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Robert Dunstan, Luke Jandreski and the Comparative Pathology Laboratory

Robert Dunstan, Luke Jandreski and the Comparative Pathology Laboratory. Fluorescence for fluorophobes--Virtual fluorescence using chromagens and histochemical stains. Lecture outline. 1. Introduction 2. Using “non-fluorophores” for fluorescence Histochemical stains

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Robert Dunstan, Luke Jandreski and the Comparative Pathology Laboratory

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  1. Robert Dunstan, Luke Jandreski and the Comparative Pathology Laboratory Fluorescence for fluorophobes--Virtual fluorescence using chromagens and histochemical stains

  2. Lecture outline • 1. Introduction • 2. Using “non-fluorophores” for fluorescence • Histochemical stains • Use of red IHC chromagens for fluorescence • Use of registration/co-registration • Conclusions

  3. Vision for virtual imaging and analysis “Increase signal, decrease noise with consistency”

  4. Vision for virtual imaging and analysis Brightfield Fluorescence Pro --Morphologic assess- ment Con --Lower signal:noise --Non-linear expression of chromagens --Colocalization difficult Pro --High signal to noise --Linear expression of fluorophores --Colocalization easy Con --Morphologic assessment difficult

  5. Vision for virtual imaging and analysis Brightfield Fluorescence --Virtual microscopy --“Non-fluoro-phores” for fluorescence --Co-registration of images Pro --Morphologic assess- ment Con --Lower signal:noise --Non-linear expression of chromagens --Colocalization difficult Pro --High signal to noise --Linear expression of chromagens --Colocalization Con --Morphologic assessment difficult

  6. Using non-fluorophores for fluorescence--histochemical stains Thioflavin S and T and Congo Red Toluidine Blue O Eosin > hematoxylin Gentian Violet Neutral Red Example of histochemical stains that fluoresce

  7. Using non-fluorophores for fluorescence--histochemical stains What determines which stains fluoresce? The number of conjugated bonds “Of the dyes with conjugated bond numbers (CBNs) of 29 or less, 90% showed fluorescence; 70% of the dyes whose CBNs exceeded 29 did not . . . “ Juarranz et al, Histochem ’86

  8. Using non-fluorophores for fluorescence--histochemical stains Histochemical Stains Eosin fluoresces!

  9. Using non-fluorophores for fluorescence--histochemical stains Histochemical Stains--Thioflavin S Brain (TG-2576 mouse with amyloid plaques)

  10. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Not perfect but very good • Good • Can assess morphology and fluorescence • Will colocalize: structures > cells > regions within cells • Higher signal:noise with fluorescence than bright field • Improved morphometry • Bad • Not as specific as standard antibody-bound fluorophores • Some red chromagens will smear

  11. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Comparing fluorescence from a chromagen with fluorescence from a fluorophore Avidin-biotin complex with alkaline phosphatase Vector Fast Red Biotin 2ndry Ab 1o Ab Epitope

  12. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Comparing fluorescence from a chromagen with fluorescence from a fluorophore CD-138 Red chromagen CD-138 Alexofluor 488 Human Lymph Node

  13. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence CD31 (endothelial cell) Smooth muscle actin (smooth muscle) CD31 (endothelial cell) Human to mouse xenograft

  14. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Is anything gained? CD31 (endothelial cell) Fluorescent Deconvolution of brightfield image Human to mouse xenograft

  15. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence CD138 (plasma Cell) VS38C (plasma Cell) CD138 (Plasma cell) Human lymph node

  16. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Is anything gained? CD138 (Plasma cell) Fluorescent Deconvolution of brightfield image Human lymph node

  17. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence B220 (B cell) F480 (macrophage) B220 (B Cell) Mouse spleen

  18. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Is anything gained? B220 (B Cell) Fluorescent Deconvolution of brightfield image Mouse spleen

  19. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence B220 (B Cell) F480 (macrophage) B220 (B Cell) Mouse liver

  20. Using non-fluorophores for fluorescence—Red IHC chromagens for fluorescence Is anything gained? B220 (B Cell) Fluorescent Deconvolution of brightfield image Mouse liver

  21. Registration of the same image Image registration--the process of transforming 2 or more related images into one coordinate system Fluo-rescent Bright field Merged

  22. Registration of the same image B220 (B cell) F480 (macrophage) B220 (B Cell) Mouse spleen

  23. Registration of the same image Cleaved caspase 3/B220 CD31/Smooth muscle actin B220/F480

  24. Registration of virtual images Using AE1 and AE3 (pancytokeratin) as a mask on TMAs Ki-67 +’ve cell in tumor cluster Ki-67 +’ve cell Brightfield Fluorescent Registration

  25. Registration of different images 3um step sections Chromagen 1 Chromagen 2 Pseudo color Pseudo color Merged

  26. Registration of different images CD31 3um apart CD31

  27. Registration of different images CD31pseudocolored 3um apart CD31pseudocolored

  28. Registration of different images CD31 pseudocolored CD31 pseudocolored Registered +

  29. Registration of different images CD31 3um apart Smooth muscle actin (SMA)

  30. Registration of different images CD31pseudocolored 3umapart SMA pseudocolored

  31. Registration of different images SMA pseudocolored CD31 pseudocolored Registered +

  32. Registration of virtual images Final result Automatic section alignment Michael Grunkin, Visopharm

  33. Registration of virtual images Michael Grunkin, Visopharm

  34. Registration of different images 3um step sections Chromagen 1 Fluorophore Fluo-rescent) Bright field Merged

  35. Registration of different images Imaging Mass Spectrometry Paul Kowalski, Bruker Daltonics

  36. Conclusions • Virtual microscopy is just beginning to meet its potential as a tool to analyze morphologic changes • Advances in virtual fluorescence, fluorophores, image registration and evolving image analysis programs will make image analysis easier and more accurate than ever • Increase signal, decrease noise in a consistent manner

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