@unpublished{WohlgemuthMiyazakiTsukadaetal.2017, author = {Wohlgemuth, Matthias and Miyazaki, Mitsuhiko and Tsukada, Kohei and Weiler, Martin and Dopfer, Otto and Fujii, Masaaki and Mitrić, Roland}, title = {Deciphering environment effects in peptide bond solvation dynamics by experiment and theory}, series = {Physical Chemistry Chemical Physics}, journal = {Physical Chemistry Chemical Physics}, doi = {10.1039/C7CP03992A}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-159483}, year = {2017}, abstract = {Most proteins work in aqueous solution and the interaction with water strongly affects their structure and function. However, experimentally the motion of a specific single water molecule is difficult to trace by conventional methods, because they average over the heterogeneous solvation structure of bulk water surrounding the protein. Here, we provide a detailed atomistic picture of the water rearrangement dynamics around the -CONH- peptide linkage in the two model systems formanilide and acetanilide, which simply differ by the presence of a methyl group at the peptide linkage. The combination of picosecond pump-probe time-resolved infrared spectroscopy and molecular dynamics simulations demonstrates that the solvation dynamics at the molecular level is strongly influenced by this small structural difference. The effective timescales for solvent migration triggered by ionization are mainly controlled by the efficiency of the kinetic energy redistribution rather than the shape of the potential energy surface. This approach provides a fundamental understanding of protein hydration and may help to design functional molecules in solution with tailored properties.}, language = {en} } @misc{BleasdalegebGoesswein1976, type = {Master Thesis}, author = {Bleasdale [geb. G{\"o}ßwein], Liselotte}, title = {Versuche zum Mechanismus des Protonentransports in der Purpurmembran von Halobacterium Halobium. Tritium- und Deuteriumaustausch am Protein-gebundenen Retinal}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-144987}, school = {Universit{\"a}t W{\"u}rzburg}, year = {1976}, abstract = {No abstract available.}, subject = {Halobacterium halobium}, language = {de} } @phdthesis{Schmitz2016, author = {Schmitz, Tobias}, title = {Functional coatings by physical vapor deposition (PVD) for biomedical applications}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-144825}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {Metals are the most used materials for implant devices, especially in orthopedics, but despite their long history of application issues such as material failure through wear and corrosion remain unsolved leading to a certain number of revision surgeries. Apart from the problems associated with insufficient material properties, another serious issue is an implant associated infection due to the formation of a biofilm on the surface of the material after implantation. Thus, improvements in implant technology are demanded, especially since there is a projected rise of implants needed in the future. Surface modification methods such as physical vapour deposition (PVD), oxygen diffusion hardening and electrochemical anodization have shown to be efficient methods to improve the surfaces of metallic bulk materials regarding biomedical issues. This thesis was focused on the development of functional PVD coatings that are suitable for further treatment with surface modification techniques originally developed for bulk metals. The aim was to precisely adjust the surface properties of the implant according to the targeted application to prevent possible failure mechanisms such as coating delamination, wear or the occurrence of post-operative infections. Initially,  tantalum layers with approx 5 µm thickness were deposited at elevated substrate temperatures on cp Ti by RF magnetron sputtering. Due to the high affinity of tantalum to oxygen, these coatings are known to provide a self healing capacity since the rapid oxide formation is known to close surface cracks. Here, the work aimed to reduce the abrupt change of mechanical properties between the hard and brittle coating and the ductile substrate by creating an oxygen diffusion zone. It was found that the hardness and adhesion could be significantly increased when the coatings were treated afterwards by oxygen diffusion hardening in a two step process. Firstly, the surface was oxidized at a pressure of 6.7•10-3 mbar at 350 450 °C, followed by 1-2 h annealing in oxygen-free atmosphere at the same temperature leading to a diffusion of oxygen atoms into deeper parts of the substrate as proved by X-ray diffraction (XRD) analysis. The hereby caused mechanical stress in the crystal lattice led to an increase in Vickers hardness of the Ta layers from 570 HV to over 900 HV. Investigations into the adhesion of oxygen diffusion treated samples by Rockwell measurements demonstrated an increase of critical force for coating delamination from 12 N for untreated samples up to 25 N for diffusion treated samples. In a second approach, the development of modular targets aimed to produce functional coatings by metallic doping of titanium with biologically active agents. This was demonstrated by the fabrication of antimicrobial Ti(Ag) coatings using a single magnetron sputtering source equipped with a titanium target containing implemented silver modules under variation of bias voltage and substrate temperature. The deposition of both Ti and Ag was confirmed by X-ray diffraction and a clear correlation between the applied sputtering parameters and the silver content of the coatings was demonstrated by ICP-MS and EDX. Surface-sensitive XPS measurements revealed that higher substrate temperatures led to an accumulation of Ag in the near-surface region, while the application of a bias voltage had the opposite effect. SEM and AFM microscopy revealed that substrate heating during film deposition supported the formation of even and dense surface layers with small roughness values, which could even be enforced by applying a substrate bias voltage. Additional elution measurements using ICP-MS showed that the release kinetics depended on the amount of silver located at the film surface and hence could be tailored by variation of the sputter parameters. In a final step, the applied Ti and Ti(Ag) coatings deposited on cp Ti, stainless steel (316L) and glass substrates were subsequently nanostructured using a self-ordering process induced by electrochemical anodization in aqueous fluoride containing electrolytes. SEM analysis showed that nanotube arrays could be grown from the Ti and Ti(Ag) coatings deposited at elevated temperatures on any substrate, whereby no influence of the substrate on nanotube morphology could be observed. EDX measurements indicated that the anodization process led to the selective etching of Ti from Ti(Ag) coating. Further experiments on coatings deposited on glass surfaces revealed that moderate substrate temperatures during deposition resulting in smooth Ti layers as determined by AFM measurements, are favorable for the generation of highly ordered nanotube arrays. Such arrays exhibited superhydrophilic behavior as proved by contact angle measurements. XRD analysis revealed that the nanostructured coatings were amorphous after anodization but could be crystallized to anatase structure by thermal treatment at temperatures of 450°C.}, subject = {PVD-Verfahren}, language = {en} } @misc{Christoffel1976, type = {Master Thesis}, author = {Christoffel, Volker}, title = {Rekonstitution des Chromophors und der Funktion von Bakteriorhodopsin aus Halobacterium halobium}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-144908}, school = {Universit{\"a}t W{\"u}rzburg}, pages = {68}, year = {1976}, abstract = {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 Molek{\"u}le in die isolierte Purpurmembran und nach Zugabe zu Halobakterien mit unterdr{\"u}ckter Retinalsynthese die direkte Beteiligung des Cyclohexenringes an der Protonenpumpe mit großer Wahrscheinlichkeit ausgeschlossen werden.