Electron microscope

An electron microscope is a microscope that uses a beam of electrons as a source of illumination. They use electron optics that are analogous to the glass lenses of an optical light microscope to control the electron beam, for instance focusing them to produce magnified images or electron diffraction patterns. As the wavelength of an electron can be up to 100,000 times smaller than that of visible light, electron microscopes have a much higher resolution of about 0.1 nm, which compares to about 200 nm for light microscopes. Electron microscope may refer to:

A modern transmission electron microscope
An image of an ant in a scanning electron microscope

Additional details can be found in the above links. This articles contains some general information mainly about transmission electron microscopes.

History

Reproduction of an early electron microscope constructed by Ernst Ruska

Many developments laid the groundwork of the electron optics used in microscopes.[1] One significant step was the work of Hertz in 1883[2] who made a cathode-ray tube with electrostatic and magnetic deflection, demonstrating manipulation of the direction of an electron beam. Others were focusing of the electrons by an axial magnetic field by Emil Wiechert in 1899,[3] improved oxide-coated cathodes which produced more electrons by Arthur Wehnelt in 1905[4] and the development of the electromagnetic lens in 1926 by Hans Busch.[5] According to Dennis Gabor, the physicist Leó Szilárd tried in 1928 to convince him to build an electron microscope, for which Szilárd had filed a patent.[6]

To this day the issue of who invented the transmission electron microscope is controversial.[7][8][9][10] In 1928, at the Technical University of Berlin, Adolf Matthias (Professor of High Voltage Technology and Electrical Installations) appointed Max Knoll to lead a team of researchers to advance research on electron beams and cathode-ray oscilloscopes. The team consisted of several PhD students including Ernst Ruska. In 1931, Max Knoll and Ernst Ruska[11][12] successfully generated magnified images of mesh grids placed over an anode aperture. The device, a replicate of which is shown in the figure, used two magnetic lenses to achieve higher magnifications, the first electron microscope. (Max Knoll died in 1969, so did not receive a share of the 1986 Nobel prize for the invention of electron microscopes.)

Apparently independent of this effort was work at Siemens-Schuckert by Reinhold Rüdenberg. According to patent law (U.S. Patent No. 2058914[13] and 2070318,[14] both filed in 1932), he is the inventor of the electron microscope, but it is not clear when he had a working instrument. He stated in a very brief article in 1932[15] that Siemens had been working on this for some years before the patents were filed in 1932, claiming that his effort was parallel to the university development. He died in 1961, so similar to Max Knoll, was not eligible for a share of the 1986 Nobel prize.

In the following year, 1933, Ruska and Knoll built the first electron microscope that exceeded the resolution of an optical (light) microscope.[16] Four years later, in 1937, Siemens financed the work of Ernst Ruska and Bodo von Borries, and employed Helmut Ruska, Ernst's brother, to develop applications for the microscope, especially with biological specimens.[16][17] Also in 1937, Manfred von Ardenne pioneered the scanning electron microscope.[18] Siemens produced the first commercial electron microscope in 1938.[19] The first North American electron microscopes were constructed in the 1930s, at the Washington State University by Anderson and Fitzsimmons [20] and at the University of Toronto by Eli Franklin Burton and students Cecil Hall, James Hillier, and Albert Prebus. Siemens produced a transmission electron microscope (TEM) in 1939.[21] Although current transmission electron microscopes are capable of two million timea magnification, as scientific instruments they remain similar but with improved optics.

Wavelength

Diagram illustrating the phenomena resulting from the interaction of energetic electrons with matter

In a typical electron gun, individual electrons, which have an elementary charge (about coulombs) and a mass (about  kg), with a potential of volts, have an energy amount of joules. The wavelength is[22]

,

where is the speed of light in vacuum (about  m/s). See electron diffraction for a full explanation.

