Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 7-Day Trial for You or Your Team.

Learn More →

Laser Scanning Microscopy To Study Molecular Transport In Single Cells

Laser Scanning Microscopy To Study Molecular Transport In Single Cells Laser scanning microscopy was used to study dynamic processes in single cells. The laser scanning microscope of Heidelberg Instruments was complemented with a 1W krypton laser and a microinjection set-up. Simple algorithms were worked out which permit determination of local and integrated intensities in fluorescence scans. In one application the lateral diffusion of macromolecules was studied. The krypton laser was used to irreversibly photolyse fluorescently labeled dextrans in small volumes of a thin fluid layer; equilibration of the local fluorescence inhomogeneity by lateral diffusion was followed by repetitive scanning. In a second application the permeability of single red blood cell membranes which had been exposed to the complement cascade was studied. In a further application artificial nuclear proteins, constructed by molecular genetic methods, were injected into the cytoplasm of hepatoma cells. The kinetics of protein transport from cytoplasm to nucleus were derived from fluorescence scans. In all applications a good agreement between results obtained by laser scanning microscopy and those obtained independently by other methods and instruments was observed. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Proceedings of SPIE SPIE

Laser Scanning Microscopy To Study Molecular Transport In Single Cells

Download PDF
7 pages

Loading next page...
 
/lp/spie/laser-scanning-microscopy-to-study-molecular-transport-in-single-cells-WkO3pOJ76h

References (3)

Publisher
SPIE
Copyright
COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.
ISSN
0277-786X
eISSN
1996-756X
DOI
10.1117/12.950335
Publisher site
See Article on Publisher Site

Abstract

Laser scanning microscopy was used to study dynamic processes in single cells. The laser scanning microscope of Heidelberg Instruments was complemented with a 1W krypton laser and a microinjection set-up. Simple algorithms were worked out which permit determination of local and integrated intensities in fluorescence scans. In one application the lateral diffusion of macromolecules was studied. The krypton laser was used to irreversibly photolyse fluorescently labeled dextrans in small volumes of a thin fluid layer; equilibration of the local fluorescence inhomogeneity by lateral diffusion was followed by repetitive scanning. In a second application the permeability of single red blood cell membranes which had been exposed to the complement cascade was studied. In a further application artificial nuclear proteins, constructed by molecular genetic methods, were injected into the cytoplasm of hepatoma cells. The kinetics of protein transport from cytoplasm to nucleus were derived from fluorescence scans. In all applications a good agreement between results obtained by laser scanning microscopy and those obtained independently by other methods and instruments was observed.

Journal

Proceedings of SPIESPIE

Published: Feb 9, 1989

There are no references for this article.