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Institute
- Fakultät für Chemie und Pharmazie (44) (remove)
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- SKZ – Das Kunststoff-Zentrum (1)
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EU-Project number / Contract (GA) number
- 646737 (1)
In this work, a toolbox was provided to create three-component polymer conjugates with a defined architecture, designed to bear different biocomponents that can interact with larger biological systems in biomacromolecular recognition experiments. The target architecture is the attachment of two biomolecule ‘arms’ to the alpha telechelic end point of a polymer and fixating the conjugate to the gold surface of SAW and SPR sensor chips with the polymer’s other omega chain end. This specific design of a conjugate will be implemented by using a strategy to yield novel double alpha as well as omega telechelic functionalized POx and the success of all cascade reaction steps leading to the final conjugation product will be proven through affinity measurements between covalently bound mannose and ConA. All reactions were performed on a low molecular model level first and then transferred to telechelic and also side chain functionalized polymer systems.
No abstract available.
Der Vernetzungsgrad von Klebstoffen und strahlenvernetzter Kunststoffformteile beeinflusst zahlreiche Materialeigenschaften und ist von essenzieller Bedeutung für die Funktionalität von Klebeverbindungen und die Beständigkeit medizinischer Implantate.
Die zerstörungsfreie Prüfung dieser Qualitätsgröße ist von großem industriellem Interesse, aber noch nicht Stand der Technik. Die unilaterale Kernspinresonanz (uNMR) ist ein vielversprechendes Verfahren zur Lösung dieser Problematik.
In diesem Buch wird die nicht-invasive Vernetzungsgradprüfung von strahlenvernetztem UHMWPE und verschiedenen Klebstoffen mittels uNMR demonstriert. Auf Basis der guten Korrelation mit praxisrelevanten Referenzmethoden (thermisch, rheologisch, dielektrisch) wurden Vergleichsmodelle entwickelt, welche Anwendern von Klebstoffen und vernetzten Kunststoffformteilen den Einsatz der uNMR zur zerstörungsfreien Qualitätssicherung ermöglichen.
The development of controlled biodegradable materials is of fundamental importance in immunodrug delivery to spatiotemporally controlled immune stimulation but avoid systemic inflammatory side effects. Based on this, polycarbonate nanogels are developed as degradable micellar carriers for transient immunoactivation of lymph nodes. An imidazoquinoline‐type TLR7/8 agonist is covalently conjugated via reactive ester chemistry to these nanocarriers. The nanogels not only provide access to complete disintegration by the hydrolysable polymer backbone, but also demonstrate a gradual disintegration within several days at physiological conditions (PBS, pH 6.4–7.4, 37 °C). These intrinsic properties limit the lifetime of the carriers but their payload can still be successfully leveraged for immunological studies in vitro on primary immune cells as well as in vivo. For the latter, a spatiotemporal control of immune cell activation in the draining lymph node is found after subcutaneous injection. Overall, these features render polycarbonate nanogels a promising delivery system for transient activation of the immune system in lymph nodes and may consequently become very attractive for further development toward vaccination or cancer immunotherapy. Due to the intrinsic biodegradability combined with the high chemical control during the manufacturing process, these polycarbonate‐based nanogels may also be of great importance for clinical translation.
The aim of this thesis was the development of a multifunctional coating system for AuNPs based on thioether polymers, providing both excellent colloidal stability and a variable possibility to introduce functionalities for biological applications.
First, two thioether-polymer systems were synthesised as a systematic investigation into colloidal stabilisation efficacy. Besides commonly used monovalent poly(ethylene glycol) (PEG-SR), its structural analogue linear poly(glycidol) (PG-SR) bearing multiple statistically distributed thioether moieties along the backbone was synthesised. Additionally, respective thiol analogues (PEG-SH and PG-SH) were produced and applied as reference.
Successive modification of varyingly large AuNPs with aforementioned thiol- and thioether-polymers was performed via ligand exchange reaction on citrate stabilised AuNPs. An increased stabilisation efficacy of both thioether-polymers against biological and physiological conditions, as well as against freeze-drying compared to thiol analogues was determined.
Based on the excellent colloidal stabilisation efficacy and multi-functionalisability of thioether-PG, a plethora of functional groups, such as charged groups, hydrophilic/hydrophobic chains, as well as bio-active moieties namely diazirine and biotin was introduced to the AuNP surface. Moreover, the generic and covalent binding of diazirine-modified PG-SR with biomolecules including peptides and proteins was thoroughly demonstrated.
Lastly, diverse applicability and bioactivity of aforementioned modified particles in various studies was displayed, once more verifying the introduction of functionalities. On the one hand the electrostatic interaction of charged AuNPs with hydrogels based on hyaluronic acid was applied to tune the release kinetics of particles from three-dimensional scaffolds. On the other hand the strong complexation of siRNA onto two positively charged AuNPs was proven. The amount of siRNA payload was tuneable by varying the surface charge, ionic strength of the surrounding medium and the N/P ratio. Moreover, the biological activity and selectivity of the biotin-streptavidin conjugation was verified with respectively functionalised particles in controlled agglomeration test and in laser-triggered cell elimination experiments. In the latter, streptavidin-functionalised AuNPs resulted in excellent depletion of biotinylated cells whereas unfunctionalised control particles failed, excluding unspecific binding of these particles to the cell surface.
The focus of this thesis was to investigate how PCL and PLGA react to the heat exposure that comes with the MEW process over a defined timespan.