}, subject = {Bakteriorhodopsin}, language = {de} } @phdthesis{Feineis2018, author = {Feineis, Susanne}, title = {Thioether-poly(glycidol) as multifunctional coating system for gold nanoparticles}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-172902}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {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.}, subject = {Nanopartikel}, language = {en} } @phdthesis{Stuckensen2016, author = {Stuckensen, Kai}, title = {Fabrication of hierarchical cell carrier matrices for tissue regeneration by directional solidification}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-145510}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {The key hypothesis of this work represented the question, if mimicking the zonal composition and structural porosity of musculoskeletal tissues influences invading cells positively and leads to advantageous results for tissue engineering. Conventional approaches in tissue engineering are limited in producing monolithic "scaffolds" that provide locally variating biological key signals and pore architectures, imitating the alignment of collagenous fibres in bone and cartilage tissues, respectively. In order to fill this gap in available tissue engineering strategies, a new fabrication technique was evolved for the production of scaffolds to validate the hypothesis. Therefore, a new solidification based platform procedure was developed. This process comprises the directional solidification of multiple flowable precursors that are "cryostructured" to prepare a controlled anisotropic pore structure. Porous scaffolds are attained through ice crystal removal by lyophilisation. Optionally, electrostatic spinning of polymers may be applied to provide an external mesh on top or around the scaffolds. A consolidation step generates monolithic matrices from multi zonal structures. To serve as matrix for tissue engineering approaches or direct implantation as medical device, the scaffold is sterilized. An Adjustable Cryostructuring Device (ACD) was successively developed; individual parts were conceptualized by computer aided design (CAD) and assembled. During optimisation, a significant performance improvement of the ACDs accessible external temperature gradient was achieved, from (1.3 ± 0.1) K/mm to (9.0 ± 0.1) K/mm. Additionally, four different configurations of the device were made available that enabled the directional solidification of collagenous precursors in a highly controlled manner with various sample sizes and shapes. By using alginate as a model substance the process was systematically evaluated. Cryostructuring diagraphs were analysed yielding solidification parameters, which were associated to pore sizes and alignments that were determined by image processing. Thereby, a precise control over pore size and alignment through electrical regulation of the ACD could be demonstrated. To obtain tissue mimetic scaffolds for the musculoskeletal system, collagens and calcium phosphates had to be prepared to serve as raw materials. Extraction and purification protocols were established to generate collagen I and collagen II, while the calcium phosphates brushite and hydroxyapatite were produced by precipitation reactions. Besides the successive augmentation of the ACD also an optimization of the processing steps was crucial. Firstly, the concentrations and the individual behaviour of respective precursor components had to be screened. Together with the insights gained by videographic examination of solidifying collagen solutions, essential knowledge was gained that facilitated the production of more complex scaffolds. Phenomena of ice crystal growth during cryostructuring were discussed. By evolutionary steps, a cryostructuring of multi-layered precursors with consecutive anisotropic pores could be achieved and successfully transferred from alginate to collagenous precursors. Finally, very smooth interfaces that were hardly detectable by scanning electron microscopy (SEM) could be attained. For the used collagenous systems, a dependency relation between adjustable processing parameters and different resulting solidification morphologies was created. Dehydrothermal-, diisocyanate-, and carbodiimide- based cross linking methods were evaluated, whereby the "zero length" cross linking by carbodiimide was found to be most suitable. Afterwards, a formulation for the cross linking solution was elaborated, which generated favourable outcomes by application inside a reduced pressure apparatus. As a consequence, a pore collapse during wet chemical cross linking could be avoided. Complex monolithic scaffolds featuring continuous pores were fabricated that mimicked structure and respective composition of different areas of native tissues by the presence of biochemical key stimulants. At first, three types of bone scaffolds were produced from collagen I and hydroxyapatite with appropriate sizes to fit critical sized defects in rat femurs. They either featured an isotropic or anisotropic porosity and partly also contained glycosaminoglycans (GAGs). Furthermore, meniscus scaffolds were prepared by processing two precursors with biomimetic contents of collagen I, collagen II and GAGs. Here, the pore structures were created under boundary conditions, which allowed an ice crystal growth that was nearly orthogonal to the external temperature gradient. Thereby, the preferential alignment of collagen fibres in the natural meniscus tissue could be mimicked. Those scaffolds owned appropriate sizes for cell culture in well plates or even an authentic meniscus shape and size. Finally, osteochondral scaffolds, sized to either fit well plates or perfusion reactors for cell culture, were fabricated to mimic the composition of subchondral bone and different cartilage zones. Collagen I and the resorbable calcium phosphate brushite were used for the subchondral zone, whereas the cartilage zones were composed out of collagen I, collagen II and tissue mimetic contents of GAGs. The pore structure corresponded to the one that is dominating the volume of natural osteochondral tissue. Energy dispersive X-ray spectroscopy (EDX) and SEM were used to analyse the composition and pore structure of the individual scaffold zones, respectively. The cross section pore diameters were determined to (65 ± 25) µm, (88 ± 35) µm and(93 ± 42) µm for the anisotropic, the isotropic and GAG containing isotropic bone scaffolds. Furthermore, the meniscus scaffolds showed pore diameters of (93 ± 21) µm in the inner meniscus zone and (248 ± 63) µm inside the outer meniscus zone. Pore sizes of (82 ± 25) µm, (83 ± 29) µm and (85 ± 39) µm were present inside the subchondral, the lower chondral and the upper chondral zone of osteochondral scaffolds. Depending on the fabrication parameters, the respective scaffold zones were also found to feature a specific micro- and nanostructure at their inner surfaces. Degradation studies were carried out under physiological conditions and resulted in a mean mass loss of (0.52 ± 0.13) \%, (1.56 ± 0.10) \% and (0.80 ± 0.10) \% per day for bone, meniscus and osteochondral scaffolds, respectively. Rheological measurements were used to determine the viscosity changes upon cooling of different precursors. Micro computer tomography (µ-CT) investigations were applied to characterize the 3D microstructure of osteochondral scaffolds. To obtain an osteochondral scaffold with four zones of tissue mimetic microstructure alignment, a poly (D, L-lactide-co-glycolide) mesh was deposited on the upper chondral zone by electrostatic spinning. In case of the bone scaffolds, the retention / release capacity of bone morphogenetic protein 2 (BMP-2) was evaluated by an enzyme linked immunosorbent assay (ELISA). Due to the high presence of attractive BMP binding sites, only less than 0.1 \% of the initially loaded cytokine was released. The suitability of combining the cryostructuring process with 3D powder printed calcium phosphate substrates was evaluated with osteochondral scaffolds, but did not appear to yield more preferable results than the