Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study

Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study

The aim of this study was to characterize the influence of functionalization of synthetic poly-(L-lactic acid) (PLLA) nanofibers on mechanical properties such as maximum load, elongation, and Young's modulus. Furthermore, the impact of osteoblast growth on the various nanofiber scaffolds stabil...

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Main Authors: Jürgen Paletta, Karla Erffmeier, Christina Theisen, Daniel Hussain, Joachim H. Wendorff, Andreas Greiner, Susanne Fuchs-Winkelmann, Markus D. Schofer
Format: Article
Language:English
Published: Hindawi Limited 2009-01-01
Series:The Scientific World Journal
Online Access:http://dx.doi.org/10.1100/tsw.2009.149
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spelling doaj-995fab48b88f42a1b6acba78e55e2c532020-11-25T00:59:32ZengHindawi LimitedThe Scientific World Journal1537-744X2009-01-0191382139310.1100/tsw.2009.149Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro StudyJürgen Paletta0Karla Erffmeier1Christina Theisen2Daniel Hussain3Joachim H. Wendorff4Andreas Greiner5Susanne Fuchs-Winkelmann6Markus D. Schofer7Department of Orthopedics, University Hospital of Marburg, Marburg, GermanyDepartment of Orthopedics, University Hospital of Marburg, Marburg, GermanyDepartment of Orthopedics, University Hospital of Marburg, Marburg, GermanyDepartment of Chemistry, University Hospital of Marburg, Marburg, GermanyDepartment of Chemistry, University Hospital of Marburg, Marburg, GermanyDepartment of Chemistry, University Hospital of Marburg, Marburg, GermanyDepartment of Orthopedics, University Hospital of Marburg, Marburg, GermanyDepartment of Orthopedics, University Hospital of Marburg, Marburg, GermanyThe aim of this study was to characterize the influence of functionalization of synthetic poly-(L-lactic acid) (PLLA) nanofibers on mechanical properties such as maximum load, elongation, and Young's modulus. Furthermore, the impact of osteoblast growth on the various nanofiber scaffolds stability was determined. Nanofiber matrices composed of PLLA, PLLA-collagen, or BMP-2–incorporated PLLA were produced from different solvents by electrospinning. Standardized test samples of each nanofiber scaffold were subjected to failure protocol before or after incubation in the presence of osteoblasts over a period of 22 days under osteoinductive conditions. PLLA nanofibers electrospun from hexafluoroisopropanol (HFIP) showed a higher strain and tended to have increased maximum loads and Young's modulus compared to PLLA fibers spun from dichloromethane. In addition, they had a higher resistance during incubation in the presence of cells. Functionalization by incorporation of growth factors increased Young's modulus, independent of the solvent used. However, the incorporation of growth factors using the HFIP system resulted in a loss of strain. Similar results were observed when PLLA was blended with different ratios of collagen. Summarizing the results, this study indicates that different functionalization strategies influence the mechanical stability of PLLA nanofibers. Therefore, an optimization of nanofibers should not only account for the optimization of biological effects on cells, but also has to consider the stability of the scaffold.http://dx.doi.org/10.1100/tsw.2009.149
collection DOAJ
language English
format Article
sources DOAJ
author Jürgen Paletta
Karla Erffmeier
Christina Theisen
Daniel Hussain
Joachim H. Wendorff
Andreas Greiner
Susanne Fuchs-Winkelmann
Markus D. Schofer
spellingShingle Jürgen Paletta
Karla Erffmeier
Christina Theisen
Daniel Hussain
Joachim H. Wendorff
Andreas Greiner
Susanne Fuchs-Winkelmann
Markus D. Schofer
Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study
The Scientific World Journal
author_facet Jürgen Paletta
Karla Erffmeier
Christina Theisen
Daniel Hussain
Joachim H. Wendorff
Andreas Greiner
Susanne Fuchs-Winkelmann
Markus D. Schofer
author_sort Jürgen Paletta
title Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study
title_short Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study
title_full Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study
title_fullStr Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study
title_full_unstemmed Influence of Poly-(L-Lactic Acid) Nanofiber Functionalization on Maximum Load, Young's Modulus, and Strain of Nanofiber Scaffolds Before and After Cultivation of Osteoblasts: An In Vitro Study
title_sort influence of poly-(l-lactic acid) nanofiber functionalization on maximum load, young's modulus, and strain of nanofiber scaffolds before and after cultivation of osteoblasts: an in vitro study
publisher Hindawi Limited
series The Scientific World Journal
issn 1537-744X
publishDate 2009-01-01
description The aim of this study was to characterize the influence of functionalization of synthetic poly-(L-lactic acid) (PLLA) nanofibers on mechanical properties such as maximum load, elongation, and Young's modulus. Furthermore, the impact of osteoblast growth on the various nanofiber scaffolds stability was determined. Nanofiber matrices composed of PLLA, PLLA-collagen, or BMP-2–incorporated PLLA were produced from different solvents by electrospinning. Standardized test samples of each nanofiber scaffold were subjected to failure protocol before or after incubation in the presence of osteoblasts over a period of 22 days under osteoinductive conditions. PLLA nanofibers electrospun from hexafluoroisopropanol (HFIP) showed a higher strain and tended to have increased maximum loads and Young's modulus compared to PLLA fibers spun from dichloromethane. In addition, they had a higher resistance during incubation in the presence of cells. Functionalization by incorporation of growth factors increased Young's modulus, independent of the solvent used. However, the incorporation of growth factors using the HFIP system resulted in a loss of strain. Similar results were observed when PLLA was blended with different ratios of collagen. Summarizing the results, this study indicates that different functionalization strategies influence the mechanical stability of PLLA nanofibers. Therefore, an optimization of nanofibers should not only account for the optimization of biological effects on cells, but also has to consider the stability of the scaffold.
url http://dx.doi.org/10.1100/tsw.2009.149
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