To assess the thermal stability of PCL during MEW over 25 d, an automated collection of fibers has been used to determine the CTS on each day of heating for three different temperatures. PCL is exceptionally stable over 25 d at 75 °C, whereas for 85 °C and 95 °C a slight upward trend during the last 10 d could be observed, which is an indication for thermal degradation. Same trend could be observed for diameter of fibers produced at a fixed collector speed. For all temperatures, CTS during the first 5 d decreased due to inhomogeneities of the melt. Physical analysis of the fibers by XRD and mechanical testing showed no significant changes.
To investigate the chemical details of the thermal durability, PCL was artificially aged over 25 d at 75 °C, 85 °C and 95 °C. Data from GPC analysis and rheology revealed that PCL is degrading steadily at all three temperatures. Combined with GC-MS analysis, two different mechanisms for degradation could be observed: random chain scission and unzipping. Additional GPC experiment using a mixture of PCL and a fluorescence labelled PCL showed that PCL was undergoing ester interchange reactions, which could explain its thermal stability.
PLGA was established successfully as material for MEW. GPC results revealed that PLGA degraded heavily in the one-hour preheating period. To reduce the processing temperature, ATEC was blended with PLGA in three mixtures. This slowed down degradation and a processing window of 6 h could be established. Mechanical testing with fibers produced with PLGA and all three blends was performed. PLGA was very brittle, whereas the blends showed an elastic behavior. This could be explained by ester interchange reactions that formed a loosely crosslinked network with ATEC.
Aluminium-copper alloys of the 2xxx type receive their excellent mechanical properties by the formation of copper-rich precipitates during hardening. Size, distribution and crystal structure of the formed precipitates determine the final strength of those alloys. Adding traces of certain elements, which bind to vacancies, significantly influences the decomposition behaviour, i.e. the diffusion of the copper atoms. For high-purity ternary alloys (Al-1.7 at.% Cu-X), we investigate the interaction of copper and trace element atoms (X=In, Sn, and Pb) with quenched-in vacancies by Positron Annihilation Lifetime Spectroscopy (PALS). By employing Vickers microhardness, Differential Scanning Calorimetry (DSC) and Small Angle X-Ray Scattering (SAXS) we obtain a comprehensive picture of the decomposition process: opposite to predicted binding energies to vacancies by ab-initio calculations we find during ageing at room and elevated temperature a more retarded clustering of copper in the presence of In rather than for Sn additions, while Pb, having the highest predicted binding to vacancies, shows nearly no retarding effect compared to pure Al-Cu. If the latter would be due to a limited solubility of lead, it had to be below 2 ppm. Transmission Electron Microscopy (TEM) as imaging method complements our findings. Annealing the quenched Al-1.7 at.% Cu-X-alloys containing 100 ppm In or Sn at 150∘C leads to finely distributed θ′-precipitates on the nanoscale, since due to the trace additions the formation temperature of θ′ is lowered by more than 100∘C. According to TEM small agglomerates of trace elements (In, Sn) may support the early nucleation for the θ′-precipitates.
In the field of biofabrication, biopolymer-based hydrogels are often used as bulk materials with defined structures or as bioinks. Despite their excellent biocompatibility, biopolymers need chemical modification to fulfill mechanical stability.
In this thesis, the primary alcohol of hyaluronic acid was oxidized using TEMPO/TCC oxidation to generate aldehyde groups without ring-opening mechanism of glycol cleavage using sodium periodate. For crosslinking reaction of the aldehyde groups, adipic acid dihydrazide was used as bivalent crosslinker for Schiff Base chemistry. This hydrogel system with fast and reversible crosslinking mechanism was used successfully as bulk hydrogel for chondrogenic differentiation with human mesenchymal stem cells (hMSC).
Gelatin was modified with pentenoic acid for crosslinking reaction via light controllable thiol-ene reaction, using thiolated 4-arm sPEG as multivalent crosslinker. Due to preservation of the thermo responsive property of gelatin by avoiding chain degradation during modification reaction, this gelatin-based hydrogel system was successfully processed via 3D printing with low polymer concentration. Good cell viability was achieved using hMSC in various concentrations after 3D bioprinting and chondrogenic differentiation showed promising results.
In this work the synthesis, the spectroscopic and electrochemical investigation as well as some applications of a broad diversity of indolenine squaraine dyes were presented. This diversity was based on two parent squaraine dyes, one standard trans-configured compound (M1) and one in which one central oxygen atom was replaced by a dicyanomethylene moiety (M2), which increased the acceptor strength and induced a cis-configuration. The variety of synthesised dyes included functionalised squaraine monomers, donor- and acceptor-substituted monomeric model squaraines, donor- and acceptor-squaraine copolymers, pure squaraine homopolymers, a squaraine-squaraine copolymer, as well as some conjugated cyclic oligomers.
In order to be able to synthesise all these different kinds of dyes, several bromine and boronic ester derivatives were synthesised, which enabled the use of the Suzuki cross coupling reaction, to generate model dyes and copolymers. In addition, the bromine derivatives were used to carry out the Yamamoto homocoupling reaction to the respective homopolymers and macrocycles.
The absorption maximum of unsubstituted reference dye M1 was found at ~ 15500 cm–1, while that of M2 was red-shifted to ~ 14300 cm–1 due to the increased acceptor strength of the central unit. The extinction coefficients were in the order of ~ 300000 M–1 cm–1 and ~ 200000 M–1 cm–1, respectively. It was found that the implementation of functional groups (M3–M9), additional electron donors (M10–M19) or acceptors (M20–M22) at the periphery lead to bathochromic shifts of the absorption depending on the strength of either - and/or -donating properties of the substituents.
