视频速率共振扫描多光子显微镜:肿瘤微环境活体成像的新兴技术。

IntraVital Pub Date : 2012-01-01 DOI:10.4161/intv.21557
Nathaniel D Kirkpatrick, Euiheon Chung, Daniel C Cook, Xiaoxing Han, Gabriel Gruionu, Shan Liao, Lance L Munn, Timothy P Padera, Dai Fukumura, Rakesh K Jain
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引用次数: 49

摘要

异常的肿瘤微环境促进肿瘤的进展、转移、免疫抑制和治疗抵抗。在过去的几十年里,活体显微镜的发展和应用为肿瘤微环境的动态提供了前所未有的见解。特别是,活体多光子显微镜已经揭示了肿瘤相关血液和淋巴管的异常结构和功能,异常肿瘤基质在药物传递、肿瘤细胞的侵袭和转移中的作用,免疫细胞向肿瘤和肿瘤内运输的动力学以及肿瘤中的基因表达。然而,传统的多光子显微镜存在固有的慢成像速率问题——每秒只有几帧,因此无法捕捉更快速的事件,如血流、淋巴流动和血管内的细胞运动。在这里,我们报告了基于谐振振镜扫描的视频速率多光子显微镜(VR-MPLSM)的开发和实现,该显微镜能够以每秒30帧的速度记录并获取重要的多光谱图像。我们证明了该系统的设计可以很容易地实现,并适用于各种实验模型。作为例子,我们展示了该系统的实用性,可以直接测量肿瘤内的血流,捕捉在脑血管和淋巴管细胞内移动的转移性癌细胞,以及对血管网络变化的急性反应进行成像。因此,VR-MPLSM有可能进一步推进活体成像,并为肿瘤微环境的生物学提供新的见解。
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Video-rate resonant scanning multiphoton microscopy: An emerging technique for intravital imaging of the tumor microenvironment.

The abnormal tumor microenvironment fuels tumor progression, metastasis, immune suppression, and treatment resistance. Over last several decades, developments in and applications of intravital microscopy have provided unprecedented insights into the dynamics of the tumor microenvironment. In particular, intravital multiphoton microscopy has revealed the abnormal structure and function of tumor-associated blood and lymphatic vessels, the role of aberrant tumor matrix in drug delivery, invasion and metastasis of tumor cells, the dynamics of immune cell trafficking to and within tumors, and gene expression in tumors. However, traditional multiphoton microscopy suffers from inherently slow imaging rates-only a few frames per second, thus unable to capture more rapid events such as blood flow, lymphatic flow, and cell movement within vessels. Here, we report the development and implementation of a video-rate multiphoton microscope (VR-MPLSM) based on resonant galvanometer mirror scanning that is capable of recording at 30 frames per second and acquiring intravital multispectral images. We show that the design of the system can be readily implemented and is adaptable to various experimental models. As examples, we demonstrate the utility of the system to directly measure flow within tumors, capture metastatic cancer cells moving within the brain vasculature and cells in lymphatic vessels, and image acute responses to changes in a vascular network. VR-MPLSM thus has the potential to further advance intravital imaging and provide new insight into the biology of the tumor microenvironment.

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