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Der erste Teil dieser Arbeit beschäftigte sich mit dem Ziel, amphiphile Oligoethylenglykol-funktionalisierte Perylenmonoimiddiester und Dicarbonsäure- bzw. Amino-funktionalisierte Perylenbisimide zu synthetisieren. Weiterhin wurden die optischen Eigenschaften in Lösung und das Aggregationsverhalten der Ester-, Dicarbonsäure- und der Amino-funktionalisierten Perylenfarbstoffe untersucht. (...)
Der zweite Teil dieser Arbeit widmete sich dem Ziel, die amphiphilen Oligoethylenglykol-funktionalisierten Zinkchlorine, 31-Hydroxy-Zinkchlorin (ZnChl-OH) und 31-Methoxy-Zinkchlorin (ZnChl-OCH3), herzustellen und desweiteren deren Aggregationsverhalten in wässriger Lösung vergleichend zu studieren, um den Einfluss der Lösungsmittel und des Substituenten in 31-Position auf die thermodynamischen und kinetischen Eigenschaften und auf die Aggregatstruktur zu bestimmen. (...)
Nach der Präparation von gewaschenen Thrombozyten, einem wichtigen Ausgangsmaterial für die experimentelle Forschung oder für die Transfusionsmedizin, tritt bekannterweise ein zunehmender Verlust der ADP-vermittelten Aggregationsfähigkeit ein. Die verminderte Funktionsfähigkeit von Thromboyzten nach dem Waschvorgang kann somit auch experimentelle Ergebnisse beeinflussten.
Allerdings sind die dafür verantwortlichen molekularen Mechanismen bisher nicht aufgeklärt, sodass in dieser Dissertationsarbeit molekulare sowie auch funktionelle Vorgänge untersucht wurden, die zum bekannten Phänomen des raschen Verlustes der ADP-vermittelten Aggregationsfähigkeit gewaschener Thrombozyten führen.
Die Wirkung von ADP wird über die drei purinergen Rezeptoren P2Y1, P2X1 und P2Y12 vermittelt wird. Daher wurde zunächst die ADP-induzierte Aggregationsfähigkeit alleine bzw. unter Kostimulation mit Epinephrin oder Serotonin - zwei Induktoren, deren Rezeptoren mit analogen Signalwegen wie die ADP-Rezeptoren P2Y1 bzw. P2Y12 gekoppelt sind - bestimmt. Um Hinweise zu erhalten, wie die Abnahme der ADP-vermittelten Reaktivität von gewaschenen Thrombozyten mit der purinergen Rezeptorexpression und -distribution sowie mit der nachgeschalteten Signalweiterleitung im Zusammenhang steht, wurde zudem die Expression purinerger Rezeptoren auf der Thrombozytenoberfläche bzw. die Konzentration von purinergen Rezeptoren im Zytosol gewaschener Thrombozyten mittels Durchflusszytometrie bzw. ELISA gemessen.
Es zeigte sich, dass die Funktion der den purinergen Rezeptoren nachgeschalteten Signalwege während der Lagerungszeit zunehmend beeinträchtigt wird, aber zumindest teilweise erhalten bleibt, wie anhand von Effekten durch Kostimulation mit den Induktoren Epinephrin und Serotonin gezeigt werden konnte. Die Distribution der Rezeptoren zwischen der Thrombozytenoberfläche und den intrazellulären Kompartimenten unterliegt komplexen Prozessen, die induktorabhängig reguliert sind. Eine initiale Zunahme der Expression von ADP-Rezeptoren während der Lagerung von gewaschenen Thrombozyten geht dabei nicht einher mit der Aufrechterhaltung der ADP-induzierten Aggregation.
In der Schlussfolgerung ist die fortschreitende Degeneration der ADP-vermittelten Aggregation - neben einem Rückgang der Rezeptorexpression nach mehr als einer Stunde Lagerungszeit - vor allem auf einen funktionellen Verlust der purinergen Rezeptoren zurückzuführen.