For the bis- and triarylamine substituted dyes M10–M13 and the dibrominated dyes M5 and M7 the electronic structure of the mono- and diradical (di)cations was explored using the interplay of cyclic voltammetry, spectroelectrochemistry, and DFT calculations. It was demonstrated that the monoradical cations still show a cyanine-like character and are delocalised Robin-Day class III species due to the low redox potential of the squaraine bridge between the additional amine redox centres. To the best of my knowledge, this made M13+∙, with an N-N-distance of 26 bonds between the additional redox centres to the longest bis(triarylamine) radical cation that is completely delocalised. For the diradical dications, the situation was of larger complexity. The computed most stable energetic state of the dianisylamine-substituted dyes turned out to be a broken-symmetry state with almost equal contributions of an open-shell singlet and triplet state. In addition, it was shown that the HOMO–1→HOMO transition dominated the absorption spectra of the diradical dications where the trans-/cis-configuration of the squaraines had a direct impact due to symmetry reasons.
Based on the donor–squaraine model compounds M10–M19, a series of donor–squaraine copolymers was synthesised (P7–P12) in order to further red shift and broaden the low energy absorption band. However, these effects were only of marginal extent. Both the optical and the electrochemical derived band gaps were barely lowered compared to the respective monomeric model dyes. This was assigned to an increased squaraine-squaraine distance and resulting lower exciton coupling between the squaraine chromophores due to the bridging units. In addition, according to semiempirical calculations the bridges were twisted out of the squaraine plane what reduced conjugational effects between the chromophores. To sum up, the idea to insert additional electron rich bridging units in order to create copolymers with broad and red-shifted absorption did not fully work out for the presented systems.
The addition of strong electron accepting NDI units at the periphery resulted in M21, the most unique monomeric model squaraine in this work. The common picture of a sharp low energy squaraine absorption completely altered due to the addition of the NDIs and a rather broad and solvent dependent low energy absorption was found. Spectroelectrochemical experiments and semiempirical calculations showed that this band is a superposition of the common squaraine HOMO→LUMO transition and a partial squaraine→NDI charge transfer transition. The latter was lost upon oxidation of the squaraine and the absorption spectrum of the monocation of M21 was found to be nearly a 1:1 image of a pure squaraine monocation. Both the monomeric model M21 and the respective copolymer P13 showed low electrochemically obtained band gaps of 1.05–1.20 eV, which were the lowest of all squaraines in this work. For both dyes, transient absorption measurements in the fs-time regime revealed the ultrafast formation of a CS state via an intermediate CT state within a few ps. Besides, charge recombination to the ground state also occured within a few ps. In the polymer, there was barely any further energy or charge transfer within the excited state lifetime and therefore the CS state was confined on adjacent squaraine-NDI pairs and did not further travel along the polymer strand.
The Ni-mediated Yamamoto homocoupling reaction was applied for the synthesis of the homopolymers (P1–P5). In contrast to the donor–squaraine copolymers, those polymers revealed strongly red-shifted and broad absorption in the red to NIR region in addition to a sharp fluorescence. These features could be explained to originate mainly from the exciton coupling of localised excited states and the presence of different superstructures in solution. For the polymers P1 and P2, an elongated J-type polymer chain caused the strong lowest energy absorption band whereas a zig-zag type arrangement of the single chromophores lead to transitions into both low and high energy excited states of the excitonic manifold. For the polymers P3 and P4, several polymer fractions of different size were investigated. Here, also an elongated chain with J-type character induced the lowest energy absorption band whereas a helical H-type arrangement caused transitions to higher energies of the excitonic manifold. The fractions to which these structures were formed depended on the chain length and the solvent. In thin film measurements, it was shown that the initially in solution formed superstructures were partly retained in the thin film but could be altered by annealing procedures. A control of the superstructures should enable the controlled tuning of the optical properties. Despite the strong interaction of the chromophores in the excited state, the redox potentials of the homopolymers barely differed to those of the respective reference dyes, indicating negligible electronic interaction in the ground state.
In addition squaraine-squaraine copolymer P6, consisting of alternating parent dyes M1 and M2, was synthesised. Likewise to the homopolymers, a broad and red-shifted absorption was observed. This was explained by exciton coupling theory, which was extended to also suit alternating copolymers. In toluene, an extraordinary narrow and intense lowest energy absorption band was observed. This exchange narrowing might be a result of a highly ordered J-type structure of the polymer especially in this solvent because it was not found in others. The features of the polymer may be compared to typical J-aggregates formed from monomeric cyanine molecules for example and the polymer used as model for excitonic interactions in an alternating copolymer. Transient absorption measurements revealed a strong energy dependence of the decay traces of the copolymer, most strikingly at early decay times. This was assigned to the occurrence of multiple excitations of one polymer strand (due to the large extinction coefficients of the polymer) and resulting exciton-exciton annihilation. Due to the large exciton diffusion constants that were estimated, the static exciton-exciton annihilation was the rate limiting process of the decay, in contrast to other conjugated polymers, where in thin film measurements the decay was diffusion controlled.
To sum up, for the polymers consisting of exclusively squaraine chromophores, it was shown that the exciton coupling of single chromophores with strong transition dipole moments was a fruitful way to tune the absorption spectra.
