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ATCC murine pre osteoblasts

Curvature-controlled orientation of cytoskeletal stress fibers on concave-cylindrical surfaces. (a) Representative confocal microscopy images depicting F-actin (magenta) and nuclei (blue) of fibroblasts, mesenchymal stromal cells, <t>osteoblasts,</t> <t>pre-osteoblasts</t> and endothelial cells seeded on flat surfaces. (b) Brass mold used to fabricate the master GeoChip from which GeoChips for use in cell culture are manufactured via sugar candy molding . Photographs show the topographic surface of the brass mold and the candy mold (Scale bar: 2 mm). Scanning electron microscopy (SEM) verified the smoothness of the resulting curved surface (half-cylinder with Ø = 1000 μm, scale bar: 200 μm). (c) Representative confocal microscopy images of cells seeded on concave-cylindrical surfaces with Ø = 100 and 1000 μm. Yellow dashed lines indicate the half-cylinder boundaries. (d-i) Distribution of stress fiber orientation quantified from the F-actin signal of cells on substrates with increasing curvature (average with standard deviation). Cartesian plots include data for fibroblasts (blue), mesenchymal stromal cells (green), osteoblasts (purple), pre-osteoblasts (orange) and endothelial cells (red). The direction 0° - 180° represents the orientation along the cylindrical surface (minimum curvature) and the direction 90° represents the orientation perpendicular to the cylindrical surface (maximum curvature). The substrate curvature experienced in dependency of the orientation is indicated by the red dashed line and red scale. Random orientation is indicated by the black dashed line. Statistical significance via Mann-Whitney test (two sided) with Bonferroni correction, ∗p < 0.05. N ≥ 3 GeoChips/cell type for a total of N ≥ 12 half-cylinders/cell type, 1 donor/cell type. Scale bars 100 μm (unless otherwise stated).

Murine Pre Osteoblasts, supplied by ATCC, used in various techniques. Bioz Stars score: 99/100, based on 2424 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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1) Product Images from "Cell type-specific response to curvature controls tissue growth dynamics in biomaterial pores"

Article Title: Cell type-specific response to curvature controls tissue growth dynamics in biomaterial pores

Journal: Bioactive Materials

doi: 10.1016/j.bioactmat.2026.02.005

Figure Legend Snippet: Curvature-controlled orientation of cytoskeletal stress fibers on concave-cylindrical surfaces. (a) Representative confocal microscopy images depicting F-actin (magenta) and nuclei (blue) of fibroblasts, mesenchymal stromal cells, osteoblasts, pre-osteoblasts and endothelial cells seeded on flat surfaces. (b) Brass mold used to fabricate the master GeoChip from which GeoChips for use in cell culture are manufactured via sugar candy molding . Photographs show the topographic surface of the brass mold and the candy mold (Scale bar: 2 mm). Scanning electron microscopy (SEM) verified the smoothness of the resulting curved surface (half-cylinder with Ø = 1000 μm, scale bar: 200 μm). (c) Representative confocal microscopy images of cells seeded on concave-cylindrical surfaces with Ø = 100 and 1000 μm. Yellow dashed lines indicate the half-cylinder boundaries. (d-i) Distribution of stress fiber orientation quantified from the F-actin signal of cells on substrates with increasing curvature (average with standard deviation). Cartesian plots include data for fibroblasts (blue), mesenchymal stromal cells (green), osteoblasts (purple), pre-osteoblasts (orange) and endothelial cells (red). The direction 0° - 180° represents the orientation along the cylindrical surface (minimum curvature) and the direction 90° represents the orientation perpendicular to the cylindrical surface (maximum curvature). The substrate curvature experienced in dependency of the orientation is indicated by the red dashed line and red scale. Random orientation is indicated by the black dashed line. Statistical significance via Mann-Whitney test (two sided) with Bonferroni correction, ∗p < 0.05. N ≥ 3 GeoChips/cell type for a total of N ≥ 12 half-cylinders/cell type, 1 donor/cell type. Scale bars 100 μm (unless otherwise stated).

