通过波前工程对深部组织中的生物动力学进行体内体积成像。
In vivo volumetric imaging of biological dynamics in deep tissue via wavefront engineering.
作者信息
Kong Lingjie, Tang Jianyong, Cui Meng
出版信息
Opt Express. 2016 Jan 25;24(2):1214-21. doi: 10.1364/OE.24.001214.
Abstract
Biological systems undergo dynamical changes continuously which span multiple spatial and temporal scales. To study these complex biological dynamics in vivo, high-speed volumetric imaging that can work at large imaging depth is highly desired. However, deep tissue imaging suffers from wavefront distortion, resulting in reduced Strehl ratio and image quality. Here we combine the two wavefront engineering methods developed in our lab, namely the optical phase-locked ultrasound lens based volumetric imaging and the iterative multiphoton adaptive compensation technique, and demonstrate in vivo volumetric imaging of microglial and mitochondrial dynamics at large depth in mouse brain cortex and lymph node, respectively.
摘要
生物系统不断经历跨越多个空间和时间尺度的动态变化。为了在体内研究这些复杂的生物动力学,非常需要能够在大成像深度工作的高速体积成像。然而,深层组织成像存在波前畸变问题,导致斯特列尔比和图像质量降低。在这里,我们结合了我们实验室开发的两种波前工程方法,即基于光学锁相超声透镜的体积成像和迭代多光子自适应补偿技术,并分别在小鼠大脑皮层和淋巴结的大深度处展示了小胶质细胞和线粒体动力学的体内体积成像。
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