Adaptive optical microscopy via virtual-imaging-assisted wavefront sensing for high-resolution tissue imaging

IF 15.7 Q1 OPTICS PhotoniX Pub Date : 2022-05-27 DOI:10.1186/s43074-022-00060-6
Zhou, Zhou, Huang, Jiangfeng, Li, Xiang, Gao, Xiujuan, Chen, Zhongyun, Jiao, Zhenfei, Zhang, Zhihong, Luo, Qingming, Fu, Ling
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引用次数: 6

Abstract

Adaptive optics (AO) is a powerful tool for optical microscopy to counteract the effects of optical aberrations and improve the imaging performance in biological tissues. The diversity of sample characteristics entails the use of different AO schemes to measure the underlying aberrations. Here, we present an indirect wavefront sensing method leveraging a virtual imaging scheme and a structural-similarity-based shift measurement algorithm to enable aberration measurement using intrinsic structures even with temporally varying signals. We achieved high-resolution two-photon imaging in a variety of biological samples, including fixed biological tissues and living animals, after aberration correction. We present AO-incorporated subtractive imaging to show that our method can be readily integrated with resolution enhancement techniques to obtain higher resolution in biological tissues. The robustness of our method to signal variation is demonstrated by both simulations and aberration measurement on neurons exhibiting spontaneous activity in a living larval zebrafish.

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自适应光学显微镜通过虚拟成像辅助波前传感高分辨率组织成像
自适应光学(AO)是光学显微镜消除光学像差影响和提高生物组织成像性能的有力工具。样本特征的多样性需要使用不同的AO方案来测量潜在的像差。在这里,我们提出了一种间接波前传感方法,利用虚拟成像方案和基于结构相似性的位移测量算法,即使具有时变信号,也可以使用固有结构进行像差测量。我们在各种生物样品中实现了高分辨率的双光子成像,包括固定生物组织和活体动物,经过像差校正。我们提出了ao结合的减影成像,表明我们的方法可以很容易地与分辨率增强技术相结合,以获得更高的生物组织分辨率。我们的方法对信号变化的鲁棒性通过模拟和畸变测量在活的斑马鱼幼虫中显示自发活动的神经元来证明。
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CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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