Types

Transmission electron microscope (TEM)

The original form of the electron microscope, the transmission electron microscope (TEM), uses a high voltage electron beam to illuminate the specimen and create an image. An electron beam is produced by an electron gun, with the electrons typically at 40 to 400 keV, focused by electromagnetic lenses, and transmitted through the specimen. When it emerges from the specimen, the electron beam carries information about the structure of the specimen that is magnified by lenses of the microscope. The spatial variation in this information (the "image") may be viewed by projecting the magnified electron image onto a detector. For example, the image may be viewed directly by an operator using a fluorescent viewing screen coated with a phosphor or scintillator material such as zinc sulfide. A high-resolution phosphor may also be coupled by means of a lens optical system or a fibre optic light-guide to the sensor of a digital camera. Direct electron detectors have no scintillator and are directly exposed to the electron beam, which addresses some of the limitations of scintillator-coupled cameras.[23]

The resolution of TEMs is limited primarily by spherical aberration, but a new generation of hardware correctors can reduce spherical aberration to increase the resolution in high-resolution transmission electron microscopy (HRTEM) to below 0.5 angstrom (50 picometres),[24] enabling magnifications above 50 million times.[25] The ability of HRTEM to determine the positions of atoms within materials is useful for nano-technologies research and development.[26]

Transmission electron microscopes are often used in electron diffraction mode. The advantages of electron diffraction over X-ray crystallography are that the specimen need not be a single crystal or even a polycrystalline powder.

Scanning transmission electron microscope (STEM)

The STEM rasters a focused incident probe across a specimem. The high resolution of the TEM is thus possible in STEM. The focusing action (and aberrations) occur before the electrons hit the specimen in the STEM, but afterward in the TEM. The STEMs use of SEM-like beam rastering simplifies annular dark-field imaging, and other analytical techniques, but also means that image data is acquired in serial rather than in parallel fashion.

Scanning electron microscope (SEM)

Image of Bacillus subtilis taken with a 1960s electron microscope

The SEM produces images by probing the specimen with a focused electron beam that is scanned across the specimen (raster scanning). When the electron beam interacts with the specimen, it loses energy by a variety of mechanisms. The lost energy is converted into alternative forms such as heat, emission of low-energy secondary electrons and high-energy backscattered electrons, light emission (cathodoluminescence) or X-ray emission, all of which provide signals carrying information about the properties of the specimen surface, such as its topography and composition. The image displayed by an SEM maps the varying intensity of any of these signals into the image in a position corresponding to the position of the beam on the specimen when the signal was generated. In the SEM image of an ant shown, the image was constructed from signals produced by a secondary electron detector, the normal or conventional imaging mode in most SEMs.

Generally, the image resolution of an SEM is lower than that of a TEM. However, because the SEM images the surface of a sample rather than its interior, the electrons do not have to travel through the sample. This reduces the need for extensive sample preparation to thin the specimen to electron transparency. The SEM also has a great depth of field, and so can produce images that are good representations of the three-dimensional surface shape of the sample.

In their most common configurations, electron microscopes produce images with a single brightness value per pixel, with the results usually rendered in greyscale.[27] However, often these images are then colourized through the use of feature-detection software, or simply by hand-editing using a graphics editor. This may be done to clarify structure or for aesthetic effect and generally does not add new information about the specimen.[28]

Sample preparation for TEM

An insect coated in gold for viewing with a scanning electron microscope

Materials to be viewed in a transmission electron microscope may require processing to produce a suitable sample. The technique required varies depending on the specimen and the analysis required:

  • Cryofixation – freezing a specimen so that the water forms vitreous (non-crystalline) ice. This preserves the specimen in a snapshot of its native state. Methods to achieve this vitrification include plunge freezing rapidly in liquid ethane, and high pressure freezing. An entire field called cryo-electron microscopy has branched from this technique. With the development of cryo-electron microscopy of vitreous sections (CEMOVIS)[30] and cryo-focused ion beam milling of lamellae,[31] it is now possible to observe samples from virtually any biological specimen close to its native state.
  • Dehydration – replacement of water with organic solvents such as ethanol or acetone, followed by critical point drying or infiltration with embedding resins. See also freeze drying.
  • Embedding, biological specimens – after dehydration, tissue for observation in the transmission electron microscope is embedded so it can be sectioned ready for viewing. To do this the tissue is passed through a 'transition solvent' such as propylene oxide (epoxypropane) or acetone and then infiltrated with an epoxy resin such as Araldite, Epon, or Durcupan;[32] tissues may also be embedded directly in water-miscible acrylic resin. After the resin has been polymerized (hardened) the sample is sectioned by ultramicrotomy and stained.
  • Embedding, materials – after embedding in resin, the specimen is usually ground and polished to a mirror-like finish using ultra-fine abrasives.
  • Freeze-fracture or freeze-etch – a preparation method[33][34][35] particularly useful for examining lipid membranes and their incorporated proteins in "face on" view.[36][37][38]
    Freeze-fracturing helps to peel open membranes to allow visualization of what is inside
    External face of bakers yeast membrane showing the small holes where proteins are fractured out, sometimes as small ring patterns.
    The fresh tissue or cell suspension is frozen rapidly (cryofixation), then fractured by breaking[39] (or by using a microtome)[38] while maintained at liquid nitrogen temperature. The cold fractured surface (sometimes "etched" by increasing the temperature to about −100 °C for several minutes to let some ice sublime)[38] is then shadowed with evaporated platinum or gold at an average angle of 45° in a high vacuum evaporator. The second coat of carbon, evaporated perpendicular to the average surface plane is often performed to improve the stability of the replica coating. The specimen is returned to room temperature and pressure, then the extremely fragile "pre-shadowed" metal replica of the fracture surface is released from the underlying biological material by careful chemical digestion with acids, hypochlorite solution or SDS detergent. The still-floating replica is thoroughly washed free from residual chemicals, carefully fished up on fine grids, dried then viewed in the TEM.
  • Freeze-fracture replica immunogold labeling (FRIL) – the freeze-fracture method has been modified to allow the identification of the components of the fracture face by immunogold labeling. Instead of removing all the underlying tissue of the thawed replica as the final step before viewing in the microscope the tissue thickness is minimized during or after the fracture process. The thin layer of tissue remains bound to the metal replica so it can be immunogold labeled with antibodies to the structures of choice. The thin layer of the original specimen on the replica with gold attached allows the identification of structures in the fracture plane.[40] There are also related methods which label the surface of etched cells[41] and other replica labeling variations.[42]
  • Ion beam milling – thins samples until they are transparent to electrons by firing ions (typically argon) at the surface from an angle and sputtering material from the surface. A subclass of this is focused ion beam milling, where gallium ions are used to produce an electron transparent membrane or 'lamella' in a specific region of the sample, for example through a device within a microprocessor or a focused ion beam SEM. Ion beam milling may also be used for cross-section polishing prior to analysis of materials that are difficult to prepare using mechanical polishing.
  • Negative stain – suspensions containing nanoparticles or fine biological material (such as viruses and bacteria) are briefly mixed with a dilute solution of an electron-opaque solution such as ammonium molybdate, uranyl acetate (or formate), or phosphotungstic acid. This mixture is applied to an EM grid, pre-coated with a plastic film such as formvar, blotted, then allowed to dry. Viewing of this preparation in the TEM should be carried out without delay for best results. The method is important in microbiology for fast but crude morphological identification, but can also be used as the basis for high-resolution 3D reconstruction using EM tomography methodology when carbon films are used for support. Negative staining is also used for observation of nanoparticles.
  • Sectioning – produces thin slices of the specimen, semitransparent to electrons. These can be cut using ultramicrotomy on an ultramicrotome with a glass or diamond knife to produce ultra-thin sections about 60–90 nm thick. Disposable glass knives are also used because they can be made in the lab and are much cheaper. Sections can also be created in situ by milling in a focused ion beam SEM, where the section is known as a lamella.[31]
  • Staining – uses heavy metals such as lead, uranium or tungsten to scatter imaging electrons and thus give contrast between different structures, since many (especially biological) materials are nearly "transparent" to electrons (weak phase objects). In biology, specimens can be stained "en bloc" before embedding and also later after sectioning. Typically thin sections are stained for several minutes with an aqueous or alcoholic solution of uranyl acetate followed by aqueous lead citrate.[43]

EM workflows

Early electron microscopy of biological specimens was often descriptive, making use of the newly available higher resolution.[44] This is still the case for various applications, such as diagnostic electron microscopy.