non-combined approach. A new custom build confined compression setup was elaborated together with a suitable evaluation procedure for the mechanical characterisation under physiological conditions. For bone and cartilage scaffolds, apparent elastic moduli of (37.6 ± 6.9) kPa and (3.14 ± 0.85) kPa were measured. A similar behaviour of the scaffolds to natural cartilage and bone tissue was demonstrated in terms of elastic energy storage. Under physiological frequencies, less than 1.0 \% and 0.8 \% of the exerted energy was lost for bone and cartilage scaffolds, respectively. With average relaxation times of (0.613 ± 0.040) sec and (0.815 ± 0.077) sec, measured for the cartilage and bone scaffolds, they respond four orders of magnitude faster than the native tissues. Additionally, all kinds of produced scaffolds were able to withstand cyclic compression at un-physiological frequencies as high as 20 Hz without a loss in structural integrity. With the presented new method, scaffolds could be fabricated whose extent in mimicking of native tissues exceeded the one of scaffolds producible by state of the art methods. This allowed a testing of the key hypothesis: The biological evaluation of an anisotropic pore structure in vivo revealed a higher functionality of immigrated cells and led finally to advantageous healing outcomes. Moreover, the mimicking of local compositions in combination with a consecutive anisotropic porosity that approaches native tissue structures could be demonstrated to induce zone specific matrix remodelling in stem cells in vitro. Additionally, clues for a zone specific chondrogenic stem cell differentiation were attained without the supplementation of growth factors. Thereby, the hypothesis that an increased approximation of the hierarchically compositional and structurally anisotropic properties of musculoskeletal tissues would lead to an improved cellular response and a better healing quality, could be confirmed. With a special focus on cell free in situ tissue engineering approaches, the insights gained within this thesis may be directly transferred to clinical regenerative therapies.}, subject = {Tissue Engineering}, language = {en} } @phdthesis{Schmitz2016, author = {Schmitz, Michael}, title = {Functional hydrophilic polymers for chemoselective coupling}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-145629}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {Chemoselective poly(oxazolines) (POx) and poly[(oligo ethylene glycol) acrylates] were synthesized. An initiator was produced for the preparation of poly(oxazoline)s capable of participating in click chemistry reactions which allows the functionalization of the polymer at the α terminus which was confirmed by 1H NMR spectroscopy. The initiator was used for the polymerization of hydrophilic 2 methyl 2 oxazoline (MeOx), whereby chemoselective, alkyne functionalized polymers could be prepared for Cu-catalyzed azide-alkyne cycloaddition. The desired molecular weight could be achieved through the living, ring opening cationic polymerization and was confirmed by 1H NMR, SEC and MALDI ToF measurements. Polymers were terminated with piperidine if no further functionalization was needed, or with an ester derivate for enabling amine attachment in a subsequent step. In addition, polymers were functionalized by termination with NaN3 in order to provide the counterpart to the azide-alkyne reaction. IR spectroscopy was suitable for the azide detection. The coupling of polymers showed the reactivity and could be confirmed by SEC, 1H NMR and IR spectroscopy. The composition of cysteine functionalized POx was completed by thiol-ene chemistry. Since the commercially available iso 2 propyl 2 oxazoline is not available for the cationic polymerization, 2 butenyl and 2 decenyl 2 oxazoline (ButenOx and DecenOx) were first prepared. The synthesis of both copolymers, based on MeOx could be confirmed by 1H NMR as well as with SEC, whereby narrow distributions with dispersities of 1.06 could be achieved. The cysteine functionalization of the copolymers was enabled by the creation of a thiazolidine component which could be synthesized by acetal and formyl protection of cysteine and subsequent functionalization with a thiol. The component enabled the reaction with a polymer by thiol-ene reaction which was started by the addition of dimethoxyphenyl-acetophenone and was catalyzed by irradiation with UV light. Both copolymers, with a shorter (polymers with BuenOx) and longer (polymers with DecenOx) hydrophobic sidechain could be functionalized. 1H NMR spectroscopic analysis showed a quantitative reaction with the thiazolidine derivate. After deprotection by acidic workup the desired, cysteine functionalized polymer could be isolated. Quantification of cysteine functions was ensured by a modified TNBSA assay, whereby the thiols were first oxidized in order to confirm an independent measurement of amine functions. Both, the TNBSA assay as well as the NMR measurement showed the desired number of cysteine residues. The cytotoxicity of functionalized polymers with different compositions was tested by a luminescent cell viability assay (LCVA). Both, the amount of cysteine functions (5-10\%) in the copolymers as well as the length of the hydrophobic side chain were varied. All polymers did not show cytotoxicity up to concentrations of 10 mg∙mL-1. The cell activity and cell numbers only decreased below 50\% and 20\% respectively, when copolymers with 5\% cysteine and longer sidechains were measured, which was attributed to a contamination of the sample itself. The cooperation partner performed Native Chemical Ligation (NCL) with model peptides and purified the products by HPLC. A sterically non demanding peptide was synthesized, consisting of an aromatic amino acid and four glycine units. The aromatic unit was used for the quantification of the polymer-peptide conjugate in the 1H NMR spectroscopy. A polymer having five cysteine side chains has been fully implemented by NCL to a conjugate of one polymer with five peptides. A sterically more demanding peptide was additionally used and MALDI ToF measurements confirmed the successful conjugation. Furthermore the cysteine functionalized polymer was used for nanogel synthesis. The thiol of the cysteine function was oxidized in an inverse mini-emulsion by H2O2, resulting in nanogels (~500 nm) which could be confirmed by SEM, AFM, DLS and NTA measurements. Besides POx, oligo (ethylene glycol)acrylates (OEGA) were polymerized; by copolymerization with the reactive pentafluorophenyl acrylate (PFPA) reactive and amphiphilic polymers were obtained. The synthesis of PFPA could be confirmed spectroscopically by 1H , 19F NMR, and by FT IR. Copolymers were synthesized by RAFT polymerization with narrow dispersities. Functionalization with an amine functionalized thiazolidine led to a hydrophilic cysteine functionalized polymer after acidic deprotection. Apart from this polymer, a thioester functionalization was successfully performed by reaction of the active polymer with a cyclic amine functionalized thioester which does not release a toxic by product (such as the resulting thiol) during NCL and thus features a very high potential to replace former thioester.