Techniques Used: Confocal Microscopy, Cell Culture, Electron Microscopy, Standard Deviation, MANN-WHITNEY

Incidence of cell spanning on concave-cylindrical surfaces. (a) Lateral view of fibroblasts exposed to cylinders with increasing diameter (decreasing curvature), with spanning cells marked by yellow arrows. (b) Probability of spanning cells in relation to the half-cylinder diameter. (c-e, top to bottom) Representative 3D reconstructed images of fibroblasts, pre-osteoblasts and endothelial cells on concave-cylindrical surfaces with Ø = 100, 200 and 300 μm. Cells were reconstructed in Imaris using the F-actin (magenta, cell surface reconstruction) and nuclei (blue) signal as obtained by confocal microscopy. Half-cylinder contour is indicated by the yellow dashed line. Spanning cells are indicated by yellow arrows in subfigures c-e for clarity. Polar plots on the right depict the percentage of spanning cells and the corresponding angle of cell orientation for fibroblasts (blue), pre-osteoblasts (orange) and endothelial cells (red). The direction 0° - 180° represents the orientation along the cylindrical surface (minimum curvature) and the direction −90° - 90° represents the orientation perpendicular to the cylindrical surface (maximum curvature). (f) Confocal microscopy images of representative cell morphologies for fibroblasts, pre-osteoblasts and endothelial cells depicting F-actin (magenta), nuclei (blue) and focal adhesions via vinculin staining (green). Focal adhesions are indicated by green arrows (example shown on fibroblasts). (g) Cell length quantified as the major axis of an ellipse fitted around the cell. (h) Cell roundness with a value of 1 representing a perfect circle and value of 0 representing a straight line. (i) FSD calculated as the distance between FA clusters (see methods part for detailed description). (j) FA size distribution per cell plotted as the percentage of FAs that fall into the indicated size classes. (k) Representative force vector maps and (l) total cell force quantified via TFM. Statistical significance via Mann-Whitney test (two sided) with Bonferroni correction, ∗p < 0.05. N ≥ 3 GeoChips/cell type for a total of N ≥ 12 half-cylinders/cell type. N ≥ 60 cells/cell type for FA and morphological analysis. 1 donor/cell type. Scale bar 50 μm.

Figure Legend Snippet: Incidence of cell spanning on concave-cylindrical surfaces. (a) Lateral view of fibroblasts exposed to cylinders with increasing diameter (decreasing curvature), with spanning cells marked by yellow arrows. (b) Probability of spanning cells in relation to the half-cylinder diameter. (c-e, top to bottom) Representative 3D reconstructed images of fibroblasts, pre-osteoblasts and endothelial cells on concave-cylindrical surfaces with Ø = 100, 200 and 300 μm. Cells were reconstructed in Imaris using the F-actin (magenta, cell surface reconstruction) and nuclei (blue) signal as obtained by confocal microscopy. Half-cylinder contour is indicated by the yellow dashed line. Spanning cells are indicated by yellow arrows in subfigures c-e for clarity. Polar plots on the right depict the percentage of spanning cells and the corresponding angle of cell orientation for fibroblasts (blue), pre-osteoblasts (orange) and endothelial cells (red). The direction 0° - 180° represents the orientation along the cylindrical surface (minimum curvature) and the direction −90° - 90° represents the orientation perpendicular to the cylindrical surface (maximum curvature). (f) Confocal microscopy images of representative cell morphologies for fibroblasts, pre-osteoblasts and endothelial cells depicting F-actin (magenta), nuclei (blue) and focal adhesions via vinculin staining (green). Focal adhesions are indicated by green arrows (example shown on fibroblasts). (g) Cell length quantified as the major axis of an ellipse fitted around the cell. (h) Cell roundness with a value of 1 representing a perfect circle and value of 0 representing a straight line. (i) FSD calculated as the distance between FA clusters (see methods part for detailed description). (j) FA size distribution per cell plotted as the percentage of FAs that fall into the indicated size classes. (k) Representative force vector maps and (l) total cell force quantified via TFM. Statistical significance via Mann-Whitney test (two sided) with Bonferroni correction, ∗p < 0.05. N ≥ 3 GeoChips/cell type for a total of N ≥ 12 half-cylinders/cell type. N ≥ 60 cells/cell type for FA and morphological analysis. 1 donor/cell type. Scale bar 50 μm.