However, electron microscopes are now frequently used in more complex workflows, with each workflow typically using multiple technologies to enable more complex and/or more quantitative analyses of a sample. A few examples are outlined below, but this should not be considered an exhaustive list. The choice of workflow will be highly dependent on the application and the requirements of the corresponding scientific questions, such as resolution, volume, nature of the target molecule, etc.

For example, images from light and electron microscopy of the same region of a sample can be overlaid to correlate the data from the two modalities. This is commonly used to provide higher resolution contextual EM information about a fluorescently labelled structure. This correlative light and electron microscopy (CLEM)[45] is one of a range of correlative workflows now available. Another example is high resolution mass spectrometry (ion microscopy), which has been used to provide correlative information about subcellular antibiotic localisation,[46] data that would be difficult to obtain by other means.

The initial role of electron microscopes in imaging two-dimensional slices (TEM) or a specimen surface (SEM with secondary electrons) has also increasingly expanded into the depth of samples.[47] An early example of these ‘volume EM’ workflows was simply to stack TEM images of serial sections cut through a sample. The next development was virtual reconstruction of a thick section (200-500 nm) volume by backprojection of a set of images taken at different tilt angles - TEM tomography.[48]

Serial imaging for volume EM

To acquire volume EM datasets of larger depths than TEM tomography (micrometers or millimeters in the z axis), a series of images taken through the sample depth can be used. For example, ribbons of serial sections can be imaged in a TEM as described above, and when thicker sections are used, serial TEM tomography can be used to increase the z-resolution. More recently, back scattered electron (BSE) images can be acquired of a larger series of sections collected on silicon wafers, known as SEM array tomography.[49][50] An alternative approach is to use BSE SEM to image the block surface instead of the section, after each section has been removed. By this method, an ultramicrotome installed in an SEM chamber can increase automation of the workflow; the specimen block is loaded in the chamber and the system programmed to continuously cut and image through the sample. This is known as serial block face SEM.[51] A related method uses focused ion beam milling instead of an ultramicrotome to remove sections. In these serial imaging methods, the output is essentially a sequence of images through a specimen block that can be digitally aligned in sequence and thus reconstructed into a volume EM dataset. The increased volume available in these methods has expanded the capability of electron microscopy to address new questions,[47] such as mapping neural connectivity in the brain,[52] and membrane contact sites between organelles.[53]

Disadvantages

JEOL transmission and scanning electron microscope made in the mid-1970s

Electron microscopes are expensive to build and maintain. Microscopes designed to achieve high resolutions must be housed in stable buildings (sometimes underground) with special services such as magnetic field canceling systems.

The samples largely have to be viewed in vacuum, as the molecules that make up air would scatter the electrons. An exception is liquid-phase electron microscopy[54] using either a closed liquid cell or an environmental chamber, for example, in the environmental scanning electron microscope, which allows hydrated samples to be viewed in a low-pressure (up to 20 Torr or 2.7 kPa) wet environment. Various techniques for in situ electron microscopy of gaseous samples have been developed.[55]

Scanning electron microscopes operating in conventional high-vacuum mode usually image conductive specimens; therefore non-conductive materials require conductive coating (gold/palladium alloy, carbon, osmium, etc.). The low-voltage mode of modern microscopes makes possible the observation of non-conductive specimens without coating. Non-conductive materials can be imaged also by a variable pressure (or environmental) scanning electron microscope.

Small, stable specimens such as carbon nanotubes, diatom frustules and small mineral crystals (asbestos fibres, for example) require no special treatment before being examined in the electron microscope. Samples of hydrated materials, including almost all biological specimens, have to be prepared in various ways to stabilize them, reduce their thickness (ultrathin sectioning) and increase their electron optical contrast (staining). These processes may result in artifacts, but these can usually be identified by comparing the results obtained by using radically different specimen preparation methods. Since the 1980s, analysis of cryofixed, vitrified specimens has also become increasingly used by scientists, further confirming the validity of this technique.[56][57][58]

