TY - THES A1 - Gentsch, Rafael T1 - Complex bioactive fiber systems by means of electrospinning T1 - Komplexe Bioaktive Fasersysteme mittels Elektrospinnen N2 - Nanofibrous mats are interesting scaffold materials for biomedical applications like tissue engineering due to their interconnectivity and their size dimension which mimics the native cell environment. Electrospinning provides a simple route to access such fiber meshes. This thesis addresses the structural and functional control of electrospun fiber mats. In the first section, it is shown that fiber meshes with bimodal size distribution could be obtained in a single-step process by electrospinning. A standard single syringe set-up was used to spin concentrated poly(ε-caprolactone) (PCL) and poly(lactic-co-glycolic acid) (PLGA) solutions in chloroform and meshes with bimodal-sized fiber distribution could be directly obtained by reducing the spinning rate at elevated humidity. Scanning electron microscopy (SEM) and mercury porosity of the meshes suggested a suitable pore size distribution for effective cell infiltration. The bimodal fiber meshes together with unimodal fiber meshes were evaluated for cellular infiltration. While the micrometer fibers in the mixed meshes generate an open pore structure, the submicrometer fibers support cell adhesion and facilitate cell bridging on the large pores. This was revealed by initial cell penetration studies, showing superior ingrowth of epithelial cells into the bimodal meshes compared to a mesh composed of unimodal 1.5 μm fibers. The bimodal fiber meshes together with electrospun nano- and microfiber meshes were further used for the inorganic/organic hybrid fabrication of PCL with calcium carbonate or calcium phosphate, two biorelevant minerals. Such composite structures are attractive for the potential improvement of properties such as stiffness or bioactivity. It was possible to encapsulate nano and mixed sized plasma-treated PCL meshes to areas > 1 mm2 with calcium carbonate using three different mineralization methods including the use of poly(acrylic acid). The additive seemed to be useful in stabilizing amorphous calcium carbonate to effectively fill the space between the electrospun fibers resulting in composite structures. Micro-, nano- and mixed sized fiber meshes were successfully coated within hours by fiber directed crystallization of calcium phosphate using a ten-times concentrated simulated body fluid. It was shown that nanofibers accelerated the calcium phosphate crystallization, as compared to microfibers. In addition, crystallizations performed at static conditions led to hydroxyapatite formations whereas in dynamic conditions brushite coexisted. In the second section, nanofiber functionalization strategies are investigated. First, a one-step process was introduced where a peptide-polymer-conjugate (PLLA-b-CGGRGDS) was co-spun with PLGA in such a way that the peptide is enriched on the surface. It was shown that by adding methanol to the chloroform/blend solution, a dramatic increase of the peptide concentration at the fiber surface could be achieved as determined by X-ray photoelectron spectroscopy (XPS). Peptide accessibility was demonstrated via a contact angle comparison of pure PLGA and RGD-functionalized fiber meshes. In addition, the electrostatic attraction between a RGD-functionalized fiber and a silica bead at pH ~ 4 confirmed the accessibility of the peptide. The bioactivity of these RGD-functionalized fiber meshes was demonstrated using blends containing 18 wt% bioconjugate. These meshes promoted adhesion behavior of fibroblast compared to pure PLGA meshes. In a second functionalization approach, a modular strategy was investigated. In a single step, reactive fiber meshes were fabricated and then functionalized with bioactive molecules. While the electrospinning of the pure reactive polymer poly(pentafluorophenyl methacrylate) (PPFPMA) was feasible, the inherent brittleness of PPFPMA required to spin a PCL blend. Blends and pure PPFPMA showed a two-step functionalization kinetics. An initial fast reaction of the pentafluorophenyl esters with aminoethanol as a model substance was followed by a slow conversion upon further hydrophilization. This was analysed by UV/Vis-spectroscopy of the pentaflurorophenol release upon nucleophilic substitution with the amines. The conversion was confirmed by increased hydrophilicity of the resulting meshes. The PCL/PPFPMA fiber meshes were then used for functionalization with more complex molecules such as saccharides. Aminofunctionalized D-Mannose or D-Galactose was reacted with the active pentafluorophenyl esters as followed by UV/Vis spectroscopy and XPS. The functionality was shown to be bioactive using macrophage cell culture. The meshes functionalized with D-Mannose specifically stimulated the cytokine production of macrophages when lipopolysaccharides were added. This was in contrast to D-Galactose- or aminoethanol-functionalized and unfunctionalized PCL/PPFPMA fiber mats. N2 - Biofunktionale Materialien gewinnen immer größere Bedeutung in biomedizinischen Anwendungen wie dem künstlichen Ersatz von Knochen oder Blutgefässe. Weiterhin können diese Stoffe nützlich sein, um die Wechselwirkung zwischen Biomaterialien und biologischen Systemen wie Zellen oder Organismen weiter zu erforschen. In diversen Studien konnten Größen wie dreidimensionaler Strukturaufbau, Oberflächentopographie, Mechanik und die Funktionalisierung mit bioaktiven Substanzen als Einflussfaktoren identifiziert werden, welche auf verschiedenen Größenskalen von makroskopisch bis nanoskopisch untersucht wurden und gegenwärtig erforscht werden. Bioinspiriert von Kollagenfasern, die als Strukturmotiv an verschieden Orten im menschlichen Körper vorkommen (z.B. extrazelluläre Matrix) konnte gezeigt werden, dass Fasermatten, die eine ähnliche Größendimensionen wie die vorher erwähnten Kollagenfasern (Ø ~ 500 nm) aufweisen, eine aussichtsreiche Gerüstmatrix darstellen. Eine einfache Methode Fasermatten in diesen Dimensionen herzustellen ist