Techniques Used: Confocal Microscopy, Staining, Plasmid Preparation, MANN-WHITNEY

Cell spanning initiates channel closure and subsequent tissue remodeling. (a) Fabrication of full-cylindrical channels with Ø = 250 μm in PDMS substrates by direct molding from a micro-machined brass mold. (b) Degree of channel closure representing the distribution of cells within the channels at the selected points in time during live confocal imaging. A value of 0 indicates that cells are exclusively found at the wall of the channel and a value of 1 indicates cells have completely closed the channel and are homogeneously distributed. (c) Relative degree of alignment of the cell-network within the channels quantified as the maximum value of the orientation distribution for the individual cell types and time points normalized to the highest detected value of all conditions (see also Supplementary Data S2). Higher values indicate a higher degree of alignment along the channel axis. (d-f) Lateral and front view of the PDMS cylindrical channels obtained by live confocal imaging of fibroblasts (blue), pre-osteoblasts (orange) and endothelial cells (red) using CellTracker™ Green ( t = 4, 12, 24 and 48 h after seeding). Open arrows indicate cells spanning perpendicular to the channel axis. Full arrows indicate cells oriented along the direction of the channel axis after channel closure. Channel contour is highlighted by the yellow dashed lines. The surface of the forming tissue is marked by red dashed lines. White dashed lines indicate the z-volume that is shown in the corresponding lateral views. Statistical significance via Mann-Whitney test with Bonferroni correction, ∗p < 0.05. N = 3 cylindrical channels/cell type. 1 donor/cell type. Scale bars 100 μm.

Figure Legend Snippet: Cell spanning initiates channel closure and subsequent tissue remodeling. (a) Fabrication of full-cylindrical channels with Ø = 250 μm in PDMS substrates by direct molding from a micro-machined brass mold. (b) Degree of channel closure representing the distribution of cells within the channels at the selected points in time during live confocal imaging. A value of 0 indicates that cells are exclusively found at the wall of the channel and a value of 1 indicates cells have completely closed the channel and are homogeneously distributed. (c) Relative degree of alignment of the cell-network within the channels quantified as the maximum value of the orientation distribution for the individual cell types and time points normalized to the highest detected value of all conditions (see also Supplementary Data S2). Higher values indicate a higher degree of alignment along the channel axis. (d-f) Lateral and front view of the PDMS cylindrical channels obtained by live confocal imaging of fibroblasts (blue), pre-osteoblasts (orange) and endothelial cells (red) using CellTracker™ Green ( t = 4, 12, 24 and 48 h after seeding). Open arrows indicate cells spanning perpendicular to the channel axis. Full arrows indicate cells oriented along the direction of the channel axis after channel closure. Channel contour is highlighted by the yellow dashed lines. The surface of the forming tissue is marked by red dashed lines. White dashed lines indicate the z-volume that is shown in the corresponding lateral views. Statistical significance via Mann-Whitney test with Bonferroni correction, ∗p < 0.05. N = 3 cylindrical channels/cell type. 1 donor/cell type. Scale bars 100 μm.

Techniques Used: Imaging, MANN-WHITNEY

Channel closure mechanism can be controlled by substrate curvature using scaffolds with well-defined geometries. (a, left) Schematic representation of the in vitro culture setup with collagen scaffold presenting channels of controlled diameter with Ø ≈ 600 μm, Ø ≈ 350 μm and Ø ≈ 150 μm. Monolayer seeding on one side of the biomaterial facilitates migration of cells from one end of the biomaterial. (a, right) SEM image of the microarchitecture (Scale bar 20 μm) and channels within the biomaterial (Scale bars 100 μm). SEM images correspond to the outermost surface of the scaffold. (b) Comparison of template diameter against resulting channel diameter after cross-linking and sterilization of the biomaterial. (c) Representative images of fibroblasts, pre-osteoblasts and endothelial cells within channels of distinct diameters 7 days after seeding. Cell cytoskeleton (F-actin) is depicted in magenta and nuclei in blue. Yellow arrows indicate the direction (arrow angle) and degree of alignment (vector length) for the corresponding region. Scale bar close-up images: 25 μm. (d, left) Degree of channel closure for the investigated channel diameters and cell types. (d, right) Relative degree of tissue alignment for the different channel diameters and cell types. Tissue alignment ranges from 0 (fully isotropic) to 1 (fully anisotropic, dashed line). Tissue across the channel and relative degree of is calculated in the central 50 % of each channel. Data displayed as average with standard deviation. N = 4 scaffolds/cell type. 1 donor/cell type. Scale bars 200 μm (unless otherwise stated).