}, subject = {Konjugate}, language = {en} } @phdthesis{Wittmann2014, author = {Wittmann, Katharina}, title = {Adipose Tissue Engineering - Development of Volume-Stable 3-Dimensional Constructs and Approaches Towards Effective Vascularization}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-107196}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Adipose tissue defects and related pathologies still represent major challenges in reconstructive surgery. Based on to the paradigm 'replace with alike', adipose tissue is considered the ideal substitute material for damaged soft tissue [1-3]. Yet the transfer of autologous fat, particularly larger volumes, is confined by deficient and unpredictable long term results, as well as considerable operative morbidity at the donor and recipient site [4-6], calling for innovative treatment options to improve patient care. With the aim to achieve complete regeneration of soft tissue defects, adipose tissue engineering holds great promise to provide functional, biologically active adipose tissue equivalents. Here, especially long-term maintenance of volume and shape, as well as sufficient vascularization of engineered adipose tissue represent critical and unresolved challenges [7-9]. For adipose tissue engineering approaches to be successful, it is thus essential to generate constructs that retain their initial volume in vivo, as well as to ensure their rapid vascularization to support cell survival and differentiation for full tissue regeneration [9,10]. Therefore, it was the ultimate goal of this thesis to develop volume-stable 3D adipose tissue constructs and to identify applicable strategies for sufficient vascularization of engineered constructs. The feasibility of the investigated approaches was verified by translation from in vitro to in vivo as a critical step for the advancement of potential regenerative therapies. For the development of volume-stable constructs, the combination of two biomaterials with complementary properties was successfully implemented. In contrast to previous approaches in the field using mainly non-degradable solid structures for mechanical protection of developing adipose tissue [11-13], the combination of a cell-instructive hydrogel component with a biodegradable porous support structure of adequate texture was shown advantageous for the generation of volume-stable adipose tissue. Specifically, stable fibrin hydrogels previously developed in our group [14] served as cell carrier and supported the adipogenic development of adipose-derived stem cells (ASCs) as reflected by lipid accumulation and leptin secretion. Stable fibrin gels were thereby shown to be equally supportive of adipogenesis compared to commercial TissuCol hydrogels in vitro. Using ASCs as a safe source of autologous cells [15,16] added substantial practicability to the approach. To enhance the mechanical strength of the engineered constructs, porous biodegradable poly(ε caprolactone)-based polyurethane (PU) scaffolds were introduced as support structures and shown to exhibit adequately sized pores to host adipocytes as well as interconnectivity to allow coherent tissue formation and vascularization. Low wettability and impaired cell attachment indicated that PU scaffolds alone were insufficient in retaining cells within the pores, yet cytocompatibility and differentiation of ASCs were adequately demonstrated, rendering the PU scaffolds suitable as support structures for the generation of stable fibrin/PU composite constructs (Chapter 3). Volume-stable adipose tissue constructs were generated by seeding the pre-established stable fibrin/PU composites with ASCs. Investigation of size and weight in vitro revealed that composite constructs featured enhanced stability relative to stable fibrin gels alone. Comparing stable fibrin gels and TissuCol as hydrogel components, it was found that TissuCol gels were less resilient to degradation and contraction. Composite constructs were fully characterized, showing good cell viability of ASCs and strong adipogenic development as indicated by functional analysis via histological Oil Red O staining of lipid vacuoles, qRT-PCR analysis of prominent adipogenic markers (PPARγ, C/EBPα, GLUT4, aP2) and quantification of leptin secretion. In a pilot study in vivo, investigating the suitability of the constructs for transplantation, stable fibrin/PU composites provided with a vascular pedicle gave rise to areas of well-vascularized adipose tissue, contrasted by insufficient capillary formation and adipogenesis in constructs implanted without pedicle. The biomaterial combination of stable fibrin gels and porous biodegradable PU scaffolds was thereby shown highly suitable for the generation of volume-stable adipose tissue constructs in vivo, and in addition, the effectiveness of immediate vascularization upon implantation to support adipose tissue formation was demonstrated (Chapter 4). Further pursuing the objective to investigate adequate vascularization strategies for engineered adipose tissue, hypoxic preconditioning was conducted as a possible approach for in vitro prevascularization. In 2D culture experiments, analysis on the cellular level illustrated that the adipogenic potential of ASCs was reduced under hypoxic conditions when applied in the differentiation phase, irrespective of the oxygen tension encountered by the cells during expansion. Hypoxic treatment of ASCs in 3D constructs prepared from stable fibrin gels similarly resulted in reduced adipogenesis, whereas endothelial CD31 expression as well as enhanced leptin and vascular endothelial growth factor (VEGF) secretion indicated that hypoxic treatment indeed resulted in a pro-angiogenic response of ASCs. Especially the observed profound regulation of leptin production by hypoxia and the dual role of leptin as adipokine and angiogenic modulator were considered an interesting connection advocating further study. Having confirmed the hypothesis that hypoxia may generate a pro-angiogenic milieu inside ASC-seeded constructs, faster vessel ingrowth and improved vascularization as well as an enhanced tolerance of hypoxia-treated ASCs towards ischemic conditions upon implanatation may be expected, but remain to be verified in rodent models in vivo (Chapter 5). Having previously been utilized for bone and cartilage engineering [17-19], as well as for revascularization and wound healing applications [20-22], stromal-vascular fraction (SVF) cells were investigated as a novel cell source for adipose tissue engineering. Providing cells with adipogenic differentiation as well as vascularization potential, the SVF was applied with the specific aim to promote adipogenesis and vascularization in engineered constructs in vivo. With only basic in vitro investigations by Lin et al. addressing the SVF for adipose repair to date [23], the present work thoroughly investigated SVF cells for adipose tissue construct generation in vitro, and in particular, pioneered the application of these cells for adipose tissue engineering in vivo. Initial in vitro experiments compared SVF- and ASC-seeded stable fibrin constructs in different medium compositions employing preadipocyte (PGM-2) and endothelial cell culture medium (EGM-2). It was found that a 1:1 mixture of PGM-2 and EGM-2, as previously established for co-culture models of adipogenesis [24], efficiently maintained cells with adipogenic and endothelial potential in SVF-seeded constructs in short and long-term culture setups. Observations on the cellular level were supported by analysis of mRNA expression of characteristic adipogenic and endothelial markers. In preparation of the evaluation of SVF-seeded constructs under in vivo conditions, a whole mount staining (WMS) method, facilitating the 3D visualization of adipocytes and blood vessels, was successfully established and optimized using native adipose tissue as template (Chapter 6). In a subcutaneous nude mouse model, SVF cells were, for the first time in vivo, elucidated for their potential to support the functional assembly of vascularized adipose tissue. Investigating the effect of adipogenic precultivation of SVF-seeded stable fibrin constructs in vitro prior to implantation on the in vivo outcome, hormonal induction was shown beneficial in terms of adipocyte development, whereas a strong vascularization potential was observed when no adipogenic inducers were added. Via histological analysis, it was proven that the developed structures were of human origin and derived from the implanted cells. Applying SVF cells without precultivation in vitro but comparing two different fibrin carriers, namely stable fibrin and TissuCol gels, revealed that TissuCol profoundly supported adipose formation by SVF cells in vivo. This was contrasted by only minor SVF cell development and a strong reduction of cell numbers in stable fibrin gels implanted without precultivation. Histomorphometric analysis of adipocytes and capillary structures was conducted to verify the qualitative results, concluding that particularly SVF cells in TissuCol were highly suited for adipose regeneration in vivo. Employing the established WMS technique, the close interaction of mature adipocytes and blood vessels in TissuCol constructs was impressively shown and via species-specific human vimentin staining, the expected strong involvement of implanted SVF cells in the formation of coherent adipose tissue was confirmed (Chapter 7). With the development of biodegradable volume-stable adipose tissue constructs, the application of ASCs and SVF cells as two promising cell sources for functional adipose regeneration, as well as the thorough evaluation of strategies for construct vascularization in vitro and in vivo, this thesis provides valuable solutions to current challenges in adipose tissue engineering. The presented findings further open up new perspectives for innovative treatments to cure soft tissue defects and serve as a basis for directed approaches towards the generation of clinically applicable soft tissue substitutes.