使用具有直接焦点传感和整形功能的自适应光学进行深层组织多光子成像。

Deep tissue multi-photon imaging using adaptive optics with direct focus sensing and shaping.

作者信息

Qin Zhongya, She Zhentao, Chen Congping, Wu Wanjie, Lau Jackie K Y, Ip Nancy Y, Qu Jianan Y

机构信息

Department of Electronic and Computer Engineering, The Hong Kong University of Science and Technology, Kowloon, Hong Kong, China.

Division of Life Science, The Hong Kong University of Science and Technology, Kowloon, Hong Kong, China.

出版信息

Nat Biotechnol. 2022 Nov;40(11):1663-1671. doi: 10.1038/s41587-022-01343-w. Epub 2022 Jun 13.

DOI:10.1038/s41587-022-01343-w

PMID:35697805

Abstract

High-resolution optical imaging deep in tissues is challenging because of optical aberrations and scattering of light caused by the complex structure of living matter. Here we present an adaptive optics three-photon microscope based on analog lock-in phase detection for focus sensing and shaping (ALPHA-FSS). ALPHA-FSS accurately measures and effectively compensates for both aberrations and scattering induced by specimens and recovers subcellular resolution at depth. A conjugate adaptive optics configuration with remote focusing enables in vivo imaging of fine neuronal structures in the mouse cortex through the intact skull up to a depth of 750 µm below the pia, enabling near-non-invasive high-resolution microscopy in cortex. Functional calcium imaging with high sensitivity and high-precision laser-mediated microsurgery through the intact skull were also demonstrated. Moreover, we achieved in vivo high-resolution imaging of the deep cortex and subcortical hippocampus up to 1.1 mm below the pia within the intact brain.

摘要

由于光学像差以及生物活体复杂结构所导致的光散射，在组织深处进行高分辨率光学成像具有挑战性。在此，我们展示了一种基于模拟锁相相位检测的自适应光学三光子显微镜，用于焦点传感与整形（ALPHA-FSS）。ALPHA-FSS能够精确测量并有效补偿由样本引起的像差和散射，在深度方向上恢复亚细胞分辨率。具有远程聚焦功能的共轭自适应光学配置，可通过完整头骨对小鼠皮层中精细的神经元结构进行活体成像，深度可达软脑膜以下750微米，实现了皮层近乎无创的高分辨率显微镜检查。还展示了通过完整头骨进行的高灵敏度功能钙成像以及高精度激光介导的显微手术。此外，我们在完整大脑内实现了对软脑膜以下深达1.1毫米的皮层深部和皮层下海马体的活体高分辨率成像。

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使用具有直接焦点传感和整形功能的自适应光学进行深层组织多光子成像。

Deep tissue multi-photon imaging using adaptive optics with direct focus sensing and shaping.

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