Flow Cytometry: Principles and Instrumentation

  • Alfonso Blanco Fernández
  • Adela M. Sánchez-Moreiras
  • Teodoro Coba de la Peña
Chapter

Keywords

Flow Cytometry Ploidy Level Optical Filter Flow Chamber Diffuse Light 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
This is a preview of subscription content, log in to check access.

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

References

  1. Bergounioux C., Brown S.C., Petit P.X. Flow cytometry and plant protoplast cell biology. Physiol Plantarum 1992; 85:374–386Google Scholar
  2. Bergounioux C., Perennes C., Brown S.C., Gadal P. Nuclear RNA quantification in protoplast cell-cycle phases: Cytometry 1988; 9:84–87Google Scholar
  3. Brown S.C. Applications of flow cytometry in plant biology and biotechnologies: review and perspectives. Biotech Biotechnol Equipm 1994; 8:75–78Google Scholar
  4. Brown S.C., Bergounioux C. “Plant Flow Cytometry.” In Flow Cytometry: Advanced Research and Clinical Applications. A. Yen, ed. Boca Raton, Florida: CRC Press, 1989Google Scholar
  5. Brown S.C., Bergounioux C., Tallet S., Marie D. “Flow Cytometry of Nuclei for Ploidy and Cell Cycle Analysis.” In A Laboratory Guide for Cellular and Molecular Plant Biology. I. Negrutiu, G. Gharti-Cherti, eds. Birkhäauser: Verlag Basel, 1991Google Scholar
  6. Conia J., Bergounioux C., Perennes C., Muller P.H. Flow cytometric analysis and sorting of plant chromosomes from Petunia hybrida protoplasts. Cytometry 1987; 8:500–508PubMedCrossRefGoogle Scholar
  7. Cytometry 19. Special issue on comparative genomic hybridization, 1995Google Scholar
  8. De Laat A.M.M., Göhde W., Vogelzang M.J.D.C. Determination of ploidy of single plants and plant populations by flow cytometry. Plant Breeding 1987; 99:303–307Google Scholar
  9. Doležel J. Flow cytometric analysis of nuclear DNA content in higher plants. Phytochem Anal 1991; 2:143–154Google Scholar
  10. Dutch Boltz R.C., Fischer P.A., Wicker L.S., Peterson L.B. Single UV excitation of Hoechst 33342 and ethidium bromide for simultaneous cell cycle analysis and viability determinations on in vitro cultures of murine b-lymphocytes. Cytometry 1994; 15:28–34Google Scholar
  11. Galbraith D.W. Analysis of higher plants by flow cytometry and cell sorting. Int Rev Cytol 1989; 116:165–228Google Scholar
  12. Galbraith D.W. “Flow Cytometric Analysis of Plant Genomes.” In Methods in Cell Biology. Z. Darzynkiewicz, H. Crissman, eds. London: Academic Press, 1990Google Scholar
  13. Galbraith D.W., Harkins K.R., Maddox J.M., Ayres N.M., Sharma D.P., Firoozabady E. Rapid flow cytometric analysis of the cell cycle in intact plant tissues. Science 1983; 220:1049–1051Google Scholar
  14. Godelle B., Cartier D., Marie D., Brown S.C., Siljak-Yakovlev S. Heterochromatin study demonstrating the non-linearity of fluorometry useful for calculating genomic base composition. Cytometry 1993; 14:618–626PubMedCrossRefGoogle Scholar
  15. Haynes J.L. Principles of flow cytometry. Cytometry supp 1988; 3:7–17Google Scholar
  16. Jayat C., Ratinaud M.H. Cell cycle analysis by flow cytometry: principles and applications. Biol Cell 1993; 78:15–25PubMedCrossRefGoogle Scholar
  17. Kerker M., Van Dilla M.A., Brunsting A. Is the central dogma of flow cytometry true: that fluorescence intensity is proportional to cellular dye content? Cytometry 1982; 3:71–78PubMedCrossRefGoogle Scholar
  18. Marcus D.A. High-performance optical filters for fluorescence analysis. Cell Motil Cytoskel 1988; 10:62–70Google Scholar
  19. Marie D., Brown S.C. A cytometric exercise in plant DNA histograms, with 2C values for 70 species. Biol Cell 1993; 78:41–51PubMedCrossRefGoogle Scholar
  20. Michaelson M.J., Price H.J., Ellison J.R., Johnston J.S. Comparison of plant DNA contents determined by Feulgen microspectrophotometry and laser flow cytometry. Am J Bot 1991; 78:183–188Google Scholar
  21. Petit J.M., Denis-Gay M., Ratinaud M.H. Assessment of fluorochromes for cellular structure and function studies by flow cytometry. Biol Cell 1993; 78:1–13PubMedCrossRefGoogle Scholar
  22. Ruch F. “Determination of DNA Content by Microfluorometry.” In Introduction to Quantitative Cytochemistry. G. Wied, ed. New York-London: Academic Press, 1966Google Scholar
  23. Sheen J., Hwang S., Niwa Y., Kobayashi H., Galbraith D.W. Green-fluorescent protein as a new vital marker in plant cells. Plant J 1995; 8:777–784PubMedCrossRefGoogle Scholar
  24. Steen H.B. “Characteristics of Flow Cytometers.” In Flow Cytometry and Sorting. New York: John Wiley and Sons, 1990aGoogle Scholar
  25. Steen H.B. Light scattering measurement in an arc lamp-based flow cytometer. Cytometry 1990b; 11:223–230PubMedCrossRefGoogle Scholar
  26. Tiersch T.R., Chandler R.W., Wachtel S.S., Elias S. Reference standards for flow cytometry and application in comparative studies of nuclear DNA content. Cytometry 1989; 10:706–710PubMedCrossRefGoogle Scholar
  27. Ulrich I., Fritz B., Ulrich W. Application of DNA fluorochromes for flow cytometric DNA analysis of plant protoplasts. Plant Sci 1988; 55:151–158CrossRefGoogle Scholar
  28. Veuskens J., Marie D., Hinnisdaels S., Brown S.C. “Flow Cytometry and Sorting of Plant Chromosomes.” In Flow Cytometry and Cell Sorting. A. Radbruch, ed. Heidelberg: Springer Berlin, 1992Google Scholar

Copyright information

© Kluwer Academic Publishers 2001

Authors and Affiliations

  • Alfonso Blanco Fernández
    • 1
  • Adela M. Sánchez-Moreiras
    • 1
  • Teodoro Coba de la Peña
    • 2
  1. 1.Dpto Bioloxía Vexetal e Ciencia do SoloUniversidade de VigoSpain
  2. 2.Dpto Fisiología y Bioquímica VegetalCentro de Ciencias Medioambientales. Consejo Superior de Investigaciones CientíficasMadridSpain

Personalised recommendations