}, subject = {Tissue Engineering}, language = {en} } @phdthesis{Ahmed2014, author = {Ahmed, Arabe}, title = {Assessing particle deposition in a representative in vitro model of the rat respiratory tract}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-104912}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {The aim of this thesis was to develop an in vitro model (IVR) of the rat lung for the purpose of investigating the deposition of drug particles in the rat airways. The model attempted to account for the affect of drug product characteristics and physiological parameters on deposition in the lungs. In addition, the model outputs were compared with in vivo lung deposition results from live rats and in silico predictions using published computer model of lung deposition in pre-clinical species. Initial work focussed on developing an aerosol exposure system capable of dosing small rodent to a range of airborne test materials. The system consists of two main parts; a fluidised bed aerosol generator and connection of the generator output to a nose only exposure chamber capable of accommodating 12 small animals in a single layer. In addition, an aerodynamic particle spectrometer (APS) was installed for continuously measuring the size distribution and airborne concentration of aerosol particles generated in the exposure chamber. System validation showed acceptable degree of variation of the test material tested, Fluorescent Microspheres (FMS) throughout the exposure chamber (CV < 15.0\%). Particle size (MMAD ± GSD) using the APS was shown to be stable throughout the exposure periods. The IVR model developed in this project was based on a number of euthanased (n=7), female Sprague-Dawley rats (weight: 372 ± 56 g), which underwent high-resolution micro-CT scans. The physical model consisted of five sub sections; Extra-Thoracic region containing the snout and nasophyarynx, trachea-bronchial region containing the trachea, bronchi, and bronchioles. All sections of the model were attached to one another in numerical order and housed within a containment unit. At the rear end of the cast, a flexible diaphragm was attached in order to collect the fraction of inhaled particles exiting the TB section and possibly reaching the lung, referred to as the Post-TB section. A study was conducted to assess the influence of inhalation parameters such as the breathing frequency and tidal volume on total and regional dose distribution using FMS as test material. The major finding of this study was the demonstration of the model sensitivity to changes in breathing parameters especially respiratory frequency, where the data showed increased deposition in the peripheral regions of the model with decreased respiratory frequency. Other studies assessed the effect of particle characteristics on deposition on the IVR model, such as particle size, dose increase and formulation changes. The results assessing particle size effect showed a slightly higher deposition levels for the 4µm sized particles versus 2µm sized particles in the head region; 90.8 ± 3.6\% and 88.2 ± 6.6\%. However, this difference did not reach statistical significance (P> 0.05) probably due to the polydispersity of aerosolised FMS particles. In addition, the regional deposition analysis showed an increased lung peripheral deposition with the smaller particles. In addition, the model was shown to be sensitive to changes in formulation composition mediated by inclusion of MgSt. The next stage of work was to validate the model in terms of comparison with lung deposition for in vivo rats. For lung deposition comparison, the absolute amount deposited in the IVR lung model (expressed as µg/kg) was shown to have a reasonably strong correlation with in vivo lung concentration measures (µg/kg); R2= 0.66, P < 0.05. Compounds were predicted well and within 2-folds of the measured lung deposition values. However, knowing the variability in biological systems and the multiple components required to estimate lung doses, predictions within 2-fold of the measured values would seem reasonable In terms of comparison with in silico model predictions using MPPD, similar deposition levels were noted between the two models, particularly when the data was expressed as percentage of total particles inhaled. The data showed the highest deposition levels were noted in the head region (> 80\%) and less than 5.0\% deposition for the peripheral lung fractions. With regards to using the IVR model to assess the relationship between dose, particle size and efficacy, an in vivo study using FP with different particle sizes (2.0 and 4.0 µm) but same doses ( 100 and 1000 µg/kg). This study demonstrated that exposure of rat to FP powder resulted in a dose-dependent inhibition of neutrophils in BAL fluids. However, a clear difference in neutrophils suppression was demonstrated for equivalent doses but different particle sizes of FP, where the smaller FP particles (2.0 µm) induced a greater level of neutrophils suppression in comparison with larger FP particles (4.0 µm). In addition, a reasonably good correlation for the relationship between lung deposition in the IVR model and a neutrophils suppression level was demonstrated. Furthermore this data support the hypothesis that regional deposition is an important determinant in efficacy. Therefore, this suggests that the IVR model may be a useful as a tool to describe in vivo efficacy with in vitro data. However, further studies should be conducted to evaluate the validity of this model and relationship. The IVR model has a number of important limitations. First, the model is based on scans up to generation four of the rat respiratory tract as this represented the limits of the micro-CT scanning technology at the time of this study. Therefore deposition in the deeper region of the lung may not be reflected precisely in the IVR model. Second, the regional deposition data generated using the model tended to show an overestimation of deposition in head region and an underestimation of deposition in the peripheral regions of the lung, in comparison with in vivo lung deposition data. Third, the current model does not take into account lung clearance. However, the amount of the drug present in the in vivo lungs is dependent on numerous physiological processes such as dissolution, passive or active absorption into the systemic circulation, binding to lung tissue and mucociliary clearance. Consequently, the results generated using this IVR model for drug molecules with high lung clearance rate should be treated with some caution. Future work extending this research could go in a number of directions. In this research, a representative model of the rat respiratory tract was constructed from analysis of imaging data from a number of euthanised Sprague-Dawley rats. This model represented the "average respiratory tract" in terms of dimensions of Sprague-Dawley rats. However, there is