As a side product of some of the polycondensation reactions, unprecedented cyclic conjugated oligomers such as the triarylamine-bridged dimer Dim1, the cyclic homotrimers Tri1–Tri3, and the tetramer Tet1 were obtained by recycling GPC in low yields. Especially the cyclic trimers showed unusual absorption and even more extraordinary fluorescence properties. They showed multiple fluorescence bands in the NIR that covered a range from ~ 8000–12500 cm–1 (800–1250 nm). First hints from theoretical calculations indicated that the trimer was not fully planar but comprised a mixture of both planar and bent single squaraine chromophores. However, final results of the calculations were still missing at the time of writing.
In the last part of this work, the application of some monomeric and polymeric squaraines in binary and ternary bulk heterojunction solar cells was demonstrated. Also the utilisation as a dopant in a polymer matrix in an OLED device was shown. The homopolymers P1–P4 were tested in the binary BHJ solar cells revealing poor performances and especially very low short circuit currents. The utilisation of the polymers P3 and P4 that carried the dicyanomethylene group resulted in higher open circuit voltages due to the lower LUMO energy levels but still an overall poor performance. Neither for the different alkyl chains nor for the size of the polymers was a trend observed. In the ternary BHJ solar cells, small amounts of either monomer M14 or polymers P1A, P4–1 or P13 were added to a P3HT/PCBM system in order to generate an additional pathway for charge or energy transfer that should result in a better device performance. However, for none of the tested squaraines, improved solar cells could be built. In similarity to the binary solar cells, the short circuit currents were lower compared to a P3HT/PCBM reference device. These low short circuit currents indicated that the morphology of the squaraine dyes was the major limitation in those devices. It is possible that the dimethyl groups at the indolenine hindered a favoured alignment of the compounds that would allow decent charge transport. In the squaraine doped OLED the squaraine M6 worked rather well as an NIR emitter. Already at low dye loads the fluorescence of the host polymer SY-PPV was completely quenchend and emission from the squaraine was observed. For electroluminescence measurements, a lower dye load (0.5 wt.%) compared to the photoluminescence measurements was sufficient, indicating that apart from FRET additional quenching mechanisms were at work in the electrically driven devices such as charge carrier dynamics.
Die vorliegende Arbeit stellt einen Beitrag zur Chemie des höherkoordinierten Siliciums dar. Im Vordergrund standen die Synthese und Charakterisierung neuer neutraler penta- und hexakoordinierter Silicium(IV)-Komplexe sowie die Synthese, Charakterisierung und Untersuchung der Reaktivität eines neuartigen Donor-stabilisierten Silylens.
Im Rahmen dieser Arbeit konnten erstmals die Eigenschaften von 1-heteroaromatisch-substituierten, freien Borolen des Typs R′BC4Ph4 untersucht werden. Der Rest R′ wurde unter Verwendung von bekannten Synthesemethoden (Zinn-Bor-Austausch, Salzeliminierung) variiert und die Borolderivate 45 (R′ = Thien-2-yl), 46 (R′ = 5-Methylfuran-2-yl), 47 (R′ = 5-Trimethylsilylthien-2-yl) und 49 (R′ = N-Methylpyrrol-3-yl) erfolgreich synthetisiert und vollständig charakterisiert (Multikern-NMR-Spektroskopie, Elementaranalyse, Röntgenstrukturanalyse am Einkristall).
Des Weiteren ist es gelungen, die ersten Bis(borole) mit den heteroaromatischen Brückeneinheiten 2,5-Thienyl (54) und 5,5′-Bithiophen (55) mittels Zinn-Bor-Austausch-Reaktion darzustellen. Die Molekülstruktur von 54 bestätigt dabei nicht nur die erfolgreiche Synthese, sondern auch die coplanare Ausrichtung der drei Ringsysteme zueinander. Anhand von cyclovoltammetrischen Messungen konnte gezeigt werden, dass in diesem -konjugierten Akzeptor-Donor-Akzeptor-System (54) eine ausgeprägte Kommunikation zwischen den beiden Borzentren vorliegt. Dadurch ergeben sich vier irreversible Reduktionsereignisse, die ausgehend von 54, dem Monoanion [54]•−, dem Dianion [54]2−, dem Trianion [54]3− und dem Tetraanion [54]4− zugewiesen werden können.
Das Verhalten von 54 gegenüber Reduktion wurde außerdem nicht nur elektrochemisch, sondern auch mithilfe unterschiedlicher Reduktionsmittel analysiert. Die Reduktion mit einem halben Äquivalent des Zwei-Elektronen-Reduktionsmittels Magnesiumanthracen führte dabei zu dem vollständig delokalisierten Monoanion Mg0.5[54], welches ESR-spektroskopisch charakterisiert werden konnte. Die Reduktion mit einem Äquivalent Magnesiumanthracen bzw. zwei Äquivalenten des Ein-Elektronen-Reduktionsmittels CoCp*2 lieferte das Dianion [54]2−, das für den Fall von [CoCp*2]2[54] im Festkörper studiert werden konnte. Die Molekülstruktur belegt, dass es sich bei Dianion [54]2− nicht um ein diradikalisches, sondern ein diamagnetisches, chinoides System handelt, welches auch als Bipolaron beschrieben werden kann.
