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Umsetzungen N-heterocyclischer Carbene mit Boranen führen zur Bildung von „Lewis-Säure-Base-Addukten“. In Abhängigkeit des Substitutionsmusters der eingesetzten Borane bzw. Carbene eignen sich die erhaltenen Addukte als Ausgangsverbindungen zur Realisierung verschiedener Strukturmotive. Mit geeigneten Übergangsmetallfragmenten gelingt die Darstellung von sigma-Boran-Komplexen bzw. Basen-stabilisierter Boryl-Komplexe, welche mittels spektroskopischer Methoden sowohl im Festkörper, als auch in Lösung untersucht wurden. Ebenfalls gelingt die Synthese Basen-stabilisierter Borirane und einer tetraedrischen Borid-Spezies. Zudem wird ein selektiver Zugang zu Basen-stabilisierten Diborenen entwickelt, wobei deren Bindungssituation und Reaktivität im Detail diskutiert wird. So kann das B=B-Fragment in polymere Spezies eingebunden werden oder als Ligand an Übergangsmetalle koordinieren.
Im Rahmen der vorliegenden Arbeit wurde ein neuer Beschichtungstyp für die Elektrodenmaterialien von Lithium-Ionen-Akkumulatoren entwickelt und charakterisiert. Dieser besteht aus einem speziellen anorganisch-organischen Hybridpolymer, das sich bezüglich seiner Zusammensetzung und Funktion gegenüber bestehenden Beschichtungsmaterialien abhebt. Das anorganisch-organische Netzwerk des Hybridpolymers konnte mittels Feststoff-NMR-Messungen vollständig aufgeklärt werden. Dabei zeigte sich ein stabiles anorganisches Gerüst aus hoch vernetzten Polysiloxan-Einheiten. Zusätzliche organische Modifizierungen liegen als lange bewegliche Ketten mit funktionellen Polyethylenoxid-Einheiten vor oder sind in Form von Polyethern und Diolen vernetzt. Mit dieser speziellen Netzwerkstruktur ist es möglich, Materialeigenschaften zu erzeugen, die über solche von rein anorganischen und rein organischen Beschichtungen hinausgehen. Zu den mit verschiedenen Methoden nachgewiesenen Eigenschaften zählen eine hohe ionische Leitfähigkeit von 10\(^{-4}\) S/cm, eine hohe Elastizität mit E = 63 kPa, eine hohe elektrochemische Stabilität bis 5,0 V vs. Li/Li\(^+\) und eine hohe thermische Stabilität.
Eine weitere Besonderheit des neuen Beschichtungsmaterials ist die mehrstufige Vernetzung der anfänglichen Prekursoren zu einem Hybridpolymer-Sol und dem abschließenden Hybridpolymer-Gel. Die im Beschichtungssol vorliegende Teilvernetzung der Vorstufen konnte detailliert mittels Flüssig-NMR-Messungen untersucht und beschrieben werden. Aus den Messungen ließ sich folgern, dass die organisch und anorganisch vernetzbaren Gruppen im Sol teilweise vernetzt vorliegen. Die sterisch erreichbaren Si-OR-Gruppen der so entstandenen Oligomere sind vorwiegend nicht hydrolysiert, wodurch deren anorganische Anbindung an die OH-Gruppen der Partikeloberflächen kinetisch bevorzugt ist. Damit lassen sich besonders homogene und vollständig bedeckende Beschichtungen der Elektrodenmaterialien erzeugen. Dies konnte mit verschiedenen physikalischen und chemischen Methoden nachgewiesen werden: simulationsgestützte Rückstreuanalysen mittels REM, hochaufgelöste TEM-Aufnahmen sowie Elementanalysen durch EDX und XPS.
