats were injected with FDG during each dual rat session. Patlak uptake constants (Ki) were calculated from whole brain images. Effects of attenuation and scatter correction on single versus dual scan images were explored.

RESULTS

Image comparison and alignment metrics indicated excellent repositioning of rats. Scaled time-activity-curves from single and dual rat scans were indistinguishable. Average single and dual scan Ki values differed by only 6.3+/-7.5%.

CONCLUSION

Dual rat scanning in a semi-stereotaxic holder is practical for economical small animal scanning and does not compromise kinetic accuracy of [18F]FDG dynamic scan data.

摘要

未标注

为降低成像成本,我们设计了一种头部固定器,用于在小动物PET扫描仪中同时扫描两只大鼠。我们的目标是:(i)保持高灵敏度,以及(ii)将扫描之间的重新定位误差降至最低。

方法

设计并制造了一种半立体定向双大鼠头部固定器,用于在我们的IndyPET-II扫描仪和商业microPET P4中进行双大鼠扫描。它也用于在小口径高分辨率动物扫描仪(“ISAP”)中进行单只大鼠扫描。通过在不同日期对同一只大鼠进行多次[11C]雷氯必利扫描来验证位置重复性。通过图像的视觉比较以及通过图像配准得出的指标来确定重新定位的准确性。通过对六只大鼠的[18F]氟脱氧葡萄糖([18F]FDG)动态PET研究进行分析来评估动力学验证。每只大鼠扫描两次:一次单独扫描,将大脑置于视野中心(CFOV),另一次与同伴一起扫描,大脑远离CFOV。在每次双大鼠扫描过程中,两只大鼠都注射了FDG。从全脑图像计算Patlak摄取常数(Ki)。探讨了衰减和散射校正对单扫描与双扫描图像的影响。

结果

图像比较和配准指标表明大鼠的重新定位效果极佳。单只和双只大鼠扫描的缩放时间-活性曲线无法区分。单扫描和双扫描的平均Ki值仅相差6.3±7.5%。

结论

在半立体定向固定器中进行双大鼠扫描对于经济的小动物扫描是可行的,并且不会损害[18F]FDG动态扫描数据的动力学准确性。

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