Der Einfluss von heteroaromatischen Substituenten wurde außerdem im Hinblick auf die Synthese neuartiger Basen-stabilisierter Diborene untersucht. Durch reduktive Kupplung geeigneter NHC-stabilisierter Dihalogenborane 77 und 78 (NHC = IMe) konnten die beiden Thienyl-substituierten Diborene 81 und 82 in sehr guten Ausbeuten (81: 82%; 82: 89%) dargestellt werden. UV-Vis-spektroskopische Untersuchungen und quantenchemische Rechnungen belegen, dass das HOMO der Diborene durch die -Bindung der BB-Bindung repräsentiert wird.
Im Gegensatz zu den bekannten Aryl-substituierten Diborenen (73, 74) zeigt die Festkörperstruktur von 82 eine coplanare Ausrichtung der Heterocyclen relativ zur BB-Bindungsebene. Dadurch wird die sterische Abschirmung der reaktiven BB-Doppelbindung vermindert und weitere Reaktivitätsuntersuchungen in Analogie zur Reaktivität von CC-Doppelbindungen können durchgeführt werden.
Die vorliegende Arbeit beschreibt die Synthese von linearen und verzweigten funktionalisierten siliciumhaltigen Synthesebausteinen unter Verwendung der 2,4,6-Trimethoxyphenyl-Schutzgruppe sowie die Synthese cyclischer siliciumhaltiger Synthese-bausteine unter Verwendung eines Donor-stabilisierten Silylens. Diese Forschungsarbeit leistet daher sowohl einen Beitrag zur Schutzgruppenchemie des Siliciums als auch zur Chemie des nieder- bzw. höhervalenten Siliciums. Alle Zielverbindungen sowie die entsprechenden isolierten Vorstufen wurden durch NMR-Spektroskopie in Lösung (1H-, 13C- und 29Si-NMR) und Elementaranalysen (C, H, N; außer 15 und 16) charakterisiert. Die Verbindungen 34, 36, 41, 42, 45, 48, 52, 54 und 55 wurden zusätzlich durch NMR-Spektroskopie im Festkörper (13C-, 15N- und 29Si-VACP/MAS-NMR) untersucht, und die Verbindungen 1–6, 9, 18, 25, 29, 34, 36, 41, 42, 45, 48, 52, 54 und 55 wurden außerdem durch Einkristall-Röntgenstrukturanalyse charakterisiert.
Die vorliegende Arbeit befasst sich mit der Synthese, Charakterisierung und Untersuchung von Foldameren und ihren Untereinheiten im Rahmen des FOLDAPPI-Projekts (Foldamers against Protein-Protein Interaction). Des Weiteren wurden neuartig substituierte Chinoline dargestellt, um sie im Rahmen des SFB 630 auf ihre Hemmwirkung gegen Leishmanien und Trypanosomen zu untersuchen.
Im ersten Projekt wurde ein neuartiges Monomer entwickelt, welches die Wasserlöslichkeit der Foldamere verbessern sollte. Zu diesem Zweck wurde eine zusätzliche, hoch polare Seitenkette in den Chinolingrundkörper eingeführt. Dieses modifizierte Monomer konnte erfolgreich synthetisiert werden. Um die Verbesserung der Wasserlöslichkeit gegenüber dem zuvor verwendeten Monomer zu testen, wurde erfolgreich ein Tetramer daraus aufgebaut. Das entschützte Tetramer konnte jedoch aufgrund seiner hohen Polarität nicht ausreichend gereinigt werden, um die abschließenden Löslichkeitsuntersuchungen durchzuführen. Um dieses Problem zu umgehen, wurde von der Umsetzung in Lösung auf Reaktionen an der Festphase gewechselt, was die Reinigung der Produkte wesentlich erleichtern sollte. Dabei wurde eine vom Arbeitskreis von I. Huc neu entwickelte mikrowellengestützte Methode verwendet. Das Referenzmolekül mit den bisher verwendeten Seitenketten konnte so ohne Probleme synthetisiert und seine Löslichkeit in Wasser bestimmt werden. Beim neu entwickelten Monomer kam es allerdings beim Aufbau des Tetrameres zu einer Zersetzungsreaktion, weshalb das abschließende Ziel nicht erreicht werden konnte.
Im zweiten Projekt wurden zwei Ziele angestrebt: Zunächst sollte ein Weg gefunden werden, die Einführung der Seitenketten an den Chinolinen erst an der festen Phase vorzunehmen, wodurch viele Syntheseschritte bei der Vorbereitung der Monomere gespart werden könnten. Zusätzlich sollte eine neue Kupplungsreaktion entwickelt werden, wodurch der Entschützungsschritt des zu kuppelnden Amins an der Festphase eingespart werden kann. Dadurch würde vor allem bei großen Foldameren das Harz geschont und die Gefahr einer Degenerierung wesentlich verringert. Für die Kupplungsreaktion vorgesehen war ein azidfunktionalisiertes Monomer, das mittels Staudinger-Reaktion verknüpft werden sollte. Das entsprechende Monomer konnte erfolgreich synthetisiert werden. Auch das erste Ziel, die Einführung der Seitenkette an der Festphase, konnte erfolgreich durchgeführt werden. Leider war die Verwirklichung beider Ziele über die gleiche Syntheseroute nicht ohne weiteres möglich. Da das Monomer ohne die Seitenkette deutlich hydrophiler wurde, wäre eine Trocknungsmethode bei erhöhter Temperatur von Vorteil gewesen, um gebundenes Wasser vollständig zu entfernen. Da das Monomer allerdings auch eine Azidfunktion trägt und sich bei 130 °C explosionsartig zersetzt, war dies nicht möglich. Allerdings genügen bereits geringe Spuren von Feuchtigkeit, um die Staudinger-Reaktion zu beeinträchtigten. Deshalb konnte das zweite Projektziel nicht verwirklicht werden.
