Stefan Glorius scite author profile

The major advantage of hydroxyapatite (HA)-forming calcium phosphate cements (CPCs) used as bone replacement materials is their setting under physiological conditions without the necessity for thermal treatment that allows the incorporation of biological factors. In the present study, we have combined the biocompatible consolidation of CPCs with the potential of rapid prototyping (RP) techniques to generate calcium phosphate-based scaffolds with defined inner and outer morphology. We demonstrate the application of the RP technique three-dimensional (3D) plotting for the fabrication of HA cement scaffolds. This was realized by utilizing a paste-like CPC (P-CPC) which is stable as a malleable paste and whose setting reaction is initiated only after contact with aqueous solutions. The P-CPC showed good processability in the 3D plotting process and allowed the fabrication of stable 3D structures of different geometries with adequate mechanical stability and compressive strength. The cytocompatibility of the plotted P-CPC scaffolds was demonstrated in a cell culture experiment with human mesenchymal stem cells. The mild conditions during 3D plotting and post-processing and the realization of the whole procedure under sterile conditions make this approach highly attractive for fabrication of individualized implants with respect to patient-specific requirements by simultaneous plotting of biological components.

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Dissecting the Impact of Matrix Anchorage and Elasticity in Cell Adhesion

Pompe

Glorius

Bischoff

et al. 2009

Biophysical Journal

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Extracellular matrices determine cellular fate decisions through the regulation of intracellular force and stress. Previous studies suggest that matrix stiffness and ligand anchorage cause distinct signaling effects. We show herein how defined noncovalent anchorage of adhesion ligands to elastic substrates allows for dissection of intracellular adhesion signaling pathways related to matrix stiffness and receptor forces. Quantitative analysis of the mechanical balance in cell adhesion using traction force microscopy revealed distinct scalings of the strain energy imparted by the cells on the substrates dependent either on matrix stiffness or on receptor force. Those scalings suggested the applicability of a linear elastic theoretical framework for the description of cell adhesion in a certain parameter range, which is cell-type-dependent. Besides the deconvolution of biophysical adhesion signaling, site-specific phosphorylation of focal adhesion kinase, dependent either on matrix stiffness or on receptor force, also demonstrated the dissection of biochemical signaling events in our approach. Moreover, the net contractile moment of the adherent cells and their strain energy exerted on the elastic substrate was found to be a robust measure of cell adhesion with a unifying power-law scaling exponent of 1.5 independent of matrix stiffness.

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Friction-Controlled Traction Force in Cell Adhesion

Pompe

Kaufmann

Kasimir

et al. 2011

Biophysical Journal

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The force balance between the extracellular microenvironment and the intracellular cytoskeleton controls the cell fate. We report a new (to our knowledge) mechanism of receptor force control in cell adhesion originating from friction between cell adhesion ligands and the supporting substrate. Adherent human endothelial cells have been studied experimentally on polymer substrates noncovalently coated with fluorescent-labeled fibronectin (FN). The cellular traction force correlated with the mobility of FN during cell-driven FN fibrillogenesis. The experimental findings have been explained within a mechanistic two-dimensional model of the load transfer at focal adhesion sites. Myosin motor activity in conjunction with sliding of FN ligands noncovalently coupled to the surface of the polymer substrates is shown to result in a controlled traction force of adherent cells. We conclude that the friction of adhesion ligands on the supporting substrate is important for mechanotransduction and cell development of adherent cells in vitro and in vivo.

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The effect of perfusion culture on proliferation and differentiation of human mesenchymal stem cells on biocorrodible bone replacement material

Jaña

Wolf‐Brandstetter

Glorius³

et al. 2011

Materials Science and Engineering: B

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Metal Foam – Bone Cement Composites: Mechanical and Biological Properties and Perspectives for Bone Implant Design

Glorius¹,

Nies²,

Jaña³

et al. 2011

Adv Eng Mater

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Several approaches for the development of highly porous metal structures with intended medical application have been published in recent years. Considering both the demands of sufficient mechanical strength for loaded bone implants as well as prevention of the stress shielding phenomena, open‐cell metal foams are reinforced with strong but resorbable mineral bone cement. Titanium‐ and iron‐based composites with highly prolonged stress resilence and favorable cytoxicity are achieved. Resorption of mineral phase gradually decreases the implant stability while concurrently raising the bone regeneration through mechanical stimulation. Furthermore, iron‐based composites are intended to be resorbed and corrode consecutively. Thus, a temporary bone implant can be obtained.

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Stefan Glorius

Fabrication of porous scaffolds by three-dimensional plotting of a pasty calcium phosphate bone cement under mild conditions

Dissecting the Impact of Matrix Anchorage and Elasticity in Cell Adhesion

Friction-Controlled Traction Force in Cell Adhesion

The effect of perfusion culture on proliferation and differentiation of human mesenchymal stem cells on biocorrodible bone replacement material

Metal Foam – Bone Cement Composites: Mechanical and Biological Properties and Perspectives for Bone Implant Design

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