Difference: CemProtocEC (1 vs. 14)
Revision 1426 Oct 2009 - Main.KdDerr
Principles & ProtocolsPrinciples - Electron crystallography | ||||||||
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In order to visualize a sample in a transmission electron microscope
the sample must (a) be thin enough
such that a beam of electrons can penetrate it (<250nm, ideally <100nm), (b)
be deposited onto an EM grid, which is a thin circular copper grid that
is 3mm in diameter, and (c)withstand high vacuum and electron radiation within
the microscope column. For tissue, samples are prepared by cutting thin sections
(sectioning). For aqueous suspensions of macromolecules, including
2D crystals and ordered helical arrays, 1-5 microliters of the solution is
pipetted onto the EM grid, which is then subjected to either
negative staining,
plunge freezing, or
a combination of these sample preservation techniques, cryo-negative staining.
Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order.
Public website mirror
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Revision 1326 Oct 2009 - Main.KdDerr
Principles & ProtocolsPrinciples - Electron crystallographyJump to ProtocolIn order to visualize a sample in a transmission electron microscope the sample must (a) be thin enough such that a beam of electrons can penetrate it (<250nm, ideally <100nm), (b) be deposited onto an EM grid, which is a thin circular copper grid that is 3mm in diameter, and (c)withstand high vacuum and electron radiation within the microscope column. For tissue, samples are prepared by cutting thin sections | ||||||||
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| < < | (sectioning). For aqueous suspensions of macromolecules, including | |||||||
| > > | (sectioning). For aqueous suspensions of macromolecules, including | |||||||
| 2D crystals and ordered helical arrays, 1-5 microliters of the solution is pipetted onto the EM grid, which is then subjected to either | ||||||||
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| < < | negative staining, plunge freezing, or a combination of these sample preservation techniques, | |||||||
| > > | negative staining, plunge freezing, or a combination of these sample preservation techniques, cryo-negative staining. | |||||||
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| < < | cryo-negative staining. | |||||||
| Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order.
Public website mirror
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Revision 1213 Oct 2009 - Main.KdDerr
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| > > | Return to Cryo EM web page at http://www.nysbc.org/facilities/CEM | |||||||
Principles & Protocols | ||||||||
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| > > | Principles - Electron crystallographyJump to Protocol | |||||||
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| In order to visualize a sample in a transmission electron microscope
the sample must (a) be thin enough
such that a beam of electrons can penetrate it (<250nm, ideally <100nm), (b)
be deposited onto an EM grid, which is a thin circular copper grid that
is 3mm in diameter, and (c)withstand high vacuum and electron radiation within
the microscope column. For tissue, samples are prepared by cutting thin sections
(sectioning). For aqueous suspensions of macromolecules, including
2D crystals and ordered helical arrays, 1-5 microliters of the solution is
pipetted onto the EM grid, which is then subjected to either
negative staining,
plunge freezing, or
a combination of these sample preservation techniques,
cryo-negative staining. Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order. Public website mirror
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Revision 1103 Sep 2009 - Main.KdDerr
Principles & ProtocolsElectron crystallography | ||||||||
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| > > | In order to visualize a sample in a transmission electron microscope
the sample must (a) be thin enough
such that a beam of electrons can penetrate it (<250nm, ideally <100nm), (b)
be deposited onto an EM grid, which is a thin circular copper grid that
is 3mm in diameter, and (c)withstand high vacuum and electron radiation within
the microscope column. For tissue, samples are prepared by cutting thin sections
(sectioning). For aqueous suspensions of macromolecules, including
2D crystals and ordered helical arrays, 1-5 microliters of the solution is
pipetted onto the EM grid, which is then subjected to either
negative staining,
plunge freezing, or
a combination of these sample preservation techniques,
cryo-negative staining. | |||||||
| Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order.
Public website mirror
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Revision 1020 Aug 2009 - Main.KdDerr
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Principles & Protocols | ||||||||
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| Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order.
Public website mirror
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Revision 920 Aug 2009 - Main.KdDerr
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Electron crystallographyTwo dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order.Public website mirror
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Revision 810 Aug 2009 - Main.BillRice
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Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order.
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| > > | Electron crystallographyTwo dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order. | ||||||||||
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Revision 707 Apr 2009 - Main.RubenDiaz
Principles & Protocols
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| > > | Two dimensional crystals are commonly formed by membrane proteins, such as bacteriorhodopsin or aquaporins. These crystals ideally consist of a single layer of molecules that are held together by specific contacts, showing crystalling order. | ||||||||||||
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Revision 612 Feb 2009 - Main.KakoliMitra
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