Smart computational light microscopes (SCLMs) of smart computational imaging laboratory (SCILab)

IF 15.7 Q1 OPTICS
Yao Fan, Jiaji Li, Linpeng Lu, Jiasong Sun, Yan Hu, Jialin Zhang, Zhuoshi Li, Qian Shen, Bowen Wang, Runnan Zhang, Qian Chen, C. Zuo
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引用次数: 40

Abstract

Computational microscopy, as a subfield of computational imaging, combines optical manipulation and image algorithmic reconstruction to recover multi-dimensional microscopic images or information of micro-objects. In recent years, the revolution in light-emitting diodes (LEDs), low-cost consumer image sensors, modern digital computers, and smartphones provide fertile opportunities for the rapid development of computational microscopy. Consequently, diverse forms of computational microscopy have been invented, including digital holographic microscopy (DHM), transport of intensity equation (TIE), differential phase contrast (DPC) microscopy, lens-free on-chip holography, and Fourier ptychographic microscopy (FPM). These computational microscopy techniques not only provide high-resolution, label-free, quantitative phase imaging capability but also decipher new and advanced biomedical research and industrial applications. Nevertheless, most computational microscopy techniques are still at an early stage of “proof of concept” or “proof of prototype” (based on commercially available microscope platforms). Translating those concepts to stand-alone optical instruments for practical use is an essential step for the promotion and adoption of computational microscopy by the wider bio-medicine, industry, and education community. In this paper, we present four smart computational light microscopes (SCLMs) developed by our laboratory, i.e., smart computational imaging laboratory (SCILab) of Nanjing University of Science and Technology (NJUST), China. These microscopes are empowered by advanced computational microscopy techniques, including digital holography, TIE, DPC, lensless holography, and FPM, which not only enables multi-modal contrast-enhanced observations for unstained specimens, but also can recover their three-dimensional profiles quantitatively. We introduce their basic principles, hardware configurations, reconstruction algorithms, and software design, quantify their imaging performance, and illustrate their typical applications for cell analysis, medical diagnosis, and microlens characterization.
智能计算成像实验室的智能计算光学显微镜
计算显微镜作为计算成像的一个子领域,结合光学操作和图像算法重建来恢复微观物体的多维微观图像或信息。近年来,发光二极管(LED)、低成本消费者图像传感器、现代数字计算机和智能手机的革命为计算显微镜的快速发展提供了丰富的机会。因此,已经发明了多种形式的计算显微镜,包括数字全息显微镜(DHM)、强度输运方程(TIE)、差分相位对比度(DPC)显微镜、无透镜片上全息术和傅立叶层析显微镜(FPM)。这些计算显微镜技术不仅提供了高分辨率、无标记、定量的相位成像能力,还可以解读新的先进生物医学研究和工业应用。尽管如此,大多数计算显微镜技术仍处于“概念验证”或“原型验证”的早期阶段(基于商用显微镜平台)。将这些概念转化为独立的光学仪器以供实际使用,是更广泛的生物医学、工业和教育界推广和采用计算显微镜的重要一步。本文介绍了我们实验室开发的四种智能计算光学显微镜,即南京科技大学的智能计算成像实验室。这些显微镜采用了先进的计算显微镜技术,包括数字全息术、TIE、DPC、无透镜全息术和FPM,不仅可以对未染色标本进行多模态对比增强观察,还可以定量恢复其三维轮廓。我们介绍了它们的基本原理、硬件配置、重建算法和软件设计,量化了它们的成像性能,并说明了它们在细胞分析、医学诊断和微透镜表征方面的典型应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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