用于脑毛细血管体内成像的反射模式贝塞尔光束光声显微镜。

Reflection-mode Bessel-beam photoacoustic microscopy for in vivo imaging of cerebral capillaries.

作者信息

Jiang Bowen, Yang Xiaoquan, Luo Qingming

出版信息

Opt Express. 2016 Sep 5;24(18):20167-76. doi: 10.1364/OE.24.020167.

DOI:10.1364/OE.24.020167

Abstract

A reflection-mode Bessel-beam photoacoustic microscope (BB-PAM) is developed for the in vivo imaging of cerebral capillaries with extended depth of field (DoF). The non-diffraction characteristic of Bessel beams means that a larger DoF can be expected in the PAM compared to that using a Gaussian beam (GB). In our system, we generate the Bessel beam using an axicon and an annular mask. The lateral resolution of the system is estimated to be 1.6 μm. The DoF is measured to be 483 μm, and this is verified by imaging a carbon fiber network. The DoF of BB-PAM is about 7 times that of a GB-PAM. The cerebral vasculature of an open-skull mouse is imaged using the developed BB-PAM to demonstrate its in vivo imaging capability and advantages over GB-PAM.

摘要

为了对具有扩展景深（DoF）的脑毛细血管进行体内成像，开发了一种反射模式贝塞尔光束光声显微镜（BB-PAM）。贝塞尔光束的非衍射特性意味着与使用高斯光束（GB）的光声显微镜相比，BB-PAM有望获得更大的景深。在我们的系统中，我们使用轴锥镜和环形光阑生成贝塞尔光束。该系统的横向分辨率估计为1.6μm。测量得到的景深为483μm，通过对碳纤维网络成像进行了验证。BB-PAM的景深约为GB-PAM的7倍。使用所开发的BB-PAM对开颅小鼠的脑血管系统进行成像，以展示其体内成像能力以及相对于GB-PAM的优势。

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用于脑毛细血管体内成像的反射模式贝塞尔光束光声显微镜。

Reflection-mode Bessel-beam photoacoustic microscopy for in vivo imaging of cerebral capillaries.

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