Sheth Rahul A, Upadhyay Rabi, Weissleder Ralph, Mahmood Umar
Center for Molecular Imaging Research, Massachusetts General Hospital, Harvard Medical School, Boston, MA 02114, USA.
Mol Imaging. 2007 May-Jun;6(3):147-55.
To address the need for a clinically applicable intravital optical imaging system, we developed a new hardware and software framework. We demonstrate its utility by applying it to an endoscope-based white light and fluorescent imaging system. The capabilities include acquisition and visualization algorithms that perform registration, segmentation, and histogram-based autoexposure of two imaging channels (full-spectrum white light and near-infrared fluorescence), all in real time. Data are processed and saved as 12-bit files, matching the standards of clinical imaging. Dynamic range is further improved by the evaluation of flux as a quantitative parameter. The above features are demonstrated in a series of in vitro experiments, and the in vivo application is shown with the visualization of fluorescent-labeled vasculature of a mouse peritoneum. The approach may be applied to diverse systems, including handheld devices, fixed geometry intraoperative devices, catheter-based imaging, and multimodal systems.
为满足临床适用的活体光学成像系统的需求,我们开发了一种新的硬件和软件框架。我们通过将其应用于基于内窥镜的白光和荧光成像系统来展示其效用。其功能包括采集和可视化算法,可实时对两个成像通道(全光谱白光和近红外荧光)进行配准、分割以及基于直方图的自动曝光。数据被处理并保存为12位文件,符合临床成像标准。通过将通量作为定量参数进行评估,进一步提高了动态范围。上述特性在一系列体外实验中得到了证明,并且在体内应用中展示了对小鼠腹膜荧光标记血管的可视化。该方法可应用于多种系统,包括手持设备、固定几何形状的术中设备、基于导管的成像以及多模态系统。