Figure Legend Snippet: Channel closure mechanism can be controlled by substrate curvature using scaffolds with well-defined geometries. (a, left) Schematic representation of the in vitro culture setup with collagen scaffold presenting channels of controlled diameter with Ø ≈ 600 μm, Ø ≈ 350 μm and Ø ≈ 150 μm. Monolayer seeding on one side of the biomaterial facilitates migration of cells from one end of the biomaterial. (a, right) SEM image of the microarchitecture (Scale bar 20 μm) and channels within the biomaterial (Scale bars 100 μm). SEM images correspond to the outermost surface of the scaffold. (b) Comparison of template diameter against resulting channel diameter after cross-linking and sterilization of the biomaterial. (c) Representative images of fibroblasts, pre-osteoblasts and endothelial cells within channels of distinct diameters 7 days after seeding. Cell cytoskeleton (F-actin) is depicted in magenta and nuclei in blue. Yellow arrows indicate the direction (arrow angle) and degree of alignment (vector length) for the corresponding region. Scale bar close-up images: 25 μm. (d, left) Degree of channel closure for the investigated channel diameters and cell types. (d, right) Relative degree of tissue alignment for the different channel diameters and cell types. Tissue alignment ranges from 0 (fully isotropic) to 1 (fully anisotropic, dashed line). Tissue across the channel and relative degree of is calculated in the central 50 % of each channel. Data displayed as average with standard deviation. N = 4 scaffolds/cell type. 1 donor/cell type. Scale bars 200 μm (unless otherwise stated).

Techniques Used: In Vitro, Migration, Comparison, Plasmid Preparation, Standard Deviation

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Journal: Bioactive Materials

Article Title: Cell type-specific response to curvature controls tissue growth dynamics in biomaterial pores

doi: 10.1016/j.bioactmat.2026.02.005

Figure Lengend Snippet: Curvature-controlled orientation of cytoskeletal stress fibers on concave-cylindrical surfaces. (a) Representative confocal microscopy images depicting F-actin (magenta) and nuclei (blue) of fibroblasts, mesenchymal stromal cells, osteoblasts, pre-osteoblasts and endothelial cells seeded on flat surfaces. (b) Brass mold used to fabricate the master GeoChip from which GeoChips for use in cell culture are manufactured via sugar candy molding . Photographs show the topographic surface of the brass mold and the candy mold (Scale bar: 2 mm). Scanning electron microscopy (SEM) verified the smoothness of the resulting curved surface (half-cylinder with Ø = 1000 μm, scale bar: 200 μm). (c) Representative confocal microscopy images of cells seeded on concave-cylindrical surfaces with Ø = 100 and 1000 μm. Yellow dashed lines indicate the half-cylinder boundaries. (d-i) Distribution of stress fiber orientation quantified from the F-actin signal of cells on substrates with increasing curvature (average with standard deviation). Cartesian plots include data for fibroblasts (blue), mesenchymal stromal cells (green), osteoblasts (purple), pre-osteoblasts (orange) and endothelial cells (red). The direction 0° - 180° represents the orientation along the cylindrical surface (minimum curvature) and the direction 90° represents the orientation perpendicular to the cylindrical surface (maximum curvature). The substrate curvature experienced in dependency of the orientation is indicated by the red dashed line and red scale. Random orientation is indicated by the black dashed line. Statistical significance via Mann-Whitney test (two sided) with Bonferroni correction, ∗p < 0.05. N ≥ 3 GeoChips/cell type for a total of N ≥ 12 half-cylinders/cell type, 1 donor/cell type. Scale bars 100 μm (unless otherwise stated).