Im dritten Projekt wurde die Herstellung einer großen Foldamer-Bibliothek für die Untersuchung der Bindungsaffinität gegenüber IL-4 angestrebt. Sie sollte aus 48 Hexameren bestehen, wobei an drei Monomeren die Seitenketten variiert werden sollten, um ein breites Spektum an verschiedenen Kombinationen von Wechselwirkungen abzudecken. Dazu wurden zunächst vier verschiedene Monomere synthetisiert, welche eine aromatisch, eine unpolare, eine anionische bzw. eine kationische Seitenkette enthielten. Für die Kupplung der Foldamere wurde eine an die Synthese von Aminosäuresequenzen angelehnte Methode entwickelt und erfolgreich angewandt. So konnten alle 48 Foldamere erfolgreich synthetisiert und 46 von ihnen in ausreichenden Mengen für die Untersuchung an IL-4 gereinigt werden. Leider liegen für diese Bibliothek bisher keine abschließenden Ergebnisse über die Inhibitionseigenschaften gegenüber IL-4 vor. Strukturell sehr ähnliche Foldamere zeigten jedoch in ersten Experimenten eine Inhibition von IL-4 was eine Wirksamkeit der neu erstellten Bibliothek vermuten lässt.
Das vierte Projekt wurde im Rahmen des SFB 630 durchgeführt. Hierzu wurden einige der ursprünglich für andere Projekte hergestellten Foldamere ausgewählt, teilweise entschützt bzw. an der Nitrogruppe reduziert und anschließend auf Ihre Aktivität gegen Leishmanien und Trypanosomen getestet. Es zeigte sich, dass das verwendete Substitutionsmuster, in den gestesteten Konzentrationen nicht gegen Leishmanien und Trypanosomen wirksam ist. Es eignet sich also nicht für die Erstellung einer neuen Leitstruktur gegen diese beiden Erreger. Allerdings trat im untersuchten Konzentrationsbereich auch keine Zytotoxizität auf, was eine interessante Information für die Verwendung der Foldamere und ihrer Bausteine in biologischen Systemen darstellt.
Silbernanodrähte (AgNW) wurden in verschiedene Hybridpolymere und in eine als Referenz dienende Silikonzusammensetzung eingebaut. Durch Spincoating konnten transparente leitfähige Filme erhalten werden. Deren jeweilige Nanodrahtverteilung, thermische Aktivierung und visuelle Transparenz wurden charakterisiert. Die Perkolationsschwelle der Filme hängt dabei von der individuellen durchschnittlichen AgNW-Länge ab. Eine beträchtliche Leitfähigkeit wurde während des mechanischen Streckens bis zu 30 % aufrechterhalten. Mikrostrukturierte Hybridpolymer-Verbundfilme wurden durch UV-Lithographie erhalten. ...
Aim of this thesis was to combine the versatility of sulfur-chemistry, regarding redox-sensitivity as well as chemo- and site-specific conjugation, with multifunctionality of poly(glycidol)s as an alternative to poly(ethylene glycol).
First the homo- and copolymerizations of EEGE and AGE were performed with respect to molar-mass distribution and reaction kinetics. A detailed study was given, varying the polymerization parameters such as DP, counter ion, solvent and monomer influence. It can be concluded that in general the rates for all polymerizations are higher using K+, in contrast to Cs+, as counter ion for the active alkoxide species. Unfortunately, K+ as counter ion commonly leads to a reduced control over polymer dispersity. In this thesis it was shown that the broad molar-mass distributions might be reduced by adding the monomer in a step-wise manner. In experiments with a syringe pump, for continuously adding the monomer, a significant reduction of the dispersities could be found using K+ as counter ion.
In analogy to the oxyanionic polymerization of epoxides, the polymerization of episulfides via a thioanionic mechanism with various DPs was successful with thiols/DBU as initiator. In most experiments bimodality could be observed due to the dimerization, caused by oxidation processes by introduced oxygen during synthesis. Reducing this was successful by modifying the degassing procedure, e.g. repeated degassing cycles after each step, i.e. initiation, monomer addition and quenching. Unfortunately, it was not always possible to completely avoid the dimerization due to oxidation. Thiophenol, butanethiol, mercaptoethanol and dithiothreitol were used as thiol initiators, all being capable to initiate the polymerization. With the prediction and the narrow molar-mass distributions, the living character of the polymerization is therefore indicated.
Homo- and copolymers of poly(glycidol) were used to functionalize these polymers with side-chains bearing amines, thiols, carboxylic acids and cysteines. The cysteine side-chains were obtained using a newly synthesized thiol-functional thiazolidine. For this, cysteine was protected using a condensation reaction with acetone yielding a dimethyl-substituted thiazolidine. Protection of the ring-amine was obtained via a mixed-anhydride route using formic acid and acetic anhydride. The carboxylic acid of 2,2-dimethylthiazolidine-4-carboxylic acid was activated with CDI and cysteamine attached. The obtained crystalline mercaptothiazolidine was subjected to thiol-ene click chemistry with allyl-functional poly(glycidol). A systematic comparison of thermal- versus photo-initiation showed a much higher yield and reaction rate for the UV-light mediated thiol-ene synthesis with DMPA as photo-initiator. Hydrolysis of the protected thiazolidine-functionalities was obtained upon heating the samples for 5 d at 70 °C in 0.1 M HCl. Dialysis against acetic acid lead to cysteine-functional poly(glycidol)s, storable as the acetate salt even under non-inert atmosphere. An oxidative TNBSA assay was developed to quantify the cysteine-content without the influence of the thiol-functionality. A cooperation partner coupled C-terminal thioester peptides with the cysteine-functional poly(glycidol)s and showed the good accessibility and reactivity of the cysteines along the backbone. SDS-PAGE, HPLC and MALDI-ToF measurements confirmed the successful coupling.
