Charis Czichy scite author profile

3D plotting is an additive manufacturing technology enabling biofabrication, thus the integration of cells or biologically sensitive proteins or growth factors into the manufacturing process. However, most (bio-)inks developed for 3D plotting were not shown to be processed into clinically relevant geometries comprising critical overhangs and cavities, which would collapse without a sufficient support material. Herein, we have developed a support hydrogel ink based on methylcellulose (mc), which is able to act as support as long as the co-plotted main structure is not stable. Therefore, 6 w/v %, 8 w/v % and 10 w/v % mc were allowed to swell in water, resulting in viscous inks, which were characterized for their rheological and extrusion properties. The successful usage of 10 w/v % mc as support ink was proven by multichannel plotting of the support together with a plottable calcium phosphate cement (CPC) acting as main structure. CPC scaffolds displaying critical overhangs or a large central cavity could be plotted accurately with the newly developed mc support ink. The dissolution properties of mc allowed complete removal of the gel without residuals, once CPC setting was finished. Finally, we fabricated a scaphoid bone model by computed tomography data acquisition and co-extrusion of CPC and the mc support hydrogel.

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Bioprinting of Magnetically Deformable Scaffolds

Spangenberg

Kilian

Czichy

et al. 2021

ACS Biomater. Sci. Eng.

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Mechanical stimulation of cells embedded in scaffolds is known to increase the cellular performance toward osteogenic or chondrogenic differentiation and tissue development. Three-dimensional bioplotting of magnetically deformable scaffolds enables the spatially defined distribution of magnetically inducible scaffold regions. In this study, a magnetic bioink based on alginate (alg, 3%) and methylcellulose (MC, 9%) with incorporated magnetite microparticles (25% w/w) was developed and characterized. The size and shape of particles were monitored via scanning electron microscopy and X-ray micro-computed tomography. Shear-thinning properties of the algMC ink were maintained after the addition of different concentrations of magnetite microparticles to the ink. Its viscosity proportionally increased with the added amount of magnetite, and so did the level of saturation magnetization as determined via vibrating sample magnetometry. The printability and shape fidelity of various shapes were evaluated, so that the final composition of algMC + 25% w/w magnetite was chosen. With application of this ink, cytocompatibility was proven in indirect cell culture and bioplotting experiments using a human mesenchymal stem cell line. Toward the deformation of cell-laden scaffolds to support cell differentiation in the future, radiography allowed the real-time monitoring of magnetically induced deformation of scaffolds of different pore architectures and scaffold orientations inside the magnetic field. Varying the strand distance and scaffold design will allow fine-tuning the degree of deformation in stimulatory experiments.

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Determination of the Young's modulus for alginate-based hydrogel with magnetite-particles depending on storage conditions and particle concentration

Czichy

Spangenberg

Günther

et al. 2020

Journal of Magnetism and Magnetic Materials

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A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

Ahlfeld¹,

Köhler²,

Czichy³

et al. 2018

Preprint

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CyMAD bioreactor: A cyclic magnetic actuation device for magnetically mediated mechanical stimulation of 3D bioprinted hydrogel scaffolds

Czichy

Kilian²,

Wang³

et al. 2022

Journal of the Mechanical Behavior of Biomedical Materials

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Sensor Integrated CFRP Structures for Intelligent Fixtures

Möhring

Wiederkehr

Lerez

et al. 2016

Procedia Technology

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3D extrusion printing of density gradients by variation of sinusoidal printing paths for tissue engineering and beyond

et al. 2023

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Erstellung eines fachspezifischen Aufgabenpools anhand von zwei Beispielen des Studienerfolgsprojektes OSA 3.0

Czichy

Abdel-Haq

Odenbach

2022

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Die Gruppe der Studieninteressierten ist bzgl. Wissenstand und Interessenslage sehr heterogen, so dass es eine Herausforderung darstellt, z. B. den Vorlesungsstoff entsprechend des Vorwissens aufzubereiten, Praktika spannend zu gestalten oder eine adäquate Prüfungsvorbereitung anzubieten. Ebenso sind Ideen gefragt, um das eigene Wahlmodul vorzustellen oder für die Vertiefung an sich zu werben. Eine Lösung stellt ein fachspezifischer Aufgabenpool dar. Wie die Wissensstände in Erfahrung gebracht und Interesse geweckt werden kann, wird anhand des Studienerfolgsprojektes OSA 3.0 erläutert, wobei OSA für Online-Self-Assessment steht. Die einzelnen Prozessschritte werden im Detail beschrieben und die Entwicklung von zwei Aufgaben wird exemplarisch für diese Schritte gezeigt.

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Charis Czichy

A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

Bioprinting of Magnetically Deformable Scaffolds

Determination of the Young's modulus for alginate-based hydrogel with magnetite-particles depending on storage conditions and particle concentration

A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

CyMAD bioreactor: A cyclic magnetic actuation device for magnetically mediated mechanical stimulation of 3D bioprinted hydrogel scaffolds

Sensor Integrated CFRP Structures for Intelligent Fixtures

3D extrusion printing of density gradients by variation of sinusoidal printing paths for tissue engineering and beyond

Erstellung eines fachspezifischen Aufgabenpools anhand von zwei Beispielen des Studienerfolgsprojektes OSA 3.0

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