TY  - JOUR
A1  - Hahn, Lukas
A1  - Beudert, Matthias
A1  - Gutmann, Marcus
A1  - Keßler, Larissa
A1  - Stahlhut, Philipp
A1  - Fischer, Lena
A1  - Karakaya, Emine
A1  - Lorson, Thomas
A1  - Thievessen, Ingo
A1  - Detsch, Rainer
A1  - Lühmann, Tessa
A1  - Luxenhofer, Robert
T1  - From Thermogelling Hydrogels toward Functional Bioinks: Controlled Modification and Cytocompatible Crosslinking
JF  - Macromolecular Bioscience
N2  - Hydrogels are key components in bioink formulations to ensure printability and stability in biofabrication. In this study, a well-known Diels-Alder two-step post-polymerization modification approach is introduced into thermogelling diblock copolymers, comprising poly(2-methyl-2-oxazoline) and thermoresponsive poly(2-n-propyl-2-oxazine). The diblock copolymers are partially hydrolyzed and subsequently modified by acid/amine coupling with furan and maleimide moieties. While the thermogelling and shear-thinning properties allow excellent printability, trigger-less cell-friendly Diels-Alder click-chemistry yields long-term shape-fidelity. The introduced platform enables easy incorporation of cell-binding moieties (RGD-peptide) for cellular interaction. The hydrogel is functionalized with RGD-peptides using thiol-maleimide chemistry and cell proliferation as well as morphology of fibroblasts seeded on top of the hydrogels confirm the cell adhesion facilitated by the peptides. Finally, bioink formulations are tested for biocompatibility by incorporating fibroblasts homogenously inside the polymer solution pre-printing. After the printing and crosslinking process good cytocompatibility is confirmed. The established bioink system combines a two-step approach by physical precursor gelation followed by an additional chemical stabilization, offering a broad versatility for further biomechanical adaptation or bioresponsive peptide modification.
KW  - chemical crosslinking
KW  - biofabrication
KW  - bioprinting
KW  - hydrogels
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-257542
VL  - 21
IS  - 10
ER  - 
TY  - THES
A1  - Nahm, Daniel
T1  - Poly(2-oxazine) Based Biomaterial Inks for the Additive Manufacturing of Microperiodic Hydrogel Scaffolds
T1  - Poly(2-oxazine) Basierte Biomaterialtinten für die Additive Fertigung von Mikroperiodischen Hydrogelstrukturen
N2  - The aim of this thesis was the preparation of a biomaterial ink for the fabrication of chemically crosslinked hydrogel scaffolds with low micron sized features using melt electrowriting (MEW). By developing a functional polymeric material based on 2-alkyl-2-oxazine (Ozi) and 2-alkyl-2-oxazoline (Ox) homo- and copolymers in combination with Diels-Alder (DA)-based dynamic covalent chemistry, it was possible to achieve this goal. This marks an important step for the additive manufacturing technique melt electrowriting (MEW), as soft and hydrophilic structures become available for the first time. The use of dynamic covalent chemistry is a very elegant and efficient method for consolidating covalent crosslinking with melt processing. It was shown that the high chemical versatility of the Ox and Ozi chemistry offers great potential to control the processing parameters. The established platform offers straight forward potential for modification with biological cues and fluorescent markers. This is essential for advanced biological applications. The physical properties of the material are readily controlled and the potential for 4D-printing was highlighted as well. The developed hydrogel architectures are excellent candidates for 3D cell culture applications. In particular, the low internal strength of some of the scaffolds in combination with the tendency of such constructs to collapse into thin strings could be interesting for the cultivation of muscle or nerve cells. In this context it was also possible to show that MEW printed hydrogel scaffolds can withstand the aspiration and ejection through a cannula. This allows the application as scaffolds for the minimally invasive delivery of implants or functional tissue equivalent structures to various locations in the human body.
N2  - Das Ziel dieses Projekts war die Herstellung einer Biomaterialtinte, welche die Herstellung chemisch vernetzter, mikrostrukturierter Hydrogelgerüste mittels Melt Electrowriting (MEW) ermöglicht. Die Verwendung von speziell auf den schmelzbasierten 3D Druck angepassten polyoxazinbasierten Polymeren und die Anwendung von dynamisch kovalenter Chemie ermöglichte es, dieses Ziel zu erreichen. Dies ist ein wichtiger Schritt für die aufstrebende, additive Fertigungstechnologie MEW, da nun erstmals weiche und hydrophile Strukturen erzeugt werden können. Speziell die Verwendung der dynamischen Diels-Alder (DA) Chemie ist ein effizienter Weg, die Fertigung von kovalent vernetzten Strukturen mit der Schmelzprozessierung zu vereinen. Es wurde weiterhin gezeigt, dass die hier etablierte Materialplattform die Möglichkeit zur Modifikation mit biologischen und chemischen Signalen bietet. Dies ist besonders für biologische Anwendungen unerlässlich. Die physikalisch-chemischen Eigenschaften des Materials lassen sich leicht auf potentielle Anwendungen anpassen und das Potential für den 4D Druck wurde ebenfalls hervorgehoben. Alles in Allem legt diese Arbeit den Grundstein für eine Vielzahl von verschiedenen Anwendungen sowohl in der Biomedizin als auch in anderen Bereichen.
KW  - Polymere
KW  - Ringöffnungspolymerisation
KW  - Biomaterial
KW  - 3D-Druck
KW  - biofabrication
KW  - poly(2-oxazoline)s
KW  - poly(2-oxazine)s
KW  - ring-opening polymerization
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-245987
ER  - 
TY  - JOUR
A1  - Ryma, Matthias
A1  - Tylek, Tina
A1  - Liebscher, Julia
A1  - Blum, Carina
A1  - Fernandez, Robin
A1  - Böhm, Christoph
A1  - Kastenmüller, Wolfgang
A1  - Gasteiger, Georg
A1  - Groll, Jürgen
T1  - Translation of collagen ultrastructure to biomaterial fabrication for material-independent but highly efficient topographic immunomodulation
JF  - Advanced materials
N2  - Supplement-free induction of cellular differentiation and polarization solely through the topography of materials is an auspicious strategy but has so far significantly lagged behind the efficiency and intensity of media-supplementation-based protocols. Consistent with the idea that 3D structural motifs in the extracellular matrix possess immunomodulatory capacity as part of the natural healing process, it is found in this study that human-monocyte-derived macrophages show a strong M2a-like prohealing polarization when cultured on type I rat-tail collagen fibers but not on collagen I films. Therefore, it is hypothesized that highly aligned nanofibrils also of synthetic polymers, if packed into larger bundles in 3D topographical biomimetic similarity to native collagen I, would induce a localized macrophage polarization. For the automated fabrication of such bundles in a 3D printing manner, the strategy of “melt electrofibrillation” is pioneered by the integration of flow-directed polymer phase separation into melt electrowriting and subsequent selective dissolution of the matrix polymer postprocessing. This process yields nanofiber bundles with a remarkable structural similarity to native collagen I fibers, particularly for medical-grade poly(ε-caprolactone). These biomimetic fibrillar structures indeed induce a pronounced elongation of human-monocyte-derived macrophages and unprecedentedly trigger their M2-like polarization similar in efficacy as interleukin-4 treatment.
KW  - biofabrication
KW  - extracellular matrix
KW  - immunomodulation
KW  - macrophages
KW  - melt electrofibrillation
KW  - melt electrowriting
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-256381
VL  - 33
IS  - 33
ER  -