Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement

The aim of this study was to predefine the pore structure of β-tricalcium phosphate (β-TCP) scaffolds with different macro pore sizes (500, 750, and 1000 µm), to characterize β-TCP scaffolds, and to investigate the growth behavior of cells within these scaffolds. The lead structures for directional...

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Autores principales: Seidenstuecker, Michael, Lange, Svenja, Esslinger, Steffen, Latorre, Sergio H., Krastev, Rumen, Gadow, Rainer, Mayr, Hermann O., Bernstein, Anke
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2019
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Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6829219/
https://www.ncbi.nlm.nih.gov/pubmed/31635363
http://dx.doi.org/10.3390/ma12203417
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author Seidenstuecker, Michael
Lange, Svenja
Esslinger, Steffen
Latorre, Sergio H.
Krastev, Rumen
Gadow, Rainer
Mayr, Hermann O.
Bernstein, Anke
author_facet Seidenstuecker, Michael
Lange, Svenja
Esslinger, Steffen
Latorre, Sergio H.
Krastev, Rumen
Gadow, Rainer
Mayr, Hermann O.
Bernstein, Anke
author_sort Seidenstuecker, Michael
collection PubMed
description The aim of this study was to predefine the pore structure of β-tricalcium phosphate (β-TCP) scaffolds with different macro pore sizes (500, 750, and 1000 µm), to characterize β-TCP scaffolds, and to investigate the growth behavior of cells within these scaffolds. The lead structures for directional bone growth (sacrificial structures) were produced from polylactide (PLA) using the fused deposition modeling techniques. The molds were then filled with β-TCP slurry and sintered at 1250 °C, whereby the lead structures (voids) were burnt out. The scaffolds were mechanically characterized (native and after incubation in simulated body fluid (SBF) for 28 d). In addition, biocompatibility was investigated by live/dead, cell proliferation and lactate dehydrogenase assays. The scaffolds with a strand spacing of 500 µm showed the highest compressive strength, both untreated (3.4 ± 0.2 MPa) and treated with simulated body fluid (2.8 ± 0.2 MPa). The simulated body fluid reduced the stability of the samples to 82% (500), 62% (750) and 56% (1000). The strand spacing and the powder properties of the samples were decisive factors for stability. The fact that β-TCP is a biocompatible material is confirmed by the experiments. No lactate dehydrogenase activity of the cells was measured, which means that no cytotoxicity of the material could be detected. In addition, the proliferation rate of all three sizes increased steadily over the test days until saturation. The cells were largely adhered to or within the scaffolds and did not migrate through the scaffolds to the bottom of the cell culture plate. The cells showed increased growth, not only on the outer surface (e.g., 500: 36 ± 33 vital cells/mm² after three days, 180 ± 33 cells/mm² after seven days, and 308 ± 69 cells/mm² after 10 days), but also on the inner surface of the samples (e.g., 750: 49 ± 17 vital cells/mm² after three days, 200 ± 84 cells/mm² after seven days, and 218 ± 99 living cells/mm² after 10 days). This means that the inverse 3D printing method is very suitable for the presetting of the pore structure and for the ingrowth of the cells. The experiments on which this work is based have shown that the fused deposition modeling process with subsequent slip casting and sintering is well suited for the production of scaffolds for bone replacement.
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spelling pubmed-68292192019-11-18 Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement Seidenstuecker, Michael Lange, Svenja Esslinger, Steffen Latorre, Sergio H. Krastev, Rumen Gadow, Rainer Mayr, Hermann O. Bernstein, Anke Materials (Basel) Article The aim of this study was to predefine the pore structure of β-tricalcium phosphate (β-TCP) scaffolds with different macro pore sizes (500, 750, and 1000 µm), to characterize β-TCP scaffolds, and to investigate the growth behavior of cells within these scaffolds. The lead structures for directional bone growth (sacrificial structures) were produced from polylactide (PLA) using the fused deposition modeling techniques. The molds were then filled with β-TCP slurry and sintered at 1250 °C, whereby the lead structures (voids) were burnt out. The scaffolds were mechanically characterized (native and after incubation in simulated body fluid (SBF) for 28 d). In addition, biocompatibility was investigated by live/dead, cell proliferation and lactate dehydrogenase assays. The scaffolds with a strand spacing of 500 µm showed the highest compressive strength, both untreated (3.4 ± 0.2 MPa) and treated with simulated body fluid (2.8 ± 0.2 MPa). The simulated body fluid reduced the stability of the samples to 82% (500), 62% (750) and 56% (1000). The strand spacing and the powder properties of the samples were decisive factors for stability. The fact that β-TCP is a biocompatible material is confirmed by the experiments. No lactate dehydrogenase activity of the cells was measured, which means that no cytotoxicity of the material could be detected. In addition, the proliferation rate of all three sizes increased steadily over the test days until saturation. The cells were largely adhered to or within the scaffolds and did not migrate through the scaffolds to the bottom of the cell culture plate. The cells showed increased growth, not only on the outer surface (e.g., 500: 36 ± 33 vital cells/mm² after three days, 180 ± 33 cells/mm² after seven days, and 308 ± 69 cells/mm² after 10 days), but also on the inner surface of the samples (e.g., 750: 49 ± 17 vital cells/mm² after three days, 200 ± 84 cells/mm² after seven days, and 218 ± 99 living cells/mm² after 10 days). This means that the inverse 3D printing method is very suitable for the presetting of the pore structure and for the ingrowth of the cells. The experiments on which this work is based have shown that the fused deposition modeling process with subsequent slip casting and sintering is well suited for the production of scaffolds for bone replacement. MDPI 2019-10-18 /pmc/articles/PMC6829219/ /pubmed/31635363 http://dx.doi.org/10.3390/ma12203417 Text en © 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Seidenstuecker, Michael
Lange, Svenja
Esslinger, Steffen
Latorre, Sergio H.
Krastev, Rumen
Gadow, Rainer
Mayr, Hermann O.
Bernstein, Anke
Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement
title Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement
title_full Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement
title_fullStr Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement
title_full_unstemmed Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement
title_short Inversely 3D-Printed β-TCP Scaffolds for Bone Replacement
title_sort inversely 3d-printed β-tcp scaffolds for bone replacement
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6829219/
https://www.ncbi.nlm.nih.gov/pubmed/31635363
http://dx.doi.org/10.3390/ma12203417
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