Article Snippet: Murine pre-osteoblasts (MC3T3-E1, CRL-2593TM, ATCC) were cultured in alpha modified minimum essential medium with nucleosides (F 0925, Biochrom AG), supplemented with 10 % v/v FBS, 1 % v/v P/S and 1 % v/v GlutaMAX (35050, Gibco®).

Techniques: Confocal Microscopy, Cell Culture, Electron Microscopy, Standard Deviation, MANN-WHITNEY

Journal: Bioactive Materials

Article Title: Cell type-specific response to curvature controls tissue growth dynamics in biomaterial pores

doi: 10.1016/j.bioactmat.2026.02.005

Figure Lengend Snippet: Incidence of cell spanning on concave-cylindrical surfaces. (a) Lateral view of fibroblasts exposed to cylinders with increasing diameter (decreasing curvature), with spanning cells marked by yellow arrows. (b) Probability of spanning cells in relation to the half-cylinder diameter. (c-e, top to bottom) Representative 3D reconstructed images of fibroblasts, pre-osteoblasts and endothelial cells on concave-cylindrical surfaces with Ø = 100, 200 and 300 μm. Cells were reconstructed in Imaris using the F-actin (magenta, cell surface reconstruction) and nuclei (blue) signal as obtained by confocal microscopy. Half-cylinder contour is indicated by the yellow dashed line. Spanning cells are indicated by yellow arrows in subfigures c-e for clarity. Polar plots on the right depict the percentage of spanning cells and the corresponding angle of cell orientation for fibroblasts (blue), pre-osteoblasts (orange) and endothelial cells (red). The direction 0° - 180° represents the orientation along the cylindrical surface (minimum curvature) and the direction −90° - 90° represents the orientation perpendicular to the cylindrical surface (maximum curvature). (f) Confocal microscopy images of representative cell morphologies for fibroblasts, pre-osteoblasts and endothelial cells depicting F-actin (magenta), nuclei (blue) and focal adhesions via vinculin staining (green). Focal adhesions are indicated by green arrows (example shown on fibroblasts). (g) Cell length quantified as the major axis of an ellipse fitted around the cell. (h) Cell roundness with a value of 1 representing a perfect circle and value of 0 representing a straight line. (i) FSD calculated as the distance between FA clusters (see methods part for detailed description). (j) FA size distribution per cell plotted as the percentage of FAs that fall into the indicated size classes. (k) Representative force vector maps and (l) total cell force quantified via TFM. Statistical significance via Mann-Whitney test (two sided) with Bonferroni correction, ∗p < 0.05. N ≥ 3 GeoChips/cell type for a total of N ≥ 12 half-cylinders/cell type. N ≥ 60 cells/cell type for FA and morphological analysis. 1 donor/cell type. Scale bar 50 μm.

Techniques: Confocal Microscopy, Staining, Plasmid Preparation, MANN-WHITNEY

Journal: Bioactive Materials

Article Title: Cell type-specific response to curvature controls tissue growth dynamics in biomaterial pores

doi: 10.1016/j.bioactmat.2026.02.005

Figure Lengend Snippet: Cell spanning initiates channel closure and subsequent tissue remodeling. (a) Fabrication of full-cylindrical channels with Ø = 250 μm in PDMS substrates by direct molding from a micro-machined brass mold. (b) Degree of channel closure representing the distribution of cells within the channels at the selected points in time during live confocal imaging. A value of 0 indicates that cells are exclusively found at the wall of the channel and a value of 1 indicates cells have completely closed the channel and are homogeneously distributed. (c) Relative degree of alignment of the cell-network within the channels quantified as the maximum value of the orientation distribution for the individual cell types and time points normalized to the highest detected value of all conditions (see also Supplementary Data S2). Higher values indicate a higher degree of alignment along the channel axis. (d-f) Lateral and front view of the PDMS cylindrical channels obtained by live confocal imaging of fibroblasts (blue), pre-osteoblasts (orange) and endothelial cells (red) using CellTracker™ Green ( t = 4, 12, 24 and 48 h after seeding). Open arrows indicate cells spanning perpendicular to the channel axis. Full arrows indicate cells oriented along the direction of the channel axis after channel closure. Channel contour is highlighted by the yellow dashed lines. The surface of the forming tissue is marked by red dashed lines. White dashed lines indicate the z-volume that is shown in the corresponding lateral views. Statistical significance via Mann-Whitney test with Bonferroni correction, ∗p < 0.05. N = 3 cylindrical channels/cell type. 1 donor/cell type. Scale bars 100 μm.