The WHO-designated neglected-disease pathogen Chlamydia trachomatis (CT) is a gram-negative bacterium responsible for the most frequently diagnosed sexually transmitted infection worldwide. CT infections can lead to infertility, blindness and reactive arthritis, among others. CT acts as an infectious agent by its ability to evade the immune response of its host, which includes the impairment of the NF-κB mediated inflammatory response and the Mcl1 pro-apoptotic pathway through its deubiquitylating, deneddylating and transacetylating enzyme ChlaDUB1 (Cdu1). Expression of Cdu1 is also connected to host cell Golgi apparatus fragmentation, a key process in CT infections.
Cdu1 may this be an attractive drug target for the treatment of CT infections. However, a lead molecule for the development of novel potent inhibitors has been unknown so far. Sequence alignments and phylogenetic searches allocate Cdu1 in the CE clan of cysteine proteases. The adenovirus protease (adenain) also belongs to this clan and shares a high degree of structural similarity with Cdu1. Taking advantage of topological similarities between the active sites of Cdu1 and adenain, a target-hopping approach on a focused set of adenain inhibitors, developed at Novartis, has been pursued. The thereby identified cyano-pyrimidines represent the first active-site directed covalent reversible inhibitors for Cdu1. High-resolution crystal structures of Cdu1 in complex with the covalently bound cyano-pyrimidines as well as with its substrate ubiquitin have been elucidated. The structural data of this thesis, combined with enzymatic assays and covalent docking studies, provide valuable insights into Cdu1s activity, substrate recognition, active site pocket flexibility and potential hotspots for ligand interaction. Structure-informed drug design permitted the optimization of this cyano-pyrimidine based scaffold towards HJR108, the first molecule of its kind specifically designed to disrupt the function of Cdu1. The structures of potentially more potent and selective Cdu1 inhibitors are herein proposed.
This thesis provides important insights towards our understanding of the structural basis of ubiquitin recognition by Cdu1, and the basis to design highly specific Cdu1 covalent inhibitors.
Rekonstitution des Chromophors und der Funktion von Bakteriorhodopsin aus Halobacterium halobium
(1976)
Ein Modell der lichtgetriebenen Protonenpumpe Bakteriorhodopsin postulierte die direkte Beteiligung der Wasserstoffe in der 4-Stellung des Cyclohexenringes des Retinalchromophors an dem Vorgang der Protonenverschiebung. Mittels Blockaden der Retroform-Bildung von Retinal durch chemische Modifizierungen des Cyclohexenringes (4-Hydroxy-Retinal, 5,6-Epoxy-Retinal) konnten nach Einbau der modifizierten Moleküle in die isolierte Purpurmembran und nach Zugabe zu Halobakterien mit unterdrückter Retinalsynthese die direkte Beteiligung des Cyclohexenringes an der Protonenpumpe mit großer Wahrscheinlichkeit ausgeschlossen werden.
Parallel polar dimers in the columnar self‐assembly of umbrella‐shaped subphthalocyanine mesogens
(2021)
The self-assembly of umbrella-shaped mesogens is explored with subphthalocyanine cores and oligo(thienyl) arms with different lengths in the light of their application as light-harvesting and photoconducting materials. While the shortest arm derivatives self-assemble in a conventional columnar phase with a single mesogen as a repeating unit, the more extended derivatives generate dimers that pile up into liquid crystalline columns.
In contrast to the antiparallel arrangement known from single crystals, the present mesogens align as parallel dimers in polar columnar phases as confirmed by X-ray scattering, experimental densities, dielectric spectroscopy, second harmonic generation, alignment, and conductivity studies.
UV–vis and fluorescence spectroscopies reveal a broad absorption in the visible range and only weak emission of the Q-band. Thus, these light-collecting molecules forming strongly polar columnar mesophases are attractive for application in the area of photoconductive materials.
The present work builds on a conjugated electrochromic polymer with a highly transmissive and colorless bright state and its application in electrochromic devices. The main body of this work focuses on the investigation of the influence of moisture on electrochromic devices and solutions to overcome possible degradation of these devices due to moisture ingress.
