Multiwall carbon nanotubes/polycaprolactone scaffolds seeded with human dental pulp stem cells for bone tissue regeneration
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Conventional approaches to bone regeneration rarely use multiwall carbon nanotubes (MWCNTs) but instead use polymeric matrices filled with hydroxyapatite, calcium phosphates and bioactive glasses. In this study, we prepared composites of MWCNTs/polycaprolactone (PCL) for bone regeneration as follows: (a) MWCNTs randomly dispersed on PCL, (b) MWCNTs aligned with an electrical field to determine if the orientation favors the growing of human dental pulp stem cells (HDPSCs), and (c) MWCNTs modified with β-glycerol phosphate (BGP) to analyze its osteogenic potential. Raman spectroscopy confirmed the presence of MWCNTs and BGP on PCL, whereas the increase in crystallinity by the addition of MWCNTs to PCL was confirmed by X-ray diffraction and differential scanning calorimetry. A higher elastic modulus (608 ± 4.3 MPa), maximum stress (42 ± 6.1 MPa) and electrical conductivity (1.67 × 10−7 S/m) were observed in non-aligned MWCNTs compared with the pristine PCL. Cell viability at 14 days was similar in all samples according to the live/dead assay, but the 21 day cell proliferation, measured by MTT was higher in MWCNTs aligned with BGP. Von Kossa and Alizarin red showed larger amounts of mineral deposits on MWCNTs aligned with BGP, indicating that at 21 days, this scaffold promotes osteogenic differentiation of HDPSCs. © 2015, Springer Science Business Media New York.
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Conventional approaches to bone regeneration rarely use multiwall carbon nanotubes (MWCNTs) but instead use polymeric matrices filled with hydroxyapatite, calcium phosphates and bioactive glasses. In this study, we prepared composites of MWCNTs/polycaprolactone (PCL) for bone regeneration as follows: (a) MWCNTs randomly dispersed on PCL, (b) MWCNTs aligned with an electrical field to determine if the orientation favors the growing of human dental pulp stem cells (HDPSCs), and (c) MWCNTs modified with β-glycerol phosphate (BGP) to analyze its osteogenic potential. Raman spectroscopy confirmed the presence of MWCNTs and BGP on PCL, whereas the increase in crystallinity by the addition of MWCNTs to PCL was confirmed by X-ray diffraction and differential scanning calorimetry. A higher elastic modulus (608 ± 4.3 MPa), maximum stress (42 ± 6.1 MPa) and electrical conductivity (1.67 × 10−7 S/m) were observed in non-aligned MWCNTs compared with the pristine PCL. Cell viability at 14 days was similar in all samples according to the live/dead assay, but the 21 day cell proliferation, measured by MTT was higher in MWCNTs aligned with BGP. Von Kossa and Alizarin red showed larger amounts of mineral deposits on MWCNTs aligned with BGP, indicating that at 21 days, this scaffold promotes osteogenic differentiation of HDPSCs. © 2015, Springer Science%2bBusiness Media New York.
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Bioactive glass; Bone; Calcium phosphate; Cell proliferation; Cytology; Dental composites; Differential scanning calorimetry; Hydroxyapatite; Mineral resources; Scaffolds (biology); Stem cells; Tissue regeneration; X ray diffraction; Yarn; Bone tissue regeneration; Conventional approach; Dental pulp stem cells; Electrical conductivity; Glycerol phosphate; Osteogenic differentiation; Osteogenic potential; Polymeric matrices; Multiwalled carbon nanotubes (MWCN); alizarin red s; beta glycerol phosphate; calcium phosphate; glycerophosphate; hydroxyapatite; multi walled nanotube; polycaprolactone; unclassified drug; carbon nanotube; polycaprolactone; polyester; adolescent; adult; Article; biocompatibility; bone development; bone regeneration; cell differentiation; cell proliferation; cell viability; controlled study; dental pulp stem cell; differential scanning calorimetry; electric conductivity; electric field; human; human cell; mineralization; MTT assay; priority journal; Raman spectrometry; stem cell; X ray diffraction; Young modulus; bone; cell culture; cell culture technique; chemistry; cytology; devices; materials testing; physiology; procedures; stem cell; tissue engineering; tissue scaffold; tooth pulp; young adult; Adolescent; Adult; Bone and Bones; Bone Regeneration; Cell Culture Techniques; Cells, Cultured; Dental Pulp; Humans; Materials Testing; Nanotubes, Carbon; Osteogenesis; Polyesters; Stem Cells; Tissue Engineering; Tissue Scaffolds; Young Adult
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