Green fluorescent protein (GFP) was originally derived from the cnidarians Aequorea victoria. GFP-positive stem cells can be tracked in vivo when used in the therapy of diseases. However, in the bone, the fluorescence generated by GFP can be lost during the decalcification process, hindering the tracking of stem cells used in the treatment of diseases or bone defects. The aim of this study was to compare different techniques of preservation of GFP in the decalcified bone tissue. Femurs of female Lewis GFP rats were distributed in four groups: 1) decalcified in formic acid and paraffin-embedded; 2) decalcified in formic acid submitted to cryomicrotomy; 3) decalcified in EDTA and paraffin-embedded and 4) decalcified in EDTA with cryomicrotomy. Sections of bone tissue of all the groups were analyzed for identification of the natural fluorescence and subsequently submitted to the immunofluorescence using anti-GFP and Alexa Flúor 555. The images were obtained by confocal microscopy. Osteocytes, osteoblasts and bone marrow cells of GFP rats only had natural fluorescence preserved in the bone tissue decalcified in EDTA and submitted to cryomicrotomy. In others groups there were loss of the natural fluorescence and the GFP cells could be only identified with the use of the immunofluorescence with anti-GFP. In conclusion, the decalcification in EDTA and the cryomicrotomy are the best techniques to preserve the natural fluorescence of the GFP cells in the bone tissue and the GFP cells in bone tissue decalcified in formic acid and paraffin-embedded can be visualized only with the use of the immunofluorescence with anti-GFP.
green fluorescent protein (GFP); decalcification; bone
