Today: Dec 27, 2024
RU / EN
Last update: Dec 27, 2024
A Novel Method for Amyloid Detection in Human Tissue Load Using a Fluorescent Dye — Congo Red Analogue

A Novel Method for Amyloid Detection in Human Tissue Load Using a Fluorescent Dye — Congo Red Analogue

Guselnikova V.V., Antimonova O.I., Fedorova E.A., Shavlovsky M.M., Safray A.E., Rukavishnikova A.A., Ilyin V.V., Milman B.L., Korzhevskii D.E.
Key words: amyloid; disodium salt of 2,7-(1-amino-4-sulfo-2-naphthylazo)fluorene; Congo red; fluorescence microscopy; amyloidosis; human myocardium.
2020, volume 12, issue 1, page 65.

Full text

html pdf
2682
2099

The aim of the study was to develop a new technology for the detection of amyloid in human tissues based on the fluorescent dye, disodium salt of 2,7-(1-amino-4-sulfo-2-naphthylazo)fluorene (DSNAF).

Materials and Methods. Synthesis of DSNAF was performed by diazotization of 2,7-diaminofluorene in a stream of argon followed by azo coupling with naphthionic acid. Identification of DSNAF was performed using MALDI mass spectrometry. Human myocardial samples from males and females aged from 85 to 98 years (n=11) were the material for the histochemical study. Myocardial paraffin sections were stained with a 0.1% aqueous solution of Congo red or with an aqueous solution (0.1 or 0.034%) of DSNAF under the same conditions.

Results. It has been demonstrated for the first time that a new fluorene-based analogue of Congo red, DSNAF, can be successfully used to identify amyloid deposits in histological sections of human myocardium. In terms of the specificity and intensity of amyloid staining, DSNAF is comparable to Congo red, which is the gold standard for detecting amyloid deposits. The fluorescence intensity of DSNAF when binding to amyloid fibrils is significantly higher than the intensity of Congo red fluorescence (with a lower intensity of background fluorescence of heart muscle tissue). This is especially useful for identifying small deposits of amyloid in the human tissues which is important when using small biopsies.

Conclusion. The advantages of using DSNAF allow us to consider the developed technology for the detection of amyloid as a new promising method of identifying amyloid deposits in human tissues.