Techniques: Imaging, MANN-WHITNEY

Journal: Bioactive Materials

Article Title: Cell type-specific response to curvature controls tissue growth dynamics in biomaterial pores

doi: 10.1016/j.bioactmat.2026.02.005

Figure Lengend Snippet: Channel closure mechanism can be controlled by substrate curvature using scaffolds with well-defined geometries. (a, left) Schematic representation of the in vitro culture setup with collagen scaffold presenting channels of controlled diameter with Ø ≈ 600 μm, Ø ≈ 350 μm and Ø ≈ 150 μm. Monolayer seeding on one side of the biomaterial facilitates migration of cells from one end of the biomaterial. (a, right) SEM image of the microarchitecture (Scale bar 20 μm) and channels within the biomaterial (Scale bars 100 μm). SEM images correspond to the outermost surface of the scaffold. (b) Comparison of template diameter against resulting channel diameter after cross-linking and sterilization of the biomaterial. (c) Representative images of fibroblasts, pre-osteoblasts and endothelial cells within channels of distinct diameters 7 days after seeding. Cell cytoskeleton (F-actin) is depicted in magenta and nuclei in blue. Yellow arrows indicate the direction (arrow angle) and degree of alignment (vector length) for the corresponding region. Scale bar close-up images: 25 μm. (d, left) Degree of channel closure for the investigated channel diameters and cell types. (d, right) Relative degree of tissue alignment for the different channel diameters and cell types. Tissue alignment ranges from 0 (fully isotropic) to 1 (fully anisotropic, dashed line). Tissue across the channel and relative degree of is calculated in the central 50 % of each channel. Data displayed as average with standard deviation. N = 4 scaffolds/cell type. 1 donor/cell type. Scale bars 200 μm (unless otherwise stated).

Techniques: In Vitro, Migration, Comparison, Plasmid Preparation, Standard Deviation

ARS staining and analysis of the effect of various endodontic sealers in MC3T3-E1 cells. ( A ) Schematic diagram of the experimental workflow. Sealers (10 μL spots, 3 mm in diameter) were placed at the center of 6-well plates, allowed to set for 24 h in a laminar flow hood, and sterilized by UV irradiation for 30 min before cell seeding. MC3T3-E1 pre-osteoblasts were then cultured and analyzed by ARS staining, qRT-PCR, and Western blotting. ( B ) Representative images of ARS staining of MC3T3-E1 cells cultured with various endodontic sealers: AH26 ® , ZOE, BC, and Sealapex™. ( C ) Quantification of ARS staining intensity using ImageJ (NIH). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (* p < 0.01, *** p < 0.0001, n.s., not significant).

Journal: Dentistry Journal

Article Title: In Vitro Assessment of Osteogenic Modulation and Molecular Responses Induced by Contemporary Endodontic Sealers in MC3T3-E1 Pre-Osteoblasts

doi: 10.3390/dj14030160

Figure Lengend Snippet: ARS staining and analysis of the effect of various endodontic sealers in MC3T3-E1 cells. ( A ) Schematic diagram of the experimental workflow. Sealers (10 μL spots, 3 mm in diameter) were placed at the center of 6-well plates, allowed to set for 24 h in a laminar flow hood, and sterilized by UV irradiation for 30 min before cell seeding. MC3T3-E1 pre-osteoblasts were then cultured and analyzed by ARS staining, qRT-PCR, and Western blotting. ( B ) Representative images of ARS staining of MC3T3-E1 cells cultured with various endodontic sealers: AH26 ® , ZOE, BC, and Sealapex™. ( C ) Quantification of ARS staining intensity using ImageJ (NIH). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (* p < 0.01, *** p < 0.0001, n.s., not significant).

