Tomographic Fluorescent and Bioluminescent Optical Imaging

断层荧光和生物发光光学成像

• 批准号: 8247267
• 负责人: EDWARD J DELIKATNY
• 金额: $ 38.03万
• 依托单位: UNIVERSITY OF PENNSYLVANIA
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-09-01 至 2013-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8247267
• 关键词: Algorithms; Animals; Atlases; Biological Sciences; Core Facility; Custom; Diffuse; Fluorescence; Funding; Image; Lighting; Mus; Operative Surgical Procedures; Pennsylvania; Positron-Emission Tomography; Reporter; Request for Applications; Signal Transduction; Silicon Dioxide; Small Animal Imaging Systems; Source; System; Tissues; Ultrasonography; Universities; digital; fluorescence imaging; in vivo; instrument; lens; optical imaging; pre-clinical research; quantum; square foot; tomography; tool

DESCRIPTION (provided by applicant): This application requests funds for an IVIS Spectrum, an in vivo small animal imaging system for preclinical research use manufactured by Caliper Life Sciences (Hopkinton, MA). The IVIS Spectrum is an advanced in vivo imaging system for imaging of deep tissue bioluminescent and fluorescent sources in whole animals. It features an optimized set of high efficiency filters and spectral un-mixing algorithms that allow imaging of bioluminescent and fluorescent reporters across the blue to near infrared wavelengths. It also offers single- view 3D tomography for both fluorescent and bioluminescent reporters that can be analyzed in an anatomical context using a Digital Mouse Atlas. The IVIS Spectrum incorporates a custom fused silica 1 inch CCD with a FOV between 3.5 cm and 25 cm, a quantum efficiency of 85% between 500-700nm and a true f/1 lens. The combination of these specifications provides for highly sensitive bioluminescent imaging with a dynamic range of 11 orders of magnitude. For fluorescence imaging, the IVIS Spectrum can use either trans-illumination or epi-illumination to illuminate in vivo fluorescent sources. This capability allows 3D diffuse fluorescence tomography such that both source localization and concentration can be determined. The instrument is equipped with narrow band excitation and emission filters that assist in significantly reducing autofluorescence. In combination with the spectral unmixing tools, this allows the separation of signals from multiple fluorescent reporters within the same animal. The IVIS Spectrum will be available to multiple users as part of the Small Animal Imaging Facility (SAIF) at the University of Pennsylvania. It will be placed in the newly renovated 2,100 sq ft. Core Facility adjacent to the 9.4 T small animal MR, micro-PET and CT, and animal ultrasound systems, adjacent to a 400 cage animal vivarium with advanced animal handling and surgery rooms. The IVIS Spectrum will add considerable functionality to the SAIF at the University of Pennsylvania. PUBLIC HEALTH RELEVANCE: This application requests funds for an IVIS Spectrum system for preclinical optical imaging of mice. The system is unique in that it can provide three-dimensional bioluminescence and fluorescence images in a format that is easily co-registered with images from other modalities. The system will be located adjacent to existing small animal MRI and ultrasound scanners and used to develop and enhance multi-modality imaging in mouse models of human disease.

描述（由申请人提供）：本申请IVIS Spectrum的资金，IVIS Spectrum是由Caliper Life Sciences（Hopkinton，MA）制造的用于临床前研究的体内小动物成像系统。IVIS Spectrum是一种先进的体内成像系统，用于对整个动物体内的深层组织生物发光和荧光源进行成像。它具有一组优化的高效滤光片和光谱解混算法，允许在蓝色到近红外波长范围内对生物发光和荧光报告分子进行成像。它还提供了单视图三维断层扫描的荧光和生物发光报告，可以分析在解剖背景下使用数字鼠标地图集。IVIS Spectrum采用定制的熔融石英1英寸CCD，FOV在3.5 cm和25 cm之间，500- 700 nm之间的量子效率为85%，以及真正的f/1透镜。这些规格的组合提供了具有11个数量级的动态范围的高灵敏度生物发光成像。对于荧光成像，IVIS Spectrum可以使用透射照明或落射照明来照射体内荧光源。这种能力允许3D扩散荧光断层扫描，使得可以确定源定位和浓度。该仪器配备了窄带激发和发射滤光片，有助于显着减少自发荧光。与光谱解混工具相结合，这允许从同一动物内的多个荧光报告物分离信号。IVIS光谱将作为宾夕法尼亚大学小动物成像设施（SAIF）的一部分提供给多个用户。它将被放置在新装修的2,100平方英尺。核心设施毗邻9.4 T小动物MR、微型PET和CT以及动物超声系统，毗邻400笼动物饲养场，配有先进的动物处理和手术室。IVIS Spectrum将为宾夕法尼亚大学的SAIF增加相当多的功能。 公共卫生相关性：该申请要求为用于小鼠临床前光学成像的IVIS Spectrum系统提供资金。该系统的独特之处在于，它可以提供三维生物发光和荧光图像的格式，很容易与其他形式的图像共同注册。该系统将位于现有的小动物MRI和超声扫描仪附近，用于开发和增强人类疾病小鼠模型的多模态成像。