See also

References

  1. Calbick, C. J. (1944). "Historical Background of Electron Optics". Journal of Applied Physics. 15 (10): 685–690. Bibcode:1944JAP....15..685C. doi:10.1063/1.1707371. ISSN 0021-8979.
  2. Hertz, Heinrich (2019), "Introduction to Heinrich Hertz's Miscellaneous Papers (1895) by Philipp Lenard", Heinrich Rudolf Hertz (1857-1894), Routledge, pp. 87–88, doi:10.4324/9780429198960-4, ISBN 978-0-429-19896-0, S2CID 195494352, retrieved 2023-02-24
  3. Wiechert, E. (1899). "Experimentelle Untersuchungen über die Geschwindigkeit und die magnetische Ablenkbarkeit der Kathodenstrahlen". Annalen der Physik und Chemie (in German). 305 (12): 739–766. Bibcode:1899AnP...305..739W. doi:10.1002/andp.18993051203.
  4. Wehnelt, A. (1905). "X. On the discharge of negative ions by glowing metallic oxides, and allied phenomena". The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science. 10 (55): 80–90. doi:10.1080/14786440509463347. ISSN 1941-5982.
  5. Busch, H. (1926). "Berechnung der Bahn von Kathodenstrahlen im axialsymmetrischen elektromagnetischen Felde". Annalen der Physik (in German). 386 (25): 974–993. Bibcode:1926AnP...386..974B. doi:10.1002/andp.19263862507.
  6. Dannen, Gene (1998) Leo Szilard the Inventor: A Slideshow (1998, Budapest, conference talk). dannen.com
  7. Mulvey, T (1962). "Origins and historical development of the electron microscope". British Journal of Applied Physics. 13 (5): 197–207. doi:10.1088/0508-3443/13/5/303. ISSN 0508-3443.
  8. Tao, Yaping (2018). "A Historical Investigation of the Debates on the Invention and Invention Rights of Electron Microscope". Proceedings of the 3rd International Conference on Contemporary Education, Social Sciences and Humanities (ICCESSH 2018). pp. 1438–1441. doi:10.2991/iccessh-18.2018.313. ISBN 978-94-6252-528-3. {{cite book}}: |journal= ignored (help)
  9. Freundlich, Martin M. (1963). "Origin of the Electron Microscope: The history of a great invention, and of a misconception concerning the inventors, is reviewed". Science. 142 (3589): 185–188. doi:10.1126/science.142.3589.185. ISSN 0036-8075. PMID 14057363.
  10. Rüdenberg, Reinhold (2010), Origin and Background of the Invention of the Electron Microscope, Advances in Imaging and Electron Physics, vol. 160, Elsevier, pp. 171–205, doi:10.1016/s1076-5670(10)60005-5, ISBN 9780123810175, retrieved 2023-02-11.
  11. Knoll, M.; Ruska, E. (1932). "Beitrag zur geometrischen Elektronenoptik. I". Annalen der Physik. 404 (5): 607–640. Bibcode:1932AnP...404..607K. doi:10.1002/andp.19324040506. ISSN 0003-3804.
  12. Knoll, M.; Ruska, E. (1932). "Das Elektronenmikroskop". Zeitschrift für Physik (in German). 78 (5–6): 318–339. Bibcode:1932ZPhy...78..318K. doi:10.1007/BF01342199. ISSN 1434-6001. S2CID 186239132.
  13. Rüdenberg, Reinhold. "Apparatus for producing images of objects". Patent Public Search Basic. Retrieved 24 February 2023.
  14. Rüdenberg, Reinhold. "Apparatus for producing images of objects". Patent Public Search Basic. Retrieved 24 February 2023.
  15. Rodenberg, R. (1932). "Elektronenmikroskop". Die Naturwissenschaften (in German). 20 (28): 522. Bibcode:1932NW.....20..522R. doi:10.1007/BF01505383. ISSN 0028-1042. S2CID 263996652.
  16. Ruska, Ernst (1986). "Ernst Ruska Autobiography". Nobel Foundation. Retrieved 2010-01-31.