considerable variability in the airway dimensions between rats. This variability encompasses a number of factors such as the strains of rats, sex and age, and disease state. Thus, it may be possible to produce a small number of airway models to represent small and large rats and scaled to represent the extrathoracic and peripheral regions based on literature reports of their dimensions in different rat populations. This approach will then enable the effect of intersubject airway dimensions for different rat populations on aerosol deposition to be thoroughly examined. In addition, due to the limitation of the micro-CT technology used to construct the physical IVR model, detailed morphology only up to generation 4 were captured. However, recent advances in MRI technology, such as the use of in situ-MRI based scanning technology have enabled rat airway morphometry to be extended to 16 airway generation. This coupled with improvements in the resolutions of rapid-prototyping process means it may be possible to construct a rat model that reflects the in vivo lung morphology more accurately, and thus enable greater understanding of the link between aerosol deposition and airway geometry. In conclusion, a model cast of the rat lung was developed and validated to allow the deposition of inhaled particles in the rat lung to be investigated. The model may be used to estimate the lung concentration in vivo rats in preference to exposure concentration measurements based on filter samples which have been shown to be a poor indicator of the lung concentration immediately after exposure. In addition, the model has the potential to be used along with live rats in an inhalation rig in pulmonary pharmaceutics research and may facilitate in development of inhaled formulations to target specific regions within the lung as well as screening of inhaled drugs in preclinical setting.}, subject = {Ratte}, language = {en} } @phdthesis{Stoll2015, author = {Stoll, Georg}, title = {Identification of the mRNA-associated TOP3β- TDRD3-FMRP (TTF) -complex and its implication for neurological disorders}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-111440}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {The propagation of the genetic information into proteins is mediated by messenger- RNA (mRNA) intermediates. In eukaryotes mRNAs are synthesized by RNA- Polymerase II and subjected to translation after various processing steps. Earlier it was suspected that the regulation of gene expression occurs primarily on the level of transcription. In the meantime it became evident that the contribution of post- transcriptional events is at least equally important. Apart from non-coding RNAs and metabolites, this process is in particular controlled by RNA-binding proteins, which assemble on mRNAs in various combinations to establish the so-called "mRNP- code". In this thesis a so far unknown component of the mRNP-code was identified and characterized. It constitutes a hetero-trimeric complex composed of the Tudor domain-containing protein 3 (TDRD3), the fragile X mental retardation protein (FMRP) and the Topoisomerase III beta (TOP3β) and was termed TTF (TOP3β-TDRD3-FMRP) -complex according to its composition. The presented results also demonstrate that all components of the TTF-complex shuttle between the nucleus and the cytoplasm, but are predominantly located in the latter compartment under steady state conditions. Apart from that, an association of the TTF-complex with fully processed mRNAs, not yet engaged in productive translation, was detected. Hence, the TTF-complex is a component of „early" mRNPs. The defined recruitment of the TTF-complex to these mRNPs is not based on binding to distinct mRNA sequence-elements in cis, but rather on an interaction with the so-called exon junction complex (EJC), which is loaded onto the mRNA during the process of pre-mRNA splicing. In this context TDRD3 functions as an adapter, linking EJC, FMRP and TOP3β on the mRNP. Moreover, preliminary results suggest that epigenetic marks within gene promoter regions predetermine the transfer of the TTF-complex onto its target mRNAs. Besides, the observation that TOP3β is able to catalytically convert RNA-substrates disclosed potential activities of the TTF-complex in mRNA metabolism. In combination with the already known functions of FMRP, this finding primarily suggests that the TTF-complex controls the translation of bound mRNAs. In addition to its role in mRNA metabolism, the TTF-complex is interesting from a human genetics perspective as well. It was demonstrated in collaboration with researchers from Finland and the US that apart from FMRP, which was previously linked to neurocognitive diseases, also TOP3β is associated with neurodevelopmental disorders. Understanding the function of the TTF-complex in mRNA metabolism might hence provide important insight into the etiology of these diseases.}, subject = {Messenger-RNS}, language = {en} } @phdthesis{Kuhlmann2015, author = {Kuhlmann, Matthias}, title = {Sulfur-functional polymers for biomedical applications}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-119832}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {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.}, subject = {Polymer}, language = {en} } @phdthesis{Macher2021, author = {Macher, Sven}, title = {On the Effects of Moisture on Polymer-Based Electrochromic Devices}, doi = {10.25972/OPUS-24240}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-242407}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {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]}, subject = {Elektrochromie}, language = {en} } @phdthesis{Lang2021, author = {Lang, Katharina}, title = {Synthese leitf{\"a}higer elastischer Materialkomposite durch Verwendung metallischer Nanodr{\"a}hte}, doi = {10.25972/OPUS-24825}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-248253}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {Silbernanodr{\"a}hte (AgNW) wurden in verschiedene Hybridpolymere und in eine als Referenz dienende Silikonzusammensetzung eingebaut. Durch Spincoating konnten transparente leitf{\"a}hige Filme erhalten werden. Deren jeweilige Nanodrahtverteilung, thermische Aktivierung und visuelle Transparenz wurden charakterisiert. Die Perkolationsschwelle der Filme h{\"a}ngt dabei von der individuellen durchschnittlichen AgNW-L{\"a}nge ab. Eine betr{\"a}chtliche Leitf{\"a}higkeit wurde w{\"a}hrend des mechanischen Streckens bis zu 30 \% aufrechterhalten. Mikrostrukturierte Hybridpolymer-Verbundfilme wurden durch UV-Lithographie erhalten. ...}, subject = {Verbundwerkstoff}, language = {de} } @phdthesis{Steinbacher2015, author = {Steinbacher, Andreas Edgar}, title = {Circular dichroism and accumulative polarimetry of chiral femtochemistry}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-116500}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {This work brings forward successful implementations of ultrafast chirality-sensitive spectroscopic techniques by probing circular dichroism (CD) or optical rotation dispersion (ORD). Furthermore, also first steps towards chiral quantum control, i.e., the selective variation of the chiral properties of molecules with the help of coherent light, are presented. In the case of CD probing, a setup capable of mirroring an arbitrary polarization state of an ultrashort laser pulse was developed. Hence, by passing a left-circularly polarized laser pulse through this setup a right-circularly polarized laser pulse is generated. These two pulse enantiomers can be utilized as probe pulses in a pump--probe CD experiment. Besides CD spectroscopy, it can be utilized for anisotropy or ellipsometry spectroscopy also. Within this thesis, the approach is used to elucidate the photochemistry of hemoglobin, the oxygen transporting protein in mammalian blood. The oxygen loss can be triggered with laser pulses as well, and the results of the time-resolved CD experiment suggest a cascade-like relaxation, probably through different spin states, of the metallo-porphyrins in