  1. Schavlovsky M.M. Ethiology and pathogenesis of amyloidoses: the molecular and genetic basis. Meditsinskiy akademicheskiy zhurnal 2010; 10(4): 63–81.
  2. Sipe J.D., Benson M.D., Buxbaum J.N., Ikeda S.I., Merlini G., Saraiva M.J., Westermark P. Amyloid fibril proteins and amyloidosis: chemical identification and clinical classification International Society of Amyloidosis 2016 Nomenclature Guidelines. Amyloid 2016; 23(4): 209–213, https://doi.org/10.1080/13506129.2016.1257986.
  3. Hassan W., Al-Sergani H., Mourad W., Tabbaa R. Amyloid heart disease. New frontiers and insights in pathophysiology, diagnosis, and management. Tex Heart Inst 2005; 32(2): 178–184.
  4. Morais G.C.P., Arruda M.M., Bonadia J.C.A., Pozzan G. Cardiac amyloidosis: a challenging diagnosis. Autops Case Rep 2014; 4(4): 9–17, https://doi.org/10.4322/acr.2014.034.
  5. Zhdanova E.A., Rameev V.V., Moiseev S.V., Kozlovskaya L.V., Safarova A.F. Cardiac amyloidosis. Klinicheskaya farmakologiya i terapiya 2011; 5: 44–50.
  6. Ukholkina G.B., Kuchin G.A., Bychkova O.P., Chikhirev O.A. Cardiac amyloidosis in clinical practice. Zhurnal serdechnaya nedostatochnost’ 2016; 17(1): 57–68, https://doi.org/10.18087/rhfj.2016.1.2201.
  7. Ovcharenko S.I., Son E.A., Okisheva E.A., Sedov V.P., Makolkin V.I. Cardiac amyloidosis. Klinitsist 2007; 6: 32–38.
  8. Nonka T.G., Repin A.N. Cardiac amyloidosis. Diagnostics and treatment of amyloid cardiomyopathy. Case report. Kliniceskaa medicina 2015; 93(4): 66–73.
  9. Linke R.P. Congo red staining of amyloid: improvements and practical guide for a more precise diagnosis of amyloid and the different amyloidoses. In: Protein misfolding, aggregation, and conformational diseases. Springer US; 2006; p. 239–276, https://doi.org/10.1007/0-387-25919-8_12.
  10. Korzhevskii D.E., Gilyarov A.V. Osnovy gistologicheskoy tekhniki [Basics of histological techniques]. Saint Petersburg: SpetsLit; 2010.
  11. Picken M.M. Amyloidosis — where are we now and where are we heading? Arch Pathol Lab Med 2010; 134(4): 545–551.
  12. Clement C.G., Truong L.D. An evaluation of Congo red fluorescence for the diagnosis of amyloidosis. Hum Pathol 2014; 45(8): 1766–1772, https://doi.org/10.1016/j.humpath.2014.04.016.
  13. Sapozhnikov S.P., Karyshev P.B., Sheptukhina A.I., Nikolayeva O.V., Avruyskaya A.A., Mitrasov Y.N., Kozlov V.A. Novel fluorescent probes for amyloid detection. Sovremennye tehnologii v medicine 2017; 9(2): 91–98, https://doi.org/10.17691/stm2017.9.2.11.
  14. Gusel’nikova V.V., Gudkova A.Ya., Semernin E.N., Grudinin N.A., Krutikov A.N., Shavloskii M.M., Mil’man B.L., Korzhevskii D.E., Mikhailova E.V., Kaminskaya E.V., Mikhailov V.M. Characterization of amyloid deposits found in internal organs of MDX mice. Cell Tiss Biol 2017; 11(1): 27–34, https://doi.org/10.1134/s1990519x17010047.
  15. Gusel’nikova V., Antimonova O., Fedorova E., Shavlovsky M., Krutikov A., Mikhailova E., Gudkova A., Mikhailov V., Korzhevskii D. Fluorescent characterization of amyloid deposits in the kidneys of mdx mice. Eur J Histochem 2018; 62(2): 2870, https://doi.org/10.4081/ejh.2018.2870.
  16. Gusel’nikova V.V., Antimonova O.I., Fedorova E.A., Shavlovskii M.M., Krutikov A.N., Mikhailova E.V., Kaminskaya E.V., Gudkova A.Ya., Korzhevskii D.E., Mikhailov V.M. Fluorene derivative disodium salt as a new fluorescent dye for identification of amyloid deposits in the myocardium of mdx mice. Cell Tiss Biol 2018; 12(3): 213–216, https://doi.org/10.1134/s1990519x18030057.
  17. Grigorev I.P., Korzhevskii D.E. Current technologies for fixation of biological material for immunohistochemical analysis (review). Sovremennye tehnologii v medicine 2018; 10(2): 156–165, https://doi.org/10.17691/stm2018.10.2.19.
  18. Antimonova O.I., Korzhevskii D.E., Shavlovsky M.M. Method of fluorescent identification of amyloid. Patent RU 2673815. 2018.
  19. Korzhevskii D.E., Sukhorukova E.G. Gistokhimicheskie metody okrashivaniya gistologicheskikh preparatov. V kn.: Morfologicheskaya diagnostika: podgotovka materiala dlya morfologicheskogo issledovaniya i elektronnoy mikroskopii [Histochemical staining methods for histological preparations. In: Morphological diagnostics: preparing material for morphological research and electron microscopy]. Pod red. Korzhevskogo D.E. [Korzhevskii D.E. (editor)]. Saint Petersburg; 2013; p. 85–97.
  20. Cohen A.S., Calkins E., Levene C.I. Studies on experimental amyloidosis. I. Analysis of histology and staining reactions of casein-induced amyloidosis in the rabbit. Am J Pathol 1959; 35: 971–989.
  21. Antimonova O.I., Grudinina N.A., Egorova V.V., Ilyina V.V., Zabrodskay Y.A., Ramsay E.S., Shabalin K.A., Protasov A.V., Yakimov A.P., Polukeev V.A., Shavlovsky M.M. Time machine: can a dye from 1928 be re-purposed for modern, fluorescence-based detection of amyloid-like fibrils? Dyes and Pigments 2020; 172: 107863, https://doi.org/10.1016/j.dyepig.2019.107863.
  22. Dapson R.W. Amyloid from a histochemical perspective. A review of the structure, properties and types of amyloid, and a proposed staining mechanism for Congo red staining. Biotech Histochem 2018; 93(8): 543–556, https://doi.org/10.1080/10520295.2018.1528385.
Guselnikova V.V., Antimonova O.I., Fedorova E.A., Shavlovsky M.M., Safray A.E., Rukavishnikova A.A., Ilyin V.V., Milman B.L., Korzhevskii D.E. A Novel Method for Amyloid Detection in Human Tissue Load Using a Fluorescent Dye — Congo Red Analogue. Sovremennye tehnologii v medicine 2020; 12(1): 65, https://doi.org/10.17691/stm2020.12.1.08


Journal in Databases

pubmed_logo.jpg

web_of_science.jpg

scopus.jpg

crossref.jpg

ebsco.jpg

embase.jpg

ulrich.jpg

cyberleninka.jpg

e-library.jpg

lan.jpg

ajd.jpg

SCImago Journal & Country Rank