Article Snippet: Murine MC3T3-E1 Subclone 4 pre-osteoblasts (ATCC CRL-2593TM, ATCC, Manassas, VA, USA) were maintained in α-MEM supplemented with 10% fetal bovine serum and 1% penicillin/streptomycin at 37 °C in a humidified atmosphere containing 5% CO 2 .

Techniques: Staining, Irradiation, Cell Culture, Quantitative RT-PCR, Western Blot

Osteogenic potential of ZOE and BC sealers in MC3T3-E1 cells. ( A ) Representative images of ARS staining of MC3T3-E1 cells cultured with ZOE or BC sealers. ( B ) Quantitative analysis of ARS staining intensity (ImageJ). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by Student’s t -test (* p < 0.01). ( C ) Representative images of ARS staining of cells cultured with ZOE and BC for 7 and 14 days after osteogenic induction. Scale bars = 100 μm. ( D ) Quantitative analysis of ARS staining intensity at 7 and 14 days after switching to OI medium. Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (** p < 0.001). ( E ) Runx2 mRNA expression in cells cultured under control (no sealer), ZOE, and BC conditions for 1 week after switching to OI medium (qRT-PCR). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (** p < 0.001). ( F ) Sp7 (Osx) mRNA expression in cells cultured under control (no sealer), ZOE, and BC conditions for 1 week after switching to OI medium (qRT-PCR). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (** p < 0.001, n.s., not significant).

Journal: Dentistry Journal

Article Title: In Vitro Assessment of Osteogenic Modulation and Molecular Responses Induced by Contemporary Endodontic Sealers in MC3T3-E1 Pre-Osteoblasts

doi: 10.3390/dj14030160

Figure Lengend Snippet: Osteogenic potential of ZOE and BC sealers in MC3T3-E1 cells. ( A ) Representative images of ARS staining of MC3T3-E1 cells cultured with ZOE or BC sealers. ( B ) Quantitative analysis of ARS staining intensity (ImageJ). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by Student’s t -test (* p < 0.01). ( C ) Representative images of ARS staining of cells cultured with ZOE and BC for 7 and 14 days after osteogenic induction. Scale bars = 100 μm. ( D ) Quantitative analysis of ARS staining intensity at 7 and 14 days after switching to OI medium. Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (** p < 0.001). ( E ) Runx2 mRNA expression in cells cultured under control (no sealer), ZOE, and BC conditions for 1 week after switching to OI medium (qRT-PCR). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (** p < 0.001). ( F ) Sp7 (Osx) mRNA expression in cells cultured under control (no sealer), ZOE, and BC conditions for 1 week after switching to OI medium (qRT-PCR). Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (** p < 0.001, n.s., not significant).

Techniques: Staining, Cell Culture, Expressing, Control, Quantitative RT-PCR

Effects of ZOE and BC sealers on MC3T3-E1 cell viability and MAPK signaling. ( A ) Western blot analysis of phosphorylated and total c-Jun, p38, and Erk in cells cultured with ZOE or BC for 1 week. Gapdh (loading control). Phospho-c-Jun, p38, and Erk band intensities were normalized to their respective total protein levels. ( B ) Representative images of MC3T3-E1 cells cultured in the presence of ZOE or BC for 4 and 5 days. Scale bars: 100 μm (white), 50 μm (black). ( C , D ) Quantification of cell numbers around sealer spots at day 4 ( C ) and day 5 ( D ). The number of cells in five random fields was counted per experimental condition under light microscopy. Data are presented as mean ± SD, and the experiments were repeated three times. Statistical significance was assessed by Student’s t -test (** p < 0.001). ( E , F ) Percentages of viable ( E ) and non-viable ( F ) cells on day 5 determined by trypan blue exclusion. Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by Student’s t -test (** p < 0.001).

