图像由 Laurence Pelletier Lab, LTRI提供

A1 HD25 / A1R HD25

共聚焦显微镜

终止 Replaced by AX / AX R with NSPARC

应用笔记

Selecting the Right Objectives - Bright, Sharp Imaging of Structures down to Deep Areas

2021年6月

Spherical aberrations caused by a mismatch of refractive indices may lead to a reduction in image resolution and brightness, and are one of the key problems in imaging. In this application note, we will demonstrate the effects of spherical aberration using 3D imaging of an enteroid, which is a 3D culture system for small intestinal epithelial cells, as an example, and show how to select the appropriate immersion liquid and objective.

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3D Imaging of Intestinal Organoid

2021年6月

To perform high resolution observation of the deep regions of specimens during confocal imaging, selecting the objective is very important. This application note, prepared with the cooperation of Dr. Hidenori Akutsu and Dr. Tomoyuki Kawasaki of the Department of Reproductive Medicine, Center for Regenerative Medicine, National Center for Child Health and Development, will introduce an example of 3D imaging of a small intestine organoid using two different objectives, comparing the difference in image quality between them.

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Quantitative 3D Imaging of Living Organs-on-Chips with a High-Speed Point-Scanning Confocal System

2021年1月

Organs-on-chips more faithfully recapitulate the 3D architectural and functional complexity of native tissues compared to standard 2D tissue culture systems. Yet these advanced cell culture platforms present technical challenges for imaging-based applications. This Application Note demonstrates how the Nikon A1R HD25 confocal point-scanning system, CFI S Plan Fluor LWD 20XC objective and NIS-Elements software can enable rapid, deep, quantitative imaging of living cells in the Emulate Organ-Chip platform.

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A1R HD25:最新的共振扫描技术让新的活细胞成像方法成为可能

2019年2月

捕捉生命系统的动态图像需要高的图像采集帧率。大标本,例如整个模式生物,还需要大视野。尼康A1R HD25共聚焦系统两者都可兼顾,结合了尼康更新的高清高速共振扫描头和前所未有的25毫米视野。该系统的表现在斑马鱼胚胎应用上已经得到验证。

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通过最大化共聚焦视野来增加数据采集量和图像精确度

2018年11月

多年来,共聚焦系统的视野(FOV)受到它们搭载的显微镜的FOV限制。随着尼康 Ti2 倒置显微镜的发布,世界上第一个25毫米FOV得以实现。现在,尼康利用这个优势,开发了世界上最大FOV的点扫描头, A1 HD25。本应用手册重点介绍该技术对简单、日常实验的影响。

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