Elektrospinning, wobei typischerweise eine viskose Polymerlösung durch anlegen eines Hochspannungsfeldes verstreckt wird. Obwohl auf diese Weise hergestellte Fasermatten für gewisse Zelllinien eine ideale Zellwechselwirkung aufweisen, ist die Zellbesiedelung solcher Netzwerke, bedingt auch durch die kleinen Porendurchmesser, problematisch und bedarf meistens weiterer Prozessierungsschritte. Diese Arbeit beschäftigt sich mit der einfachen Herstellung von strukturel und funktional kontrollierten Fasersystem mittels Elektrospinning. Der erste Teil behandelt ein Einschrittverfahren zum Elektrospinnen von bimodalen Fasermatten bestehend aus Nano- und Mikrofasern. In Zellstudien mit Epithelzellen konnte gezeigt werden, dass solche Netzwerke tiefer besiedelt werden als Matten bestehend aus unimodalen 1.5 μm dicken Fasern. Des Weiteren wurden diese Fasermatten für fasergerichtete Kristallisation von Kalziumcarbonat und – phosphat benutzt. In einem zweiten Teil wurden 2 Strategien für die Faserfunktionalisierung mit Peptiden und Zuckermolekülen entwickelt. Zum einen wurde gezeigt, dass funktionale Peptidfasern durch Verspinnung einer Mischung von einem Peptid-Polymer-Konjugat mit einem kommerziellen Polymer hergestellt werden konnten. Zusätzlich wurde ein modularer Ansatz für die Herstellung von reaktiven Fasern ausgearbeitet, die anschließend mit Peptiden oder Zuckern funktionalisiert wurden. Die Bioaktivität der Zucker funktionalisierten Fasern konnte durch Zellversuche erfolgreich bestätigt werden. KW - Elektrospinnen KW - Faser KW - bioaktiv KW - funktional KW - Struktur KW - electrospinning KW - fiber KW - bioactive KW - functional KW - structure Y1 - 2010 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-44900 ER - TY - JOUR A1 - Guill, Christian A1 - Hülsemann, Janne A1 - Klauschies, Toni T1 - Self-organised pattern formation increases local diversity in metacommunities JF - Ecology letters N2 - Self-organised formation of spatial patterns is known from a variety of different ecosystems, yet little is known about how these patterns affect the diversity of communities. Here, we use a food chain model in which autotroph diversity is described by a continuous distribution of a trait that affects both growth and defence against heterotrophs. On isolated patches, diversity is always lost over time due to stabilising selection, and the local communities settle on one of two alternative stable community states that are characterised by a dominance of either defended or undefended species. In a metacommunity context, dispersal can destabilise these states and complex spatio-temporal patterns in the species' abundances emerge. The resulting biomass-trait feedback increases local diversity by an order of magnitude compared to scenarios without self-organised pattern formation, thereby maintaining the ability of communities to adapt to potential future changes in biotic or abiotic environmental conditions. KW - biomass-trait feedback KW - fitness gradient KW - food chain KW - functional KW - diversity KW - metacommunity KW - self-organisation KW - source-sink dynamics KW - spatio-temporal pattern KW - trait-based aggregate model KW - Turing instability Y1 - 2021 U6 - https://doi.org/10.1111/ele.13880 SN - 1461-023X SN - 1461-0248 VL - 24 IS - 12 SP - 2624 EP - 2634 PB - Wiley-Blackwell CY - Oxford ER - TY - JOUR A1 - Tarazona Lizcano, Natalia Andrea A1 - Machatschek, Rainhard Gabriel A1 - Balcucho, Jennifer A1 - Castro-Mayorga, Jinneth Lorena A1 - Saldarriaga, Juan Francisco A1 - Lendlein, Andreas T1 - Opportunities and challenges for integrating the development of sustainable polymer materials within an international circular (bio)economy concept JF - MRS energy & sustainability : science & technology & socio-economics & policy N2 - The production and consumption of commodity polymers have been an indispensable part of the development of our modern society. Owing to their adjustable properties and variety of functions, polymer-based materials will continue playing important roles in achieving the Sustainable Development Goals (SDG)s, defined by the United Nations, in key areas such as healthcare, transport, food preservation, construction, electronics, and water management. Considering the serious environmental crisis, generated by increasing consumption of plastics, leading-edge polymers need to incorporate two types of functions: Those that directly arise from the demands of the application (e.g. selective gas and liquid permeation, actuation or charge transport) and those that enable minimization of environmental harm, e.g., through prolongation of the functional lifetime, minimization of material usage, or through predictable disintegration into non-toxic fragments. Here, we give examples of how the incorporation of a thoughtful combination of properties/functions can enhance the sustainability of plastics ranging from material design to waste management. We focus on tools to measure and reduce the negative impacts of plastics on the environment throughout their life cycle, the use of renewable sources for their synthesis, the design of biodegradable and/or recyclable materials, and the use of biotechnological strategies for enzymatic recycling of plastics that fits into a circular bioeconomy. Finally, we discuss future applications for sustainable plastics with the aim to achieve the SDGs through international cooperation.
Leading-edge polymer-based materials for consumer and advanced applications are necessary to achieve sustainable development at a global scale. It is essential to understand how sustainability can be incorporated in these materials via green chemistry, the integration of bio-based building blocks from biorefineries, circular bioeconomy strategies, and combined smart and functional capabilities. KW - biomaterial KW - degradable KW - functional KW - life cycle assessment KW - renewable KW - sustainability Y1 - 2022 U6 - https://doi.org/10.1557/s43581-021-00015-7 SN - 2329-2229 SN - 2329-2237 VL - 9 IS - 1 SP - 28 EP - 34 PB - Springer Nature CY - London ER -