Journal: Dentistry Journal

Article Title: In Vitro Assessment of Osteogenic Modulation and Molecular Responses Induced by Contemporary Endodontic Sealers in MC3T3-E1 Pre-Osteoblasts

doi: 10.3390/dj14030160

Figure Lengend Snippet: Effects of ZOE and BC sealers on MC3T3-E1 cell viability and MAPK signaling. ( A ) Western blot analysis of phosphorylated and total c-Jun, p38, and Erk in cells cultured with ZOE or BC for 1 week. Gapdh (loading control). Phospho-c-Jun, p38, and Erk band intensities were normalized to their respective total protein levels. ( B ) Representative images of MC3T3-E1 cells cultured in the presence of ZOE or BC for 4 and 5 days. Scale bars: 100 μm (white), 50 μm (black). ( C , D ) Quantification of cell numbers around sealer spots at day 4 ( C ) and day 5 ( D ). The number of cells in five random fields was counted per experimental condition under light microscopy. Data are presented as mean ± SD, and the experiments were repeated three times. Statistical significance was assessed by Student’s t -test (** p < 0.001). ( E , F ) Percentages of viable ( E ) and non-viable ( F ) cells on day 5 determined by trypan blue exclusion. Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by Student’s t -test (** p < 0.001).

Techniques: Western Blot, Cell Culture, Control, Light Microscopy

Effects of MAPK inhibition on BC-induced osteogenic differentiation in MC3T3-E1 cells. ( A , B ) qRT-PCR analysis of Runx2 ( A ) and Sp7 ( Osx ) ( B ) expression after 1 week of culture in OI medium under control conditions (no sealer), BC, or BC combined with MAPK inhibitors [U0126 (Erk), SB203580 (p38), SP600125 (Jnk)]. Expression levels were normalized to Gapdh . Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (* p < 0.01). ( C ) Western blot analysis of Runx2, Sp7 (Osx), p-c-Jun, c-Jun, p-p38, p38, p-Erk, and Erk under the same conditions as ( A ). Gapdh (loading control). ( D ) Representative of ARS staining images of cells cultured with control (no sealer), BC, or BC plus MAPK inhibitors for 2 weeks with OIM. Scale bars = 100 μm. ( E ) Quantification of ARS staining intensity using ImageJ. Data are presented as mean ± SD from 5 fields, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (*** p < 0.0001). ( F ) Proposed schematic model, based on the present findings, illustrating that the BC sealer regulates MAPK signaling pathways (Jnk, p38, Erk) to induce osteogenic differentiation by modulating the expression of Runx2 and Sp7 ( Osx ) in pre-osteoblasts.

Journal: Dentistry Journal

Article Title: In Vitro Assessment of Osteogenic Modulation and Molecular Responses Induced by Contemporary Endodontic Sealers in MC3T3-E1 Pre-Osteoblasts

doi: 10.3390/dj14030160

Figure Lengend Snippet: Effects of MAPK inhibition on BC-induced osteogenic differentiation in MC3T3-E1 cells. ( A , B ) qRT-PCR analysis of Runx2 ( A ) and Sp7 ( Osx ) ( B ) expression after 1 week of culture in OI medium under control conditions (no sealer), BC, or BC combined with MAPK inhibitors [U0126 (Erk), SB203580 (p38), SP600125 (Jnk)]. Expression levels were normalized to Gapdh . Data are presented as mean ± SD from triplicate assays, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (* p < 0.01). ( C ) Western blot analysis of Runx2, Sp7 (Osx), p-c-Jun, c-Jun, p-p38, p38, p-Erk, and Erk under the same conditions as ( A ). Gapdh (loading control). ( D ) Representative of ARS staining images of cells cultured with control (no sealer), BC, or BC plus MAPK inhibitors for 2 weeks with OIM. Scale bars = 100 μm. ( E ) Quantification of ARS staining intensity using ImageJ. Data are presented as mean ± SD from 5 fields, and the experiments were repeated three times. Statistical significance was assessed by one-way ANOVA with Tukey’s post hoc test (*** p < 0.0001). ( F ) Proposed schematic model, based on the present findings, illustrating that the BC sealer regulates MAPK signaling pathways (Jnk, p38, Erk) to induce osteogenic differentiation by modulating the expression of Runx2 and Sp7 ( Osx ) in pre-osteoblasts.

Techniques: Inhibition, Quantitative RT-PCR, Expressing, Control, Western Blot, Staining, Cell Culture, Protein-Protein interactions

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