Correlative light-electron microscopy
Correlative light-electron microscopy (CLEM) is the combination of an optical microscope - usually a fluorescence microscope - with an electron microscope. In an integrated CLEM system, the sample is imaged using an electron beam and an optical light path simultaneously. Traditionally, samples would be imaged using two separate microscopy modalities, potentially at different facilities and using different sample preparation methods. Integrated CLEM is thus considered to be beneficial because the methodology is quicker and easier, and it reduces the chance of changes in the sample during the process of data collection. Overlay of the two images is thus performed automatically as a result of the integration of two microscopes.[1]
This technique is used in order to obtain information at different length scales: the electron microscope provides high-resolution information down to the nano-scale, while the fluorescence microscope highlights the regions of interest. CLEM is used for various disciplines in the life sciences, including neuroscience, tissue research, and protein research.[2]
Fluorescence microscope
In preparation for imaging with a fluorescence microscope, different methods can be used, such as fluorophores or dyes, immunolabeling, and genetically encoded fluorescent proteins. Different fluorescent labels can be used in order to highlight multiple regions of interest in the sample.[3]
Electron microscope
The electron microscope is used to obtain structural information at the nano-scale. Unlike an optical microscope, an electron microscope is able to surpass the diffraction limit of light. This is because the wavelength of accelerated electrons is much shorter than the wavelength of light.[4]
References
- ↑ BV, DELMIC. "Automated Overlay - Technical Note | DELMIC". request.delmic.com. Retrieved 2017-02-08.
- ↑ "CELL BIOLOGY/CORRELATIVE MICROSCOPY: A powerful pairing for cell studies: Correlative light and electron microscopy". 2014-05-19.
- ↑ "What is Correlative Light and Electron Microscopy?". 2017-01-13.
- ↑ Voortman, Lenard (2014). "Integration without compromise". Microscopy Today. 22: 30–35.
Further reading
- de Boer, Pascal, Jacob P. Hoogenboom, and Ben NG Giepmans. "Correlated light and electron microscopy: ultrastructure lights up!" Nature methods 12.6 (2015): 503-513.
- Brama, Elisabeth, et al. "Standard fluorescent proteins as dual-modality probes for correlative experiments in an integrated light and electron microscope." Journal of Chemical Biology 8.4 (2015): 179-188.
- Debroye, Elke, et al. "Assessing Photocatalytic Activity at the Nanoscale Using Integrated Optical and Electron Microscopy". Particle & Particle Systems Characterization. 33.7 (2016): 412 - 418.
- Huan, Y. et al. "Photoluminescence Blinking of Single-Crystal Methylammonium Lead Iodide Perovskite Nanorods Induced by Surface Traps", ACS Omega 1 (1), 148–159 (2016)
- Liv, Nalan, et al. "Electron microscopy of living cells during in-situ fluorescence microscopy", ACS Nano 10, 265-273 (2016)
- Liv, Nalan, et al. "Simultaneous correlative scanning electron and high-NA fluorescence microscopy." PLoS One 8.2 (2013): e55707.
- Liv, Nalan, et al. "Scanning electron microscopy of individual nanoparticle bio-markers in liquid." Ultramicroscopy 143 (2014): 93-99.
- Peddie, Christopher J., et al. "Integrated light and scanning electron microscopy of GFP-expressing cells." Methods in cell biology 124 (2014): 363-389.
- Peddie, Christopher J., et al. "Correlative and integrated light and electron microscopy of in-resin GFP fluorescence, used to localise diacylglycerol in mammalian cells." Ultramicroscopy 143 (2014): 3-14.
- Sueters-di Meo, J., et al. "Using advanced correlative microscopy to study complex biological samples in Encyclopedia of Analytical Chemistry", eds R.A. Meyers, John Wiley: Chichester, a9473 (2016)
- Voorneveld, Philip W., et al. "Loss of SMAD4 alters BMP signaling to promote colorectal cancer cell metastasis via activation of Rho and ROCK." Gastroenterology 147.1 (2014): 196-208.
- Yuan, Haifeng, et al. "Degradation of Methylammonium Lead Iodide Perovskite Structures through Light and Electron Beam Driven Ion Migration." The Journal of Physical Chemistry Letters 7 (2016): 561-566.
- Zonnevylle, A. C., et al. "Integration of a high-NA light microscope in a scanning electron microscope." Journal of microscopy 252.1 (2013): 58-70.