Deep optical imaging within complex scattering media

显微镜 光学(聚焦) 光散射 散射 光学 消光(光学矿物学) 图像分辨率 分辨率(逻辑) 临床前影像学 光学成像 计算机科学 生物系统 物理 人工智能 生物 体内 生物技术
作者
Seokchan Yoon,Moonseok Kim,Mooseok Jang,Youngwoon Choi,Wonjun Choi,Sungsam Kang,Wonshik Choi
出处
期刊:Nature Reviews Physics [Nature Portfolio]
卷期号:2 (3): 141-158 被引量:410
标识
DOI:10.1038/s42254-019-0143-2
摘要

Optical imaging has had a central role in elucidating the underlying biological and physiological mechanisms in living specimens owing to its high spatial resolution, molecular specificity and minimal invasiveness. However, its working depth for in vivo imaging is extremely shallow, and thus reactions occurring deep inside living specimens remain out of reach. This problem originates primarily from multiple light scattering caused by the inhomogeneity of tissue obscuring the desired image information. Adaptive optical microscopy, which minimizes the effect of sample-induced aberrations, has to date been the most effective approach to addressing this problem, but its performance has plateaued because it can suppress only lower-order perturbations. To achieve an imaging depth beyond this conventional limit, there is increasing interest in exploiting the physics governing multiple light scattering. New approaches have emerged based on the deterministic measurement and/or control of multiple-scattered waves, rather than their stochastic and statistical treatment. In this Review, we provide an overview of recent developments in this area, with a focus on approaches that achieve a microscopic spatial resolution while remaining useful for in vivo imaging, and discuss their present limitations and future prospects. Optical microscopy is limited to shallow in vivo imaging depths owing to the exponential extinction of single-scattered waves by multiple light scattering. In this Review, we survey methodologies for deep optical imaging that maintain microscopic resolution by making deterministic use of multiple-scattered waves.
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