NuPET PET/MRI 嵌入式联用扫描仪
产品简介
详细信息
NuPET™ PET/MRI 嵌入式联用扫描仪
产品概述:
用于PET/MR成像的革命性的磁共振兼容PET扫描仪,允许同时测量体内的分子和功能过程,Cubresa的 NuPET™是一个革命性的 PET扫描仪,可插入到现有的MRI中,创建一个功能强大且灵活的混合临床前体内成像平台 ,将PET的分子灵敏度与MRI的优异解剖,结构和功能信息相结合。使用同步PET/MRI成像的研究人员可以同时测量多种生理过程,同时具有出色的组织对比度,定量准确度和研究通量。连续的PET/MRI扫描可以在不同的时间获取数据,当动物生理学在几分钟内发生变化时,难以分析重要的功能关系。通过NuPET的同步扫描,PET和MRI协同工作,捕捉以前无法达到的时间同步和高度互补的信息 - 这样您就可以开辟新的发现之路。
NuPET™ 技术特点:
√ 在你的MRI中同时进行全身小鼠和鼠脑成像
√ 支持广泛的MRI系统,包括高场模型,以及小动物梯度的使用
√ 可用的独立PET操作系统
√ 全自动的 PET/MRI 图像配准
√ 行业内最小尺寸
特别精确的PET / MR图像配准和配对的PET和MRI数据点引发了诸如基于MR的运动校正和部分容积校正(PVC)等增加PET定量准确性的进展。利用MRI的高软组织对比度,可以使用解剖数据准确绘制VOI,而无需猜测。较短的麻醉持续时间有助于减少动物的压力,并降低诱发可能影响研究质量的生理变化的风险。
技术原理:
对于生物的安装,Cubresa做了一个更大的套筒,适合于PET的插入。这个套筒有一个可充气的橡皮管,可以被抽上来。这个大套筒适合于核磁共振孔径的2或3毫米之内,然后使橡胶套筒被泵起以保持PET插入到位和减轻振动效果。该系统的工作流程包括用于从前端出口的核磁共振线圈的调谐棒。这使得动物,动物的处理,动物的定位和调优都可以从MRI的前部,节省时间和麻烦。对于这种MRI机械的安排,一个支持和锁条被设计成允许适合于一些定制的硬件孔槽。
应用领域:
神经科学—受体活性,功能药理学
肿瘤学—肿瘤特征及治疗反应评估
心脏病学—多参数功能和代谢评估
探针发展—“聪明”造影剂
应用案例
加拿大伦敦劳森研究
Cubresa在加拿大安大略省伦敦劳森研究所安装了NuPET系统用于临床前研究。该系统用于3T西门子生物图。Cubresa提供机械附件,西门子床可与PET插入一起使用。这个系统的工作流程很重要。停靠站位于外的房间由于病人安全问题,因此电缆来自滤板的板,通过核磁共振成像系统,并延伸到前面的MRI宠物准备插入和动物运动系统,如上图所示。
亚利桑那大学
亚利桑那大学有一个7T布鲁克尔系统和20厘米的孔。这些系统通常使用BGS- 12A渐变,内径为116毫米。Cubresa NuPET设计用于MRI,因此不需要外部套管。这个系统的工作流程从后面插入一个NuPET,从前面插入一个床系统。
NuPET™ 技术参数:
文献列表:
[1] Dr. Gregory Stortz (2016), “Development of a small animal MR compatible PET insert” (Doctoral Thesis). Department of Physics and Astronomy, University of British Columbia.
[2] Graham Schellenberg (2015), “An algorithm for automatic crystal identification in pixelated scintillation detectors using thin plate splines and Gaussian mixture models” (Master's Thesis). Department of Physics and Astronomy, University of Manitoba.
[3] Ehsan Shams (2014), “A slow control system with gain stabilization for a small animal MR –compatible PET insert” (Master's Thesis). Graduate Program in Biomedical Engineering, University of Manitoba.
[4] Chen-Yi Liu (2013), “Characterization of silicon photomultiplier readout designs for us in positron emission tomography systems” (Master's Thesis). Department of Physics & Astronomy, University of Manitoba.
[5] Leonid Lamwertz (2013), “Data acquisition and real-time signal processing in positron emission tomography” (Master's Thesis). Department of Electrical & Computer Engineering, University of Manitoba.
[6] Dr. Fazal ur-Rehman (2012), “Design and development of detector modules for a highly compact and portable preclinical PET system”, (DoctoralThesis). Department of Physics & Astronomy, University of Manitoba.
[7] C. J. Thompson et al., “Comparison of single and dual layer scintillator blocks for preclinical MRI-PET” IEEE Transactions on Nuclear Science, 2012
[8] X. Zhang et al., “Development and evaluation of a LOR-based image reconstruction with 3D system response modeling for a PET insert with dual-layer offset crystal design”, Physics in Medicine and Biology, 2013 Dec 7;58(23):8379-99.
[9] "Measurement of energy and timing resolution of very highly pixellated LYSO crystal blocks with multiplexed SiPMreadout for use in a small animal PET/MR insert", Christopher J. Thompson, Andrew L Goertzen, Poitr Kozlowski, Fabrice Retiere, Greg Stortz, Vesna Sossi, Xuezhu Zhang, Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC) 2013 IEEE, pp. 1-5, 2013.
[10] “Design and Performance of a resistor multiplexing readout circuit for a SiPMdetector array” Andrew L Goertzen, Xuezhu Zhang, Megan M McClarty, Eric J Berg, Chen-Yi Liu, Piotr Kozlowski, Fabrice Retière, Lawrence Ryner, Vesna Sossi, Greg Stortz, Christopher J Thompson, 2013/6, J. IEEE Trans. Nuc. Sci
[11] G. Stortz, M. D. Walker, C. J. Thompson, A. L. Goertzen, F. Retière, X. Zhang, J. D. Thiessen, P. Kozlowski, and V. Sossi, "Characterization of a New MR Compatible Small Animal PET Scanner Using Monte-Carlo Simulations," IEEE Trans. Nucl. Sci., vol. 60, no. 3, pp. 1637-1644, Jun. 2013.
[12] “A PET detector interface board and slow control system based on the Raspberry Pi®”, E. Shams et al, Nuc. Sci Symposium and Med Imaging Conference, 2013 IEEE
[13] Thiessen, J.D., Jackson, C., O’Neill, K., Bishop, D., Kozlowski, P., Retière, F., Sossi, V., Stortz, G., Thompson, C.J., & A.L. Goertzen. Performance Evaluation of SensL SiPMArrays for High-Resolution PET. 2013 IEEE Nuclear Science Symposium and Medical Imaging Conference Seoul, Korea, October
27, 2013.
[14] Zhang, X., Thompson, C.J., Thiessen, J.D., & A.L. Goertzen. “Simulations Studies of a Phoswich PET Detector Design with a Two-Fold Improvement in Spatial Sampling” 2013 IEEE Nuclear Science Symposium and Medical Imaging Conference Seoul, Korea, October 27, 2013.
[15] Thiessen, J.D., Berg, E., Liu, C.-Y., Bishop, D., Kozlowski, P., Retière, F., Sossi, V., Stortz, G., Thompson, C.J., Zhang, X., & A.L. Goertzen. MRCompatibility of a SiPM-Based PET Detector Module Using HDMI for Analog Readout and Power Supply. ISMRM 21st Annual Meeting and Exhibition
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