  17. Kruger, DH; Schneck, P; Gelderblom, HR (May 2000). "Helmut Ruska and the visualisation of viruses". The Lancet. 355 (9216): 1713–1717. doi:10.1016/S0140-6736(00)02250-9. PMID 10905259. S2CID 12347337.
  18. Ardenne, M. Von; Beischer, D. (1940). "Untersuchung von Metalloxyd-Rauchen mit dem Universal-Elektronenmikroskop" [Investigation of metal oxide smoking with the universal electron microscope]. Zeitschrift für Elektrochemie und Angewandte Physikalische Chemie (in German). 46 (4): 270–277. doi:10.1002/bbpc.19400460406 (inactive 1 August 2023).{{cite journal}}: CS1 maint: DOI inactive as of August 2023 (link)
  19. History of electron microscopy, 1931–2000. Authors.library.caltech.edu (2002-12-10). Retrieved on 2017-04-29.
  20. "North America's first electron microscope".
  21. "James Hillier". Inventor of the Week: Archive. 2003-05-01. Archived from the original on 2003-08-23. Retrieved 2010-01-31.
  22. Kirkland, Earl (2010). Advanced computing in electron microscopy. New York: Springer. ISBN 978-1-4419-6533-2. OCLC 668095602.
  23. Cheng Y, Grigorieff N, Penczek PA, Walz T (April 2015). "A primer to single-particle cryo-electron microscopy". Cell. 161 (3): 438–449. doi:10.1016/j.cell.2015.03.050. PMC 4409659. PMID 25910204.
  24. Erni, Rolf; Rossell, MD; Kisielowski, C; Dahmen, U (2009). "Atomic-Resolution Imaging with a Sub-50-pm Electron Probe". Physical Review Letters. 102 (9): 096101. Bibcode:2009PhRvL.102i6101E. doi:10.1103/PhysRevLett.102.096101. PMID 19392535.
  25. "The Scale of Things". Office of Basic Energy Sciences, U.S. Department of Energy. 2006-05-26. Archived from the original on 2010-02-01. Retrieved 2010-01-31.
  26. O'Keefe MA; Allard LF (2004-01-18). "Sub-Ångstrom Electron Microscopy for Sub-Ångstrom Nano-Metrology" (PDF). Information Bridge: DOE Scientific and Technical Information – Sponsored by OSTI. {{cite journal}}: Cite journal requires |journal= (help)
  27. Burgess, Jeremy (1987). Under the Microscope: A Hidden World Revealed. CUP Archive. p. 11. ISBN 978-0-521-39940-1.
  28. "Introduction to Electron Microscopy" (PDF). FEI Company. p. 15. Retrieved 12 December 2012.
  29. Humbel, Bruno M; Schwarz, Heinz; Tranfield, Erin M; Fleck, Roland A (February 15, 2019). "Chapter 10: Chemical Fixation". In Fleck, Roland A; Humbel, Bruno M (eds.). Biological Field Emission Scanning Electron Microscopy, First Edition. John Wiley & Sons Ltd. pp. 191–221. doi:10.1002/9781118663233.ch10. ISBN 9781118663233. S2CID 243064180.
  30. Al-Amoudi A, Norlen LP, Dubochet J (October 2004). "Cryo-electron microscopy of vitreous sections of native biological cells and tissues". J Struct Biol. 148 (1): 131–5. doi:10.1016/j.jsb.2004.03.010. PMID 15363793.
  31. Wagner FR, Watanabe R, Schampers R, Singh D, Persoon H, Schaffer M, Fruhstorfer P, Plitzko J, Villa E (June 2020). "Preparing samples from whole cells using focused-ion-beam milling for cryo-electron tomography". Nat Protoc. 15 (6): 2041–2070. doi:10.1038/s41596-020-0320-x. PMC 8053421. PMID 32405053.
  32. Luft, J.H. (1961). "Improvements in epoxy resin embedding methods". The Journal of Biophysical and Biochemical Cytology. Vol. 9, no. 2. p. 409. PMC 2224998. PMID 13764136.
  33. Meryman H.T. and Kafig E. (1955). The study of frozen specimens, ice crystals and ices crystal growth by electron microscopy. Naval Med. Res. Ints. Rept NM 000 018.01.09 Vol. 13 pp 529–544
  34. Steere, Russell L. (1957-01-25). "Electron microscopy of structural detail in frozen biological specimens". The Journal of Biophysical and Biochemical Cytology. 3 (1): 45–60. doi:10.1083/jcb.3.1.45. PMC 2224015. PMID 13416310.
  35. Isailović, Tanja M.; Todosijević, Marija N.; Đorđević, Sanela M.; Savić, Snežana D. (2017-01-01), Čalija, Bojan (ed.), "Chapter 7 - Natural Surfactants-Based Micro/Nanoemulsion Systems for NSAIDs—Practical Formulation Approach, Physicochemical and Biopharmaceutical Characteristics/Performances", Microsized and Nanosized Carriers for Nonsteroidal Anti-Inflammatory Drugs, Boston: Academic Press, pp. 179–217, doi:10.1016/b978-0-12-804017-1.00007-8, ISBN 978-0-12-804017-1, retrieved 2020-10-22
  36. Moor H, Mühlethaler K (1963). "Fine structure in frozen-etched yeast cells". The Journal of Cell Biology. 17 (3): 609–628. doi:10.1083/jcb.17.3.609. PMC 2106217. PMID 19866628.
  37. Black, Joel A. (1990-01-01), Conn, P. Michael (ed.), "[20] - Use of Freeze-Fracture in Neurobiology", Methods in Neurosciences, Quantitative and Qualitative Microscopy, Academic Press, 3: 343–360, doi:10.1016/b978-0-12-185255-9.50025-0, ISBN 9780121852559, retrieved 2020-10-22
  38. Stillwell, William (2016-01-01), Stillwell, William (ed.), "Chapter 11 - Long-Range Membrane Properties", An Introduction to Biological Membranes (Second Edition), Elsevier, pp. 221–245, doi:10.1016/b978-0-444-63772-7.00011-7, ISBN 978-0-444-63772-7, retrieved 2020-10-22
  39. Bullivant, Stanley; Ames, Adelbert (1966-06-01). "A simple freeze-fracture replication method for electron microscopy". The Journal of Cell Biology. 29 (3): 435–447. doi:10.1083/jcb.29.3.435. PMC 2106967. PMID 5962938.
  40. Gruijters, W. T.; Kistler, J; Bullivant, S; Goodenough, D. A. (1987-03-01). "Immunolocalization of MP70 in lens fiber 16-17-nm intercellular junctions". The Journal of Cell Biology. 104 (3): 565–572. doi:10.1083/jcb.104.3.565. PMC 2114558. PMID 3818793.
  41. da Silva, Pedro Pinto; Branton, Daniel (1970-06-01). "Membrane splitting in freeze-etching". The Journal of Cell Biology. 45 (3): 598–605. doi:10.1083/jcb.45.3.598. PMC 2107921. PMID 4918216.
  42. Rash, J. E.; Johnson, T. J.; Hudson, C. S.; Giddings, F. D.; Graham, W. F.; Eldefrawi, M. E. (1982-11-01). "Labelled-replica techniques: post-shadow labelling of intramembrane particles in freeze-fracture replicas". Journal of Microscopy. 128 (Pt 2): 121–138. doi:10.1111/j.1365-2818.1982.tb00444.x. PMID 6184475. S2CID 45238172.
  43. Reynolds, E. S. (1963). "The use of lead citrate at high pH as an electron-opaque stain in electron microscopy". Journal of Cell Biology. 17 (1): 208–212. doi:10.1083/jcb.17.1.208. PMC 2106263. PMID 13986422.
  44. Sjostrand FS, Hanzon V (November 1954). "Ultrastructure of Golgi apparatus of exocrine cells of mouse pancreas". Exp Cell Res. 7 (2): 415–29. doi:10.1016/s0014-4827(54)80087-5. PMID 13220587.
  45. "Methods in Cell Biology | Correlative Light and Electron Microscopy III | ScienceDirect.com by Elsevier".
  46. Finin P, Khan RM, Oh S, Boshoff HI, Barry CE (May 2023). "Chemical approaches to unraveling the biology of mycobacteria". Cell Chem Biol. 30 (5): 420–435. doi:10.1016/j.chembiol.2023.04.014. PMC 10201459. PMID 37207631.
  47. Peddie CJ, Genoud C, Kreshuk A, Meechan K, Micheva KD, Narayan K, Pape C, Parton RG, Schieber NL, Schwab Y, Titze B, Verkade P, Aubrey A, Collinson LM (July 2022). "Volume electron microscopy". Nat Rev Methods Primers. 2: 51. doi:10.1038/s43586-022-00131-9. PMC 7614724. PMID 37409324.
  48. Crowther RA, Amos LA, Finch JT, De Rosier DJ, Klug A (May 1970). "Three dimensional reconstructions of spherical viruses by fourier synthesis from electron micrographs". Nature. 226 (5244): 421–5. Bibcode:1970Natur.226..421C. doi:10.1038/226421a0. PMID 4314822. S2CID 4217806.
  49. White IJ, Burden JJ (2023). "A practical guide to starting SEM array tomography—An accessible volume EM technique". Chapter 7 - A practical guide to starting SEM array tomography—An accessible volume EM technique. Methods in Cell Biology. Vol. 177. pp. 171–196. doi:10.1016/bs.mcb.2022.12.023. ISBN 9780323916073. PMID 37451766.
  50. Kolotuev I (August 2023). "Work smart, not hard: How array tomography can help increase the ultrastructure data output". J Microsc. doi:10.1111/jmi.13217. PMID 37626455. S2CID 261174348.
  51. Denk W, Horstmann H (November 2004). "Serial block-face scanning electron microscopy to reconstruct three-dimensional tissue nanostructure". PLOS Biol. 2 (11): e329. doi:10.1371/journal.pbio.0020329. PMC 524270. PMID 15514700.
  52. Abbott LF, Bock DD, Callaway EM, Denk W, Dulac C, Fairhall AL, Fiete I, Harris KM, Helmstaedter M, Jain V, Kasthuri N, LeCun Y, Lichtman JW, Littlewood PB, Luo L, Maunsell JH, Reid RC, Rosen BR, Rubin GM, Sejnowski TJ, Seung HS, Svoboda K, Tank DW, Tsao D, Van Essen DC (September 2020). "The Mind of a Mouse". Cell. 182 (6): 1372–1376. doi:10.1016/j.cell.2020.08.010. PMID 32946777. S2CID 221766693.
  53. Prinz WA, Toulmay A, Balla T (January 2020). "The functional universe of membrane contact sites". Nat Rev Mol Cell Biol. 21 (1): 7–24. doi:10.1038/s41580-019-0180-9. PMID 31732717. S2CID 208019972.
  54. de Jonge, N.; Ross, F.M. (2011). "Electron microscopy of specimens in liquid". Nature Nanotechnology. 6 (8): 695–704. Bibcode:2003NatMa...2..532W. doi:10.1038/nmat944. PMID 12872162. S2CID 21379512.
  55. Gai, P.L.; Boyes, E.D. (2009). "Advances in atomic resolution in situ environmental transmission electron microscopy and 1A aberration corrected in situ electron microscopy". Microsc Res Tech. 72 (3): 153–164. arXiv:1705.05754. doi:10.1002/jemt.20668. PMID 19140163. S2CID 1746538.
  56. Adrian, Marc; Dubochet, Jacques; Lepault, Jean; McDowall, Alasdair W. (1984). "Cryo-electron microscopy of viruses". Nature (Submitted manuscript). 308 (5954): 32–36. Bibcode:1984Natur.308...32A. doi:10.1038/308032a0. PMID 6322001. S2CID 4319199.
  57. Sabanay, I.; Arad, T.; Weiner, S.; Geiger, B. (1991). "Study of vitrified, unstained frozen tissue sections by cryoimmunoelectron microscopy". Journal of Cell Science. 100 (1): 227–236. doi:10.1242/jcs.100.1.227. PMID 1795028.
  58. Kasas, S.; Dumas, G.; Dietler, G.; Catsicas, S.; Adrian, M. (2003). "Vitrification of cryoelectron microscopy specimens revealed by high-speed photographic imaging". Journal of Microscopy. 211 (1): 48–53. doi:10.1046/j.1365-2818.2003.01193.x. PMID 12839550. S2CID 40058086.


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