Firstly, a series of EDOT derivatives with a terminal double bond in the lateral sidechain to potentially achieve a highly transmissive and fully colorless bright state was investigated. All of the EDOT derivatives were electrochemically polymerized and characterized by means of (in-situ) spectroelectrochemistry. The results highlight the dramatic influence of the terminal double bond on the improved visible light transmittance and color neutrality in the bright state. After detailed evaluation and comparison, the best performing compound, which contains a hexenyl sidechain (PEDOT-EthC6), was scaled-up by changing the deposition technique from an electrochemical to a chemical in-situ polymerization process on a R2R-pilot line in an industrially relevant environment. The R2R-processed PEDOTEthC6 half-cells were characterized in detail and provide enhanced electrochromic properties in terms of visible light transmittance and color neutrality in the bright state as well as short response times, improved contrast ratio, coloration efficiency and cycling stability (10 000 cycles).[21]
In a second step, the novel PEDOT-EthC6 electrochromic polymer was combined with a Prussian Blue counter electrode and a solid polymer electrolyte to form an all-solid-sate ECDs based on complementary switching electrodes and PET-ITO as flexible substrates. The fabricated ECDs were optically and spectroelectrochemically characterized. Excellent functionality of the S2S-processed flexible ECDs was maintained throughout 10 000 switching cycles under laboratory conditions. The ECDs offer enhanced electrochromic properties in terms of visible light transmittance change and color neutrality in the bright state as well as contrast ratio, coloration efficiency, cycling stability and fast response times. Furthermore, the final device assembly was transferred from a S2S-process to a continuous R2R-lamination process.[238]
In a third step, the PEDOT-EthC6/PB-based ECDs were submitted to conscious environmental aging tests. The emphasis of the research presented in this work, was mainly put at the influence of moisture and possible failure mechanisms regarding the PEDOT-EthC6/PB based ECDs. An intense brown coloration of the electrodes was observed while cycling the ECDs in humid atmospheres (90% rH) as a major degradation phenomenon. The brown coloration and a thereby accompanied loss of conductivity of the PET-ITO substrates was related to significant degradation of the ITO layers, inserted as the conductive layers in the flexible ECDs. A dissolution of the ITO thin films and formation of metallic indium particles on the surface of the ITO layers was observed that harmed the cycling stability enormously. The conductive layers of the aged ECDs were investigated by XRD, UV-Vis, SEM and spectroelectrochemical measurements and validated the supposed irreversible reduction of the ITO layers.[279]
In the absence of reasonable alternatives to PET-ITO for flexible (R2R-processed) ECDs, it is also important to investigate measures to avoid the degradation of ECDs. This is primarily associated with the avoidance of appropriate electrode potentials necessary for ITO reduction in humid atmospheres. As an intrinsic action point, the electrode potentials were investigated via electrochemical measurements in a three-electrode setup of an all-solid-state ECD. Extensive knowledge on the electrode potentials allowed the voltage-induced degradation of the ITO in flexible ECDs to be avoided through the implementation of an unbalanced electrode configuration (charge density ratio of working and counter electrode). It was possible to narrow the overall operational voltage window to an extent in which irreversible ITO reduction no longer occurs. The unbalanced electrode configuration lead to an improved cycling stability without harming other characteristics such as response time and light transmittance change and allows ECD operation in the presence of humidity.[279]
The avoidance of the mentioned degradation phenomena is further associated with appropriate sealing methods and materials as well as appropriate electrode and device fabrication processes. Since a variety of sealing materials is commercially available, due to the commercial launch of organic photovoltaic (OPV) and light emitting diodes (OLEDs), the focus in the present work was put to water-free electrode fabrication. As an extrinsic action point, a novel preparation method of a nanoscale PEDOT-EthC6 dispersion based on organic solvents is presented here in a final step. The water-free processing method gives access to straightforward printing and coating processes on flexible PET-ITO substrates and thus represents a promising and simplified alternative to the established PEDOT:PSS. The resulting nano-PEDOT-EthC6 thin films exhibit enhanced color neutrality and transmissivity in the bright state and are comparable to the properties of the in-situ polymerized PEDOT-EthC6 thin films.[280]
In this work, the influence of aromatic structures on drug encapsulation, self-assembly and hydrogel formation was investigated. The physically crosslinked gelling systems were characterized and optimized for the use in biofabrication and applied in initial (bio)printing experiments.
Chapter I: The cytocompatible (first in vitro and in vivo studies) amphiphile PMeOx-b-PBzOx-b- PMeOx (A-PBzOx-A) was used for the solubilization of PTX, schizandrin A (SchA), curcumin (CUR), niraparib and HS-173.
Chapter II: Compared to the polymers A-PPheOx-A, A-PBzOx-A and A-PBzOzi-A, only the polymer A-PPheOzi-A showed a reversible temperature- and concentration-dependent inverse thermogelation, which is accompanied by a morphology change from long wormlike micelles in the gel to small spherical micelles in solution. The worm formation results from novel interactions between the hydrophilic and hydrophobic aromatic polymer blocks. Changes in the hydrophilic block significantly alter the gel system. Rheological properties can be optimized by concentration and temperature, which is why the hydrogel was used to significantly improve the printability and stability of Alg in a blend system.
Chapter III: By extending the side chain of the aromatic hydrophobic block, the inverse thermogelling polymer A-poly(2-phenethyl-2-oxazoline)-A (A-PPhenEtOx-A) is obtained. Rapid gelation upon cooling is achieved by inter-correlating spherical micelles. Based on ideal rheological properties, first cytocompatible bioprinting experiments were performed in combination with Alg. The polymers A- poly(2-benzhydryl-2-oxazoline)-A (A-PBhOx-A) and A-poly(2-benzhydryl-2-oxazine) (A-PBhOzi-A) are characterized by two aromatic benzyl units per hydrophobic repeating unit. Only the polymer A- PBhOzi-A exhibited inverse thermogelling behavior. Merging micelles could be observed by electron microscopy. The system was rheologically characterized and discussed with respect to an application in 3D printing.
Chapter IV: The thermogelling POx/POzi system, in particular the block copolymer PMeOx-b- PnPrOzi, was used in different applications in the field of biofabrication. The introduction of maleimide and furan units along the hydrophilic polymer part ensured additional stabilization by Diels-Alder crosslinking after the printing process.