Nach der Optimierung des nasschemischen Beschichtungsprozesses über Rotationsverdampfen ergaben sich für die verschiedenen Elektrodenmaterialien Li\(_4\)Ti\(_5\)O\(_{12}\), Li(Ni,Co,Mn)O\(_2\) und Li(Mn,Ni)\(_2\)O\(_4\) jeweils etwa 20 nm dicke Beschichtungen mit Hybridpolymer. Die Frage nach deren Lösungsmittelbeständigkeit konnte durch die Analyse von behandelten Proben mit TG, REM, XPS und ICP-OES aufgeklärt werden. Dabei zeigte sich sowohl für die Behandlung mit NMP, dem klassischen Lösungsmittel bei der Elektrodenfertigung mit PVDF-Binder, als auch für die Behandlung mit dessen umweltschonenderem Ersatzstoff Aceton eine gute Beständigkeit der Beschichtung. Die Beschichtung löste sich in den Lösungsmitteln an, blieb allerdings als geschlossene nanoskalige Beschichtung erhalten. Lediglich gegenüber dem Lösungsmittel H\(_2\)O, das in Kombination mit dem neuen Binder CMC eingesetzt wird, wurde eine mangelnde Schichtstabilität deutlich. Das dafür verantwortliche Quellverhalten der Beschichtung konnte mittels Dünnschicht-Modellsystem und daran durchgeführten REM-, IR- und EPA-Untersuchungen aufgeklärt werden. Die Optimierung des Hybridpolymer-Materials bezüglich einer besseren H\(_2\)O-Beständigkeit übersteigt den Rahmen dieser Arbeit und liefert die Grundlage für weitere künftige Forschungsarbeiten.
Aufgrund der vollständigen Bedeckung der neuen Beschichtung, ihrer besonderen Eigenschaften und ihrer Beständigkeit bei der klassischen Elektrodenfertigung ist es möglich, die Elektrodenmaterialien grundlegend hinsichtlich ihrer wichtigsten Eigenschaften zu verbessern. Hierfür wurden sowohl über die NMP- als auch über die Aceton-Route Elektroden gefertigt und zu Halbzellen und Vollzellen verarbeitet. Die REM-Analyse der Elektroden zeigte, dass die Partikelbeschichtungen keinen negativen Einfluss auf die Homogenität und Morphologie der Elektroden ausüben. Damit war es möglich, jeweils einen direkten Vergleich von beschichteten und unbeschichteten Materialien hinsichtlich ihrer elektrochemischen Performance anzustellen. Für die Kathodenmaterialien Li(Ni,Co,Mn)O\(_2\) und Li(Mn,Ni)\(_2\)O\(_4\) ergaben die Zyklenfestigkeits- und Impedanzmessungen klare Verbesserungen durch die Beschichtung. Verbunden mit einer Verbesserung der Energiedichte erhöhte sich bei beiden Materialien die Zyklenfestigkeit um mehr als 60 %. Bei Li(Mn,Ni)\(_2\)O\(_4\) zeigt sich die Verbesserung in einer erhöhten Zellspannung durch das vergleichsweise hohe Redoxpotential des Materials von etwa 4,7 V vs. Li/Li\(^+\), während sich bei Li(Ni,Co,Mn)O\(_2\) die Hochvoltfähigkeit des Materials verbessert, was mit einer vergrößerten Speicherkapazität verbunden ist. Dabei ist herauszustellen, dass für keines der Materialien ein negativer Einfluss der dünnen Beschichtung auf die Leistungsdichte festgestellt werden konnte.
Der erwartete Mechanismus für die verbesserte Elektrodenfunktion durch das Hybridpolymer ist die Bildung einer physikalischen Schutzschicht in Form einer Li\(^+\)-leitfähigen Membran. Diese umgibt das Elektrodenmaterial vollständig, ermöglicht die Ladungsträgerinterkalation und schützt die Elektrode gleichzeitig vor irreversiblen Reaktionen mit dem Elektrolyten. Damit verbunden ist eine verminderte Mn-Auslösung und eine verminderte Entwