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Items: 1 to 20 of 164

1.

Mass mapping of large globin complexes by scanning transmission electron microscopy.

Wall JS, Simon MN, Lin BY, Vinogradov SN.

Methods Enzymol. 2008;436:487-501. doi: 10.1016/S0076-6879(08)36027-3.

PMID:
18237650
2.

Application of scanning transmission electron microscopy to the study of biological structure.

Engel A, Colliex C.

Curr Opin Biotechnol. 1993 Aug;4(4):403-11. Review.

PMID:
7763970
3.

Image analysis of Artemia salina ribosomes by scanning transmission electron microscopy.

Tumminia SJ, Hellmann W, Wall JS, Boublik M.

J Struct Biol. 1992 Sep-Oct;109(2):109-15.

PMID:
1288613
4.

Hierarchy of globin complexes. The quaternary structure of the extracellular chlorocruorin of Eudistylia vancouverii.

Qabar AN, Stern MS, Walz DA, Chiu JT, Timkovich R, Wall JS, Kapp OH, Vinogradov SN.

J Mol Biol. 1991 Dec 20;222(4):1109-29.

PMID:
1762147
5.

Quantitative scanning transmission electron microscopy of ultrathin cryosections: subcellular organelles in rapidly frozen liver and cerebellar cortex.

Buchanan RA, Leapman RD, O'Connell MF, Reese TS, Andrews SB.

J Struct Biol. 1993 May-Jun;110(3):244-55.

PMID:
8373705
6.

Quantitative dark-field mass analysis of ultrathin cryosections in the field-emission scanning transmission electron microscope.

Andrews SB, Buchanan RA, Leapman RD.

Scanning Microsc Suppl. 1994;8:13-23; discussion 23-4.

PMID:
7638482
8.

Mass mapping of amyloid fibrils in the electron microscope using STEM imaging.

Sousa AA, Leapman RD.

Methods Mol Biol. 2013;950:195-207. doi: 10.1007/978-1-62703-137-0_12.

PMID:
23086877
9.
10.

Scanning transmission electron microscopy study of the molecular mass of amphipol/cytochrome b6f complexes.

Tribet C, Mills D, Haider M, Popot JL.

Biochimie. 1998 May-Jun;80(5-6):475-82.

PMID:
9782387
11.
12.

Mass mapping of a protein complex with the scanning transmission electron microscope.

Engel A, Baumeister W, Saxton WO.

Proc Natl Acad Sci U S A. 1982 Jul;79(13):4050-4.

13.

Observation of unstained biological macromolecules with the STEM.

Ohtsuki M.

Ultramicroscopy. 1980;5(3):317-23.

PMID:
7414740
14.
15.
16.

Thin dielectric film thickness determination by advanced transmission electron microscopy.

Diebold AC, Foran B, Kisielowski C, Muller DA, Pennycook SJ, Principe E, Stemmer S.

Microsc Microanal. 2003 Dec;9(6):493-508.

PMID:
14750984
17.

Standardless atom counting in scanning transmission electron microscopy.

LeBeau JM, Findlay SD, Allen LJ, Stemmer S.

Nano Lett. 2010 Nov 10;10(11):4405-8. doi: 10.1021/nl102025s. Epub 2010 Oct 14. Erratum in: Nano Lett. 2011 Jan 12;11(1):310.

PMID:
20945926
18.

[The mapping of the local content of water and dry matter by using ultrathin frozen sections].

Buravkov SV, Zierold K, Shakhlamov VA.

Biull Eksp Biol Med. 1993 Sep;116(9):325-8. Russian.

PMID:
8118017
19.

Observations of unstained biological specimens using a low-energy, high-resolution STEM.

Takaoka A, Hasegawa T.

J Electron Microsc (Tokyo). 2006 Jun;55(3):157-63. Epub 2006 Jun 28.

PMID:
16809349
20.

Mass analysis of biological macromolecular complexes by STEM.

Thomas D, Schultz P, Steven AC, Wall JS.

Biol Cell. 1994;80(2-3):181-92. Review.

PMID:
8087068

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