hemoglobin. The ORD probing was realized via the combination of common-path optical heterodyne interferometric polarimetry and accumulative femtosecond spectroscopy. Within this setup, on the one hand the applicability of this approach for ultrafast studies was demonstrated explicitly. On the other hand, the discrimination between an achiral and a racemic solution without prior spatial separation was realized. This was achieved by inducing an enantiomeric excess via polarized femtosecond laser pulses and following its evolution with the developed polarimeter. Hence, chiral selectivity was already achieved with this method which can be turned into chiral control if the polarized laser pulses are optimized to steer an enhancement of the enantiomeric excess. Furthermore, within this thesis, theoretical prerequisites for anisotropy-free pump--probe experiments with arbitrary polarized laser pulses were derived. Due to the small magnitude of optical chirality-sensitve signals, these results are important for any pump--probe chiral spectroscopy, like the CD probing presented in this thesis. Moreover, since for chiral quantum control the variation of the molecular structure is necessary, the knowledge about rearrangement reactions triggered by photons is necessary. Hence, within this thesis the ultrafast Wolff rearrangement of an α-diazocarbonyl was investigated via ultrafast photofragment ion spectroscopy in the gas phase. Though the compound is not chiral, the knowledge about the exact reaction mechanism is beneficial for future studies of chiral compounds.}, subject = {Ultrakurzzeitspektroskopie}, language = {en} } @phdthesis{Grotz2013, author = {Grotz, Michael}, title = {Synthese und Charakterisierung abiotischer Foldamere und ihrer Bausteine f{\"u}r die Nutzung in biologischen Systemen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-96486}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {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 Wasserl{\"o}slichkeit der Foldamere verbessern sollte. Zu diesem Zweck wurde eine zus{\"a}tzliche, hoch polare Seitenkette in den Chinolingrundk{\"o}rper eingef{\"u}hrt. Dieses modifizierte Monomer konnte erfolgreich synthetisiert werden. Um die Verbesserung der Wasserl{\"o}slichkeit gegen{\"u}ber dem zuvor verwendeten Monomer zu testen, wurde erfolgreich ein Tetramer daraus aufgebaut. Das entsch{\"u}tzte Tetramer konnte jedoch aufgrund seiner hohen Polarit{\"a}t nicht ausreichend gereinigt werden, um die abschließenden L{\"o}slichkeitsuntersuchungen durchzuf{\"u}hren. Um dieses Problem zu umgehen, wurde von der Umsetzung in L{\"o}sung auf Reaktionen an der Festphase gewechselt, was die Reinigung der Produkte wesentlich erleichtern sollte. Dabei wurde eine vom Arbeitskreis von I. Huc neu entwickelte mikrowellengest{\"u}tzte Methode verwendet. Das Referenzmolek{\"u}l mit den bisher verwendeten Seitenketten konnte so ohne Probleme synthetisiert und seine L{\"o}slichkeit 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: Zun{\"a}chst sollte ein Weg gefunden werden, die Einf{\"u}hrung der Seitenketten an den Chinolinen erst an der festen Phase vorzunehmen, wodurch viele Syntheseschritte bei der Vorbereitung der Monomere gespart werden k{\"o}nnten. Zus{\"a}tzlich sollte eine neue Kupplungsreaktion entwickelt werden, wodurch der Entsch{\"u}tzungsschritt des zu kuppelnden Amins an der Festphase eingespart werden kann. Dadurch w{\"u}rde vor allem bei großen Foldameren das Harz geschont und die Gefahr einer Degenerierung wesentlich verringert. F{\"u}r die Kupplungsreaktion vorgesehen war ein azidfunktionalisiertes Monomer, das mittels Staudinger-Reaktion verkn{\"u}pft werden sollte. Das entsprechende Monomer konnte erfolgreich synthetisiert werden. Auch das erste Ziel, die Einf{\"u}hrung der Seitenkette an der Festphase, konnte erfolgreich durchgef{\"u}hrt werden. Leider war die Verwirklichung beider Ziele {\"u}ber die gleiche Syntheseroute nicht ohne weiteres m{\"o}glich. Da das Monomer ohne die Seitenkette deutlich hydrophiler wurde, w{\"a}re eine Trocknungsmethode bei erh{\"o}hter Temperatur von Vorteil gewesen, um gebundenes Wasser vollst{\"a}ndig zu entfernen. Da das Monomer allerdings auch eine Azidfunktion tr{\"a}gt und sich bei 130 °C explosionsartig zersetzt, war dies nicht m{\"o}glich. Allerdings gen{\"u}gen bereits geringe Spuren von Feuchtigkeit, um die Staudinger-Reaktion zu beeintr{\"a}chtigten. Deshalb konnte das zweite Projektziel nicht verwirklicht werden. Im dritten Projekt wurde die Herstellung einer großen Foldamer-Bibliothek f{\"u}r die Untersuchung der Bindungsaffinit{\"a}t gegen{\"u}ber 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 zun{\"a}chst vier verschiedene Monomere synthetisiert, welche eine aromatisch, eine unpolare, eine anionische bzw. eine kationische Seitenkette enthielten. F{\"u}r die Kupplung der Foldamere wurde eine an die Synthese von Aminos{\"a}uresequenzen angelehnte Methode entwickelt und erfolgreich angewandt. So konnten alle 48 Foldamere erfolgreich synthetisiert und 46 von ihnen in ausreichenden Mengen f{\"u}r die Untersuchung an IL-4 gereinigt werden. Leider liegen f{\"u}r diese Bibliothek bisher keine abschließenden Ergebnisse {\"u}ber die Inhibitionseigenschaften gegen{\"u}ber IL-4 vor. Strukturell sehr {\"a}hnliche Foldamere zeigten jedoch in ersten Experimenten eine Inhibition von IL-4 was eine Wirksamkeit der neu erstellten Bibliothek vermuten l{\"a}sst. Das vierte Projekt wurde im Rahmen des SFB 630 durchgef{\"u}hrt. Hierzu wurden einige der urspr{\"u}nglich f{\"u}r andere Projekte hergestellten Foldamere ausgew{\"a}hlt, teilweise entsch{\"u}tzt bzw. an der Nitrogruppe reduziert und anschließend auf Ihre Aktivit{\"a}t 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 f{\"u}r die Erstellung einer neuen Leitstruktur gegen diese beiden Erreger. Allerdings trat im untersuchten Konzentrationsbereich auch keine Zytotoxizit{\"a}t auf, was eine interessante Information f{\"u}r die Verwendung der Foldamere und ihrer Bausteine in biologischen Systemen darstellt.}, subject = {Foldamere}, language = {de} } @phdthesis{Junold2014, author = {Junold, Konstantin}, title = {Synthese, Struktur und Eigenschaften neuer h{\"o}herkoordinierter Silicium(II)- und Silicium(IV)-Komplexe}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-104848}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Die vorliegende Arbeit stellt einen Beitrag zur Chemie des h{\"o}herkoordinierten Siliciums dar. Im Vordergrund standen die Synthese und Charakterisierung neuer neutraler penta- und hexakoordinierter Silicium(IV)-Komplexe sowie die Synthese, Charakterisierung und Untersuchung der Reaktivit{\"a}t eines neuartigen Donor-stabilisierten Silylens.}, subject = {Siliciumkomplexe}, language = {de} } @phdthesis{Laskowski2014, author = {Laskowski, Nadine}, title = {Synthese und Charakterisierung neuartiger siliciumhaltiger Synthesebausteine}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-107481}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {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. h{\"o}hervalenten Siliciums. Alle Zielverbindungen sowie die entsprechenden isolierten Vorstufen wurden durch NMR-Spektroskopie in L{\"o}sung (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 zus{\"a}tzlich durch NMR-Spektroskopie im Festk{\"o}rper (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-R{\"o}ntgenstrukturanalyse charakterisiert.