In conclusion, the present thesis demonstrates that the highly desired J-type aggregation of functional perylene bisimide chromophores can be achieved by proper design of monomeric building blocks that direct self-assemble by mutual effects of hydrogen bonding and pi-pi interaction, and on the other hand, are prevented to assemble in columnar stacks owing to their twisted pi-conjugated core and sterically demanding substituents. Furthermore, the self-assembly studies gave new insights into the dynamic aggregation process of low-dimensional extended assemblies with strongly excitonically coupled chromophores. The relationship between commonly known cyanine dye aggregates like that of THIATS and that of the present PBI 1a was investigated by absorption and fluorescence spectroscopy at low temperatures down to 5 K. The formerly unprecedented functional properties of PBI aggregates that are expressed in J-type excitonic coupling hold promise for application in optoelectronic and photovoltaic devices.
The present thesis demonstrates how different thermodynamic aspects of self-assembly and stimuli-responsive properties in water can be encoded on the structure of π-amphiphiles, consisting of perylene or naphthalene bisimide cores. Initially, quantitative thermodynamic insights into the entropically-driven self-assembly was studied for a series of naphthalene bisimides with UV/Vis and ITC measurements, which demonstrated that their thermodynamic profile of aggregation is heavily influenced by the OEG side chains. Subsequently, a control over the bifurcated thermal response of entropically driven and commonly observed enthalpically driven self-assembly was achieved by the modulation of glycol chain orientation. Finally, Lower Critical Solution Temperature (LCST) phenomenon observed for these dyes was investigated as a precise control of this behavior is quintessential for self-assembly studies as well as to generate ‘smart’ materials. It could be shown that the onset of phase separation for these molecules can be encoded in their imide substituents, and they are primarily determined by the supramolecular packing, rather than the hydrophobicity of individual monomers.
The main objective of this thesis was the design and synthesis of perylene bisimide dyes with sufficient water-solubility for the construction of self-assembled architectures in aqueous solutions. Beside these tasks another goal of this project was the control over the self-assembly process in terms of aggregate size and helicity, respectively. Within this thesis an appropriate synthesis for spermine-functionalized perylene bisimide dyes was developed and conducted successfully. The characterization of these building blocks and their course of self-assembly were investigated by NMR, UV/Vis and fluorescence spectroscopy as well as by atomic force and transmission electron microscopy. For the better understanding of the experimental results theoretical calculations were performed.
Within this thesis the interactions between novel corannulene derivatives in solution as well as in the solid state by changing the imide residue of a literature known extended corannulene dicarboximide were investigated, in order to obtain a better understanding of the packing and possible charge transport in potential applications. Accordingly, the goal of the work was to synthesize and investigate an electron-poor corannulene bis(dicarboximide) based on previously published work but with higher solubility and less steric encumbrance in imide position to enable self-assembly in solution.
To obtain further insights into the conformational stability, structure and chiroptical properties of heavily twisted PBIs another aim of this thesis was the design, synthesis, and optoelectronic investigation of various fourfold directly arylated PBIs by substitution in bay position with smaller hydrocarbons with different steric demand, i.e., benzene, naphthalene and pyrene, which should be separable by chiral high performance liquid chromatography (HPLC).
As of yet, no concise study concerning the optical and electronic properties of differently core-substituted PBIs in the neutral as well as the mono- and dianionic state in solution is available, which also elucidates the origin of the different optical transitions observed in the absorption and emission spectra. Thus, in this thesis, the investigation of five PBI derivatives with different frontier energetic levels to produce a reference work of reduced PBIs was tackled.
The presented work in the field of supramolecular chemistry describes the synthesis and detailed investigation of (bi)pyridine-based oligo(phenylene ethynylene) (OPE) amphiphiles, decorated with terminal glycol chains. The metal-ligating property of these molecules could be exploited to coordinate to Pd(II) and Pt(II) metal ions, respectively, resulting in the creation of novel metallosupramolecular π-amphiphiles of square-planar geometry.
