Summary
A detailed quantitative analysis of the anisotropic properties of Sirius Red F3B, Picrosirius, and Chlorantine Fast Red crystals, and of their complexes with a macromolecularly oriented protein either in a pure form or as part of a tissue structure was carried out. Collagen I was used as the protein model. Linear dichroism and dispersion of birefringence were investigated in dye aggregates, in stained filaments of collagen I and in collagen bundles in sections of tendon. A positive linear dichroism, the characteristics of which varied as a function of the dye type used, was demonstrated for the dye aggregates and stained substrates. However, even thin regions of the stained tendon collagen bundles showed very high absorbances, differing from the pattern reported previously, for collagen stained with another sulphonated azo dye, Xylidine Ponceau. Consequently, not all these dyes enable protein concentration and orientation to be determined in collagen-containing structures. From the linear dichroism patterns it is assumed that the long axis of the molecules of these azo dye is mostly parallel to that of filaments of pure collagen I and statistically parallel to the long axis of collagen bundles of tendon sections. The dye aggregates and, stained pure collagen I and tendon collagen bundles exhibited birefringent images with interference colours that varied as a function of thickness and packing state of the preparations, which is in agreement with reports in the literature. The optical retardations of the collagen bundles increased by a factor of 5–6 times after staining with Picrosirius. From data on form dichroism it is concluded that when studying the macromolecular orientation of collagen preparations stained with azo dyes, the choice of the mounting medium deserves consideration.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Conn, H. J. (1969)Biological stains. A handbook of the nature and uses of the dyes employed in the biological laboratory. Baltimore: Williams & Wilkins.
Deitch, A. D. (1966) Cytophotometry of proteins. InIntroduction to quantitative Cytochemistry (edited byWied, G. L.), pp. 451–68. New York, London: Academic Press.
Ewing, G. W. (1969)Instrumental Methods of Chemical Analysis. New York: McGraw-Hill.
Frey-Wissling, A. (1948)Submicroscopy morphology of protoplasm and its derivatives. Amsterdam: Elsevier.
Goldstein, D. J. (1969) Detection of dichroism with the microscope.J. Microsc. 89, 19–36.
Joiner, D. W., Puchtler, H. &Sweat, F. (1968) Staining of immature collagen by resorcinfuchsin in infant kidneys.J. R. microsc. Soc. 88, 461–71.
Junqueira, L. C. U., Bignolas, G. &Brentani, R. R. (1979) Picrosirius staining plus polarization microscopy, a specific method for collagen detection in tissue sections.Histochem. J. 11, 447–55.
Lison, L. (1960)Histochimie et Cytochimie Animales. Paris: Gauthier-Villars.
Missmahl, H. P. (1966) Birefringence and dichroism of dyes and their significance in the detection of oriented structures. InIntroduction to Quantitative Cytochemistry (edited byWied, G. L.), pp. 539–47. New York, London: Academic Press.
Nordén, B. (1980) Applications of linear dichroism spectroscopy.Appl. Spectr. Rev. 14, 157–248.
Pérez-Tamayo, R. &Montfort, J. (1980) The susceptibility of hepatic collagen to homologous collagenase in human and experimental cirrhosis of the liver.Am. J. Pathol. 100, 427–42.
Pimentel, E. R. & Vidal, B. C. (1980) Propriedades anisotrópicas de feixes de colágeno e glicoproteínas ligadas ao sirius red.II Congr. Bras. Biol Celular, Rio de Janeiro, Abstracts, pp. 156–7.
Puchtler, H., Sweat, F., Jackson, J. G. &Joiner, D. W. (1966) Collagen-like staining, polarization and fluorescence microscopic properties of ‘elastic fibers’ in hyperplastic arteriosclerosis. InBiochemistry and Physiology of Connective Tissue (edited byCompte, P.). Lyon: Société Ormeco et Imprimerie du Sud-Est.
Schmidt, W. J. (1937)Doppelbrechung von Karyoplasma, Zytoplasma und Metaplasma. Berlin: Borntraeger.
Schmidt, W. J. &Keil, A. (1958)Die gesunden und die erkrankten Zahngewebe des Menschen und der Wirbeltiere im Polarizations mikroskop. München: Carl Hanser Verlag.
Sweat, F., Puchtler, H. &Rosenthal, S. I. (1964) Sirius red F3BA as a stain for connective tissueArch. Path. 78, 69–72.
Venkataraman, K. (1952)The Chemistry of Synthetic Dyes. New York: Academic Press.
Vidal, B. C. (1970) Dichroism in collagen bundles stained with xylidine ponceau 2R.Ann. Histochim. 15, 289–96.
Vidal, B. C. (1972) Toluidine blue: Cotton effect-like phenomena of crystal aggregates obtained by drying on microscopical slides.Ann. Histochim. 17, 151–7.
Vidal, B. C. (1980) The part played by proteoglycans and structural glycoproteins in the molecular orientation of collagen bundles.Cell. molec. Biol. 26, 415–21.
Wood, G. C. (1964) The precipitation, of collagen fibres from solution.Int. Rev. Connect. Tiss. Res. 2, 1–28.
Zeiss Information (1977) Continuous filter monochromator b with motor drive.Mikro Bull. 18, 1–2.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Vidal, B.D.C., Mello, M.L.S. & Pimentel, É.R. Polarization microscopy and microspectrophotometry of Sirius Red, Picrosirius and Chlorantine Fast Red aggregates and of their complexes with collagen. Histochem J 14, 857–878 (1982). https://doi.org/10.1007/BF01005229
Received:
Revised:
Issue Date:
DOI: https://doi.org/10.1007/BF01005229