}, subject = {Silicium}, language = {de} } @phdthesis{FlatenAndersen2013, author = {Fl{\aa}ten Andersen, Hanne}, title = {New Materials for Lithium-Ion Batteries}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-101434}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {Over the last decades, lithium-ion batteries have grown more important and substituted other energy storage systems. Due to advantages such as high energy density and low self-discharge, the lithium-ion battery has taken its part in the rechargeable energy storage market, and it is now found in most laptops, cameras and mobile phones. With the increasing demands for electrical vehicles and stationary energy storage systems, there is a necessity for improved lithium-ion battery materials. In this thesis several alternative electrode materials have been examined with a main focus on the electrochemical characterisation. As an alternative to the commercial cathode LiCoO2, the LiMn2O4 cathode has been suggested due to its reduced toxicity, material abundance, reduced costs and increased specific capacity. On the anode side, several Sn-containing anodes have been investigated and steps to overcome the main challenge, the great volume expansion upon cycling, have been taken. In addition, a novel anode material group was synthesised at the University of Marburg and two substances of the lithium chalcogenidometalate networks were successfully characterised. The cathode material, LiMn2O4, was synthesised via the sol-gel technique and several coating methods such as dip-coating, electrophoretics and infiltration were investigated. The LiMn2O4 material was initially coated on a porous metal foam as a current collector, thus providing new possibilities as the porosity of the substrate increased, mechanical stability and adhesion improved and a 3-dimensional network was obtained. In order to compare the results of the LiMn2O4 cathode material on the novel current collector, the material was also coated on a standard metallic foil and characterised. The analysis followed via X-ray diffraction, electron microscopy, thermogravimetrical analysis and several electrochemical techniques. Tin containing anode materials were chosen due to the doubling of the theoretical capacity compared with the commercially used graphite. However, a great challenge lies with using tin or tin-containing anode materials. Upon lithiation of Sn, the material can expand up to 300 \%, therefore a stabilising effect is necessary to avoid a collapse of the material. This work shows several new concepts and attempts to overcome this challenge, including SnO2 nanowires deposited via chemical vapour deposition on both metallic foam and standard current collectors. A new improvement consisted of the tin - carbon nanofibers where the nanofibers form a stabilising matrix that can partially buffer the volume change of the Sn particles. The synthesis of the Sn-containing anodes took place at the University of Cologne, while characterisation, cell preparation and optimising the electrode system were features of this thesis. In addition, a lithium chalcogenidometalate network proved to be an interesting, new anode material group. Both Li4MnSn2Se7 and Li4MnGe2S7 (synthesised at Philipps-Universit{\"a}t Marburg) were electrochemically examined to better understand the lithiation processes. Both materials obtained very high specific capacities and were found to be possible alternatives to the state-of-the art anodes. All the examined electrode materials were found to have some advantage over the commercially used LiCoO2 and graphite electrodes, and a thorough characterization of the materials was performed to understand the processes that took place.}, subject = {Lithium-Ionen-Akkumulator}, language = {en} } @phdthesis{Voelker2014, author = {V{\"o}lker, Sebastian}, title = {Synthesis, Spectroscopic and Electrochemical Properties of Squaraine Polymers}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-101638}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {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.}, subject = {Squaraine}, language = {en} } @phdthesis{Englbrecht2014, author = {Englbrecht, Clemens}, title = {Biochemische Rekonstitution und funktionelle Charakterisierung der Zusammenlagerungsmaschinerie spleißosomaler U snRNPs}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-98168}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Das Spleißen von pr{\"a}-mRNAs stellt in der Expression eukaryontischer Gene einen essentiellen Reifungsschritt dar. Erst durch das exakte Entfernen von nicht-kodierenden Introns und Verbinden der kodierenden Exons kann die genetische Information am Ribosom in funktionelle Proteine umgesetzt werden. Spleißen wird durch das Spleißosom katalysiert, welches sich aus den small nuclear ribonucleoproteins (snRNPs) U1, U2, U4, U5 und U6 und einer großen Anzahl weiterer Proteinfaktoren zusammensetzt. Die snRNPs bestehen aus einer Uridin-reichen snRNA, spezifischen und generellen (Sm-)Proteinen. Die Sm-Proteine B/B`, D1, D2, D3, E, F, und G bilden einen heptameren Ring um die sog. Sm-Bindungsstelle der snRNAs. W{\"a}hrend die Zusammenlagerung von Sm-Proteinen mit der RNA in vitro spontan ablaufen kann, wird dieser Prozess in vivo von zwei makromolekularen Proteinkomplexen assistiert, die als PRMT5- bzw. SMN-Komplex bezeichnet werden. Der PRMT5-Komplex (bestehend aus PRMT5, WD45 und pICln) agiert in der fr{\"u}hen Phase der Zusammenlagerung. Seine Hauptfunktion ist die symmetrische Dimethylierung der Sm-Proteine und die Stabilisierung von Sm-Proteinkomplexen durch das Chaperon pICln in zwei Intermediaten. Einhergehend mit dieser Aktivit{\"a}t werden auch Aggregation bzw. unspezifische Wechselwirkungen der Sm-Proteine mit RNAs verhindert. In der sp{\"a}ten Phase der Zusammenlagerung l{\"o}st der SMN-Komplex (bestehend aus SMN, Gemin2-8 und unrip) pICln-Intermediate auf, wobei dieser die Sm-Proteine en bloc {\"u}bernimmt und sie auf die snRNA {\"u}bertr{\"a}gt. W{\"a}hrend dieser Reaktion wird pICln aus den Komplexen verdr{\"a}ngt. Ein Fehlen des SMN-Proteins, einer Schl{\"u}sselkomponente des SMN-Komplexes, f{\"u}hrt zur autosomal rezessiven Erbkrankheit `Spinale Muskelatrophie` (SMA) wobei der Schweregrad der Krankheit invers mit der Menge an funktionellem SMN-Protein korreliert. Es wird vermutet, dass eine gest{\"o}rte snRNP-Biogenese die Ursache der SMA ist. In der vorliegenden Arbeit sollte die U snRNP-Zusammenlagerungsmaschinerie aus rekombinanten Bausteinen rekonstituiert werden und so funktionellen und strukturellen Studien zug{\"a}nglich gemacht werden. Folgende Resultate wurden in dieser Arbeit erhalten: 1) Im ersten Teil der Arbeit wurde eine experimentelle Strategie etabliert, welche die Rekonstitution des humanen SMN-Komplexes aus rekombinanten Untereinheiten erlaubte. Entscheidend hierf{\"u}r war die Definition von Subkomplexen aufgrund einer Protein-Interaktionskarte. Die Subkomplexe konnten separat hergestellt und anschließend zum Gesamtkomplex vereinigt werden. 2) Die erfolgreiche Etablierung eines rekonstitutiven Systems erlaubte eine detaillierte biochemische Charakterisierung des SMN-Komplexes. Es konnte gezeigt werden, dass der rekombinante Komplex alle f{\"u}r die Biogenese von U snRNPs n{\"o}tigen Schritte bewerkstelligen konnte. Dies schließt sowohl die {\"U}bernahme der Sm-Proteine aus den pICln-Intermediaten als auch das Verdr{\"a}ngen des Chaperons pICln und die {\"U}bertragung der Sm-Proteine auf die snRNAs ein. 3) Durch die Reduzierung des SMN-Gesamtkomplexes um Gemin3-5 auf einen SMN-Pentamer konnte dieser als ein funktioneller Kernbereich identifiziert werden, der die einzelnen Schritte der U snRNP-Biogenese vergleichbar mit dem gesamten Komplex bewerkstelligen konnte. Zudem agierte dieser reduzierte Komplex als notwendiger und ausreichender Spezifit{\"a}tsfaktor der RNP-Zusammenlagerung. 4) Das rekombinante System erm{\"o}glichte erstmals SMN-Komplexe mit SMA-pathogenen Mutationen herzustellen und einer eingehenden funktionellen und strukturellen Untersuchung zu unterziehen. Die detaillierte Analyse der SMA-verursachenden Punktmutation SMN(E134K) offenbarte spezifische Defekte im Zusammenlagerungsprozess und damit Einblicke in die Pathophysiologie der Krankheit. Mit der im Rahmen dieser Arbeit etablierten Rekonstitution des rekombinanten SMN-Komplexes wurde die Grundlage f{\"u}r die detaillierte biochemische und strukturbiologische Untersuchung der Zusammenlagerungsmaschinerie spleißosomaler U snRNPs gelegt. Dieses experimentelle System wird auch bei der Aufdeckung der biochemischen Defekte hilfreich sein, die zur neuromuskul{\"a}ren Krankheit SMA f{\"u}hren.}, subject = {Small nuclear RNP}, language = {de} }