Trypan blue viability test of the labeled and unlabeled MSCs showed a significant decrease in high labeling concentration 100 and 125 µg/mL... To evaluate the effect of the ferucarbotran
Trang 1Figure 3-7 Trypan blue viability test
Trypan blue viability test of the labeled and unlabeled MSCs showed a
significant decrease in high labeling concentration (100 and 125 µg/mL)
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Labeling medium iron concentration (µg/ml)
Trang 2Figure 3-8 MTS assay
MTS assay showed that labeling of the MSCs did not affect the proliferation rate of the cells over time
3.4.6 Differentiation potential of labeled MSC
MSCs are multipotent stem cells, which can differentiate to different lineage (77, 78, 198, 199) To evaluate the effect of the ferucarbotran labeling on the multipotent potential, we assessed the adipogenic (figure 3.9), osteogenic (figure 3.10), and chondrogenic (figure 3.11) differentiation capacity of the labeled cells
3.4.6.1 Adipogenic differentiation
Qualitative evaluation of adipogenic differentiation after 21 days by Oil red O staining demonstrated that unlabeled and labeled cells exhibited no difference
in developing fat vacuoles (Figure 3.9)
Trang 3Figure 3-9 Oil red O staining
Oil red O staining of the MSCs after 21 days adipogenic differentiation
induction; Unlabeled (A), labeled with 25 µg/ml ferucarbotran (B), labeled with
50 µg/ml ferucarbotran (C), labeled with 75 µg/ml ferucarbotran (D), labeled with 100 µg/ml ferucarbotran (E), labeled with 125 µg/ml ferucarbotran (F)
3.4.6.2 Osteogenic differentiation
Alizarin red staining showed that MSCs labeled with SPIO did not affect osteogenic differentiation capacity of cells (figure 3.10)
Figure 3-10 Alizarin Red staining
Alizarin Red staining of the MSCs was used to visualize the calcium
deposition of the cells after 21 days osteogenic differentiation induction; Unlabeled (A), labeled with 25 µg/ml ferucarbotran (B), labeled with 50 µg/ml ferucarbotran (C), labeled with 75 µg/ml ferucarbotran (D), labeled with 100
Trang 43.4.6.3 Chondrogenic differentiation
Immunohistochemical staining after high density pellet culturing showed that the distribution of collagen type II in extracellular matrix of cells was same between unlabeled and 25 and 50 µg/mL SPIO labeling, however the matrix production were decreased in labeling concentration of higher than 75 µg/mL SPIO (Figure 3.11) Alcian blue staining also showed the inhibition of the Aggrecan production in labeling concentration of the 75 µg/mL or higher Prussian blue was used to show the presence of iron particles
Interestingly, SPIO labeled MSCs separated into distinct areas; the areas with less Prussian blue stains (less iron content) showed more collagen type II and aggrecan production It appears that the inhibition seemed to be related to the cellular iron content, increasing the labeling concentration could inhibit
chondrogenesis
Trang 5Figure 3-11 Chondrogenic differentiation potential evaluation of the MSCs
Upper panel shows the Alcian blue staining of unlabeled and labeled cells with different concentration of ferucarbotran (25µg/mL, 50µg/mL, 75µg/mL, 100µg/mL, 125µg/mL) Middle panel shows the immunohistochemistry against collagen type
II in all groups and lower panel demonstrate the Prussian blue staining of the cell pellets to visualize the iron particles as blue dots in the cells (Scale bar is equal to 100 µm)
Trang 63.4.7 MR imaging of animals
3.4.7.1 Preliminary experiments
To optimize the sequences that we needed to visualize the articular cartilage
of the pig knee, we performed a trial MRI to test different coils and sequences
on the pigs’ normal knee Figure 3.12 showed chondral defect without / with different fillings Blank defect was the defect with no filling (air), which made a signal loss (dark defect) in both FSE and GRE sequences Defect with
scaffold only (1% agarose) filling showed an iso-intense signal to adjacent cartilage in both FSE and GRE sequences Defects filled with the agarose mixed with different amount of Ferucarbotran, which can be a representative
of different concentrations of the labeled cells (the average amount of the iron nanoparticles per cell was assumed as 10ng/cell; e.g 1, 10, 1000 µg iron nanoparticles were mixed with agarose as representative of 100, 1000,
100000 cells) We showed the efficacy of specifically imaging proton density (short TE FSE) for anatomical data and the sensitivity of gradient echo
sequences (SPGR and 2D/3D-GRE) to signal loss due to iron nanoparticles to reveal contrast between newly formed tissue and the incorporated iron
nanoparticles (Fe) The FIESTA sequence was also useful in the context of proton density, however FIESTA images with Fe injected into the knee space (to simulate unattached labeled cells) contained artifacts, which could
interfere with interpretation
Trang 7Figure 3-12 MR imaging of the Pig's knee explant
MR images of the pig’s knee explants with blank and scaffold only defect (A), 100 cells simulation (B), 1000 cells simulation (C), and 100,000 cells simulation (D) Left panel of each image is 3D-FSE sequence and Right panel is 3D SPGR sequence