The focus of the presented studies is on the self-assembly behaviour of the OPE ligands and their corresponding metal complexes in polar and aqueous environment. In this way, the underlying aggregation mechanism (isodesmic or cooperative) is revealed and the influence of various factors on the self-assembly process in supramolecular systems is elucidated. In this regard, the effect of the molecular design of the ligand, the coordination to a metal centre as well as the surrounding medium, the pH value and temperature is investigated.
This thesis included the synthesis of conformationally stable chiral perylene bisimide (PBI) dyes, the study of their optical properties in solution and their chiral self-sorting behaviour in nonpolar solvents in which dimerization via pi-pi-stacking takes place. Furthermore, the influence of PBI core chirality on the properties of these dyes in the condensed state has been also studied. We have demonstrated and quantified the prevalence of chiral self-recognition over self-discrimination in pi-stacking dimerization of PBIs. It has been shown that this self-recognition event is compromised by the increasing flexibility of the structures related to the size of the OEG bridging units. Moreover, the inherent chirality of these PBIs has been proven to strongly influence their condensed state properties, for which large differences between the pure enantiomers and the racemates were revealed, as well as between the different bridged macrocyclic PBIs.
The culture of human induced pluripotent stem cells (hiPSCs) at large-scale becomes feasible with the aid of scalable suspension setups in continuously stirred tank reactors (CSTRs). Suspension cul- tures of hiPSCs are characterized by the self-aggregation of single cells into macroscopic cell aggre- gates that increase in size over time. The development of these free-floating aggregates is dependent on the culture vessel and thus represents a novel process parameter that is of particular interest for hiPSC suspension culture scaling. Further, aggregates surpassing a critical size are prone to spon- taneous differentiation or cell viability loss. In this regard, and, for the first time, a hiPSC-specific suspension culture unit was developed that utilizes in situ microscope imaging to monitor and to characterize hiPSC aggregation in one specific CSTR setup to a statistically significant degree while omitting the need for error-prone and time-intensive sampling. For this purpose, a small-scale CSTR system was designed and fabricated by fused deposition modeling (FDM) using an in-house 3D- printer. To provide a suitable cell culture environment for the CSTR system and in situ microscope, a custom-built incubator was constructed to accommodate all culture vessels and process control devices. Prior to manufacture, the CSTR design was characterized in silico for standard engineering parameters such as the specific power input, mixing time, and shear stress using computational fluid dynamics (CFD) simulations. The established computational model was successfully validated by comparing CFD-derived mixing time data to manual measurements. Proof for system functionality was provided in the context of long-term expansion (4 passages) of hiPSCs. Thereby, hiPSC aggregate size development was successfully tracked by in situ imaging of CSTR suspensions and subsequent automated image processing. Further, the suitability of the developed hiPSC culture unit was proven by demonstrating the preservation of CSTR-cultured hiPSC pluripotency on RNA level by qRT-PCR and PluriTest, and on protein level by flow cytometry.
Im Rahmen dieser Dissertation wurden optische Eigenschaften von halbleitenden, einwandigen Kohlenstoffnanoröhren (SWNTs) der (6,5)-Chiralität untersucht. Dies gelang durch Ensemblemessungen aber vor allem durch den Aufbau eines Mikroskops zur Messung an einzelnen SWNTs. Dieses Einzel- SWNT-Mikroskop ermöglichte nebst „normaler“ Bildgebung durch Sammlung und Abbildung der nahinfraroten Photolumineszenz (PL) der (6,5)-SWNTs auch die spektral- und zeitaufgelöste Untersuchung der PL. Durch Verwendung von Dichtegradientenultrazentrifugation (DGU) zur chiralen Aufreinigung des SWNT-Rohmaterials konnten alle Messungen unter Minimierung des störenden Einflusses von Aggregaten oder SWNTs anderer Chiralität durchgeführt werden. Untersucht und bestimmt wurde der Absorptionsquerschnitt und die Exzitonengröße, die PL-Eigenschaften aggregierter SWNTs und der Einfluß der Permittivität auf die PL einzelner SWNTs.