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相关概念视频

Imaging Biological Samples with Optical Microscopy01:18

Imaging Biological Samples with Optical Microscopy

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Optical microscopy uses optic principles to provide detailed images of samples. Antonie van Leeuwenhoek designed the first compound optical microscope in the 17th century to visualize blood cells, bacteria, and yeast cells. In 1830, Joseph Jackson Lister created an essentially modern light microscope. The 20th century saw the development of microscopes with enhanced magnification and resolution.
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Overview of Microscopy Techniques01:22

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The early pioneers of microscopy opened a window into the invisible world of microorganisms. In 1830, Joseph Jackson Lister created an essentially modern light microscope. The 20th century saw the development of microscopes that leveraged nonvisible light, such as fluorescence microscopy that uses an ultraviolet light source and electron microscopy that uses short-wavelength electron beams. These advances significantly improved magnification, image resolution, and contrast. By comparison, the...
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Cryo-electron Microscopy01:28

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Conventional electron microscopy (EM) involves dehydration, fixation, and staining of biological samples, which distorts the native state of biological molecules and results in several artifacts. Also, the high-energy electron beam damages the sample and makes it difficult to obtain high-resolution images. These issues can be addressed using cryo-EM, which uses frozen samples and gentler electron beams. The technique was developed by Jacques Dubochet, Joachim Frank, and Richard Henderson, for...
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Super-resolution Fluorescence Microscopy01:37

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Super-resolution fluorescence microscopy (SRFM) provides a better resolution than conventional fluorescence microscopy by reducing the point spread function (PSF). PSF is the light intensity distribution from a point that causes it to appear blurred. Due to PSF, each fluorescing point appears bigger than its actual size, and it is the PSF interference of nearby fluorophores that causes the blurred image. Various approaches to achieving higher resolution through SRFM have recently been...
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Electron Microscope Tomography and Single-particle Reconstruction01:07

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Transmission electron microscopy (TEM) can be used to determine the 3D structure of biological samples with the help of techniques such as electron microscope tomography and single-particle reconstruction. While single-particle reconstruction can examine macromolecules and macromolecular complexes in vitro conditions only, tomography permits the study of cell components or small cells in vivo.
Electron Tomography
Electron tomography can be performed either in TEM or STEM (scanning transmission...
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Overview of Electron Microscopy01:25

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The wavelengths of visible light ultimately limit the maximum theoretical resolution of images created by light microscopes. Most light microscopes can only magnify 1000X, and a few can magnify up to 1500X. Electrons, like electromagnetic radiation, can behave like waves, but with wavelengths of 0.005 nm, they produce significantly greater resolution up to 0.05 nm as compared to 500 nm for visible light. An electron microscope (EM) can create a sharp image that is magnified up to 2,000,000X.
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Visualizing Single Molecular Complexes In Vivo Using Advanced Fluorescence Microscopy
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作为一种工具,SERS显微镜可以在复杂样品中进行全面的生物化学表征.

Janina Kneipp1, Stephan Seifert2, Florian Gärber2

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此摘要是机器生成的。

表面增强拉曼散射 (SERS) 从微小的生物材料中提供生化见解. 本综述探讨了复杂样本中的SERS,数据分析以及用于增强分辨率的先进技术.

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科学领域:

  • 生物物理学的生物物理.
  • 频谱学是一种光谱学.
  • 生物化学 生物化学

背景情况:

  • 表面增强拉曼散射 (SERS) 能够在纳米尺度上对生物材料进行生化分析.
  • 细胞和组织等异质样本对SERS分析构成挑战.
  • 了解SERS因子对于准确的生化信息检索至关重要.

研究的目的:

  • 在复杂的生物有机样本中审查影响SERS实验的因素.
  • 讨论微观设置和先进技术中的SERS应用.
  • 为SERS数据引入强大的数据分析工具,包括生物信息学和机器学习.

主要方法:

  • 探索SERS原则和生物相容环境.
  • 显微镜中的SERS光谱学的示例.
  • 将SERS与其他显微工具集成,以提高分辨率.
  • 生物信息学和机器学习方法的应用用于数据分析.

主要成果:

  • 确定影响生物样本SERS结果的关键因素.
  • 在各种微观配置中展示SERS的实用性.
  • 突出了先进数据分析的潜力,以解释复杂的SERS频谱.
  • 展示机器学习用于超越分类的化学信息提取.

结论:

  • 塞尔斯是一个强大的工具,用于生物材料的纳米生化分析.
  • 优化SERS实验和数据分析对于可靠的结果至关重要.
  • 生物信息学和机器学习为先进的SERS数据解释提供了有前途的途径.