Microfabrication of position reference patterns onto glass microscope slides for high-accurate analysis of dynamic cellular events

TecnoLogicas Pub Date : 2017-05-15 DOI:10.22430/22565337.695
J. Galeano, P. Sandoz, A. Zarzycki, L. Robert, Juan Jaramillo
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引用次数: 0

Abstract

Glass microscopes slides are widely used as in situ base-substrates carrying diverse micro-fabricated systems or elements. For such purposes, the micro-fabrication process consists in transferring a pre-defined design onto the substrate made of a glass microscope slide. This is known as patterning, which is a technique that can also be used in transferring specific designs that allows region of interest (ROI) recovery under the microscope. In those cases, two main challenges appear: 1) Disturbances in light transmission should remain minimum to keep the high quality of observation of the object of interest under the microscope. 2) The pattern-size should then be small enough but, however, larger than the diffraction limit to be observable satisfactorily for positioning purposes. In this article, we present the procedures involved in the microfabrication of Pseudo-Periodic Patterns (PPP) encrypting the absolute position of an extended area. Those patterns are embedded in Petri dishes in order to allow the high-accurate retrieval of absolute position and orientation. The presented microfabrication is based in a technique known as lift-off, which after parameter adjustment, allows the obtaining of PPP fulfilling the two previously mentioned requirements. The results report on PPP realized on glass microscope slides and composed by 2µm side dots made of aluminum with a thickness of 30nm.
在玻璃显微镜载玻片上微加工位置参考图案,用于高精度分析动态细胞事件
玻璃显微镜载玻片被广泛用作承载各种微制造系统或元件的原位基底。为此,微制造工艺包括将预定义的设计转移到由玻璃显微镜载玻片制成的基板上。这被称为图案化,这是一种也可以用于转移特定设计的技术,可以在显微镜下恢复感兴趣区域(ROI)。在这些情况下,出现了两个主要挑战:1)光传输中的干扰应保持最小,以保持在显微镜下对感兴趣对象的高质量观察。2) 图案尺寸应足够小,但应大于衍射极限,以便出于定位目的而令人满意地观察到。在这篇文章中,我们介绍了伪周期图案(PPP)加密扩展区域绝对位置的微制造过程。这些模式被嵌入到培养皿中,以便能够高精度地检索绝对位置和方向。所提出的微制造基于一种称为剥离的技术,在参数调整后,可以获得满足前面提到的两个要求的PPP。PPP的结果报告在玻璃显微镜载玻片上实现,由厚度为30nm的铝制成的2µm侧点组成。
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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30
审稿时长
28 weeks
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