Nanoscale Surface Metal-Coating Method without Pretreatment for High-Magnification Biological Observation and Applications.

IF 3.4 3区 医学 Q1 ENGINEERING, MULTIDISCIPLINARY Biomimetics Pub Date : 2024-09-28 DOI:10.3390/biomimetics9100588
Kenshin Takemura, Taisei Motomura, Yuko Takagi
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Abstract

Biospecimen imaging is essential across various fields. In particular, a considerable amount of research has focused on developing pretreatment techniques, ranging from freeze-drying to the use of highly conductive polymers, and on advancements in instrumentation, such as cryogenic electron microscopy. These specialized techniques and equipment have facilitated nanoscale and microscale bioimaging. However, user access to these environments remains limited. This study introduced a novel technique to achieve high conductivity in bioimaging by employing a magnetically controlled sputtering cathode to facilitate low-temperature deposition and low-electron bombardment. This approach allows for the convenient high-magnification observation of highly structured three-dimensional specimens, such as pill bugs and butterfly wings, and fragile specimens, such as single-cell protozoan parasites, using metal deposition only. Furthermore, it is easily accessible in the field of bioimaging because it does not require any pretreatment and enables surface analysis of biospecimens with an electron microscope using only a single pretreatment process. Protozoa, which are microorganisms, were successfully observed at high magnification without structural changes due to thermal denaturation. Furthermore, metallic film deposition and electrochemical signal measurements using these metallic films were achieved in pill bugs.

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无需预处理的纳米级表面金属涂层法,用于高倍率生物观察和应用。
生物样本成像在各个领域都至关重要。特别是,大量研究集中于开发预处理技术,从冷冻干燥到使用高导电聚合物,以及仪器的进步,如低温电子显微镜。这些专业技术和设备为纳米级和微米级生物成像提供了便利。然而,用户进入这些环境的机会仍然有限。本研究引入了一种新技术,通过采用磁控溅射阴极来促进低温沉积和低电子轰击,从而在生物成像中实现高导电性。这种方法只需使用金属沉积,就能方便地高倍观察高度结构化的三维标本(如药虫和蝴蝶翅膀)和易碎标本(如单细胞原生动物寄生虫)。此外,由于无需任何预处理,只需一道预处理工序就能用电子显微镜对生物标本进行表面分析,因此在生物成像领域很容易实现。在高倍率下成功观察到微生物原生动物,而不会因热变性而导致结构变化。此外,还在药丸虫体内实现了金属膜沉积和使用这些金属膜进行电化学信号测量。
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
Biomimetics
Biomimetics Biochemistry, Genetics and Molecular Biology-Biotechnology
CiteScore
3.50
自引率
11.10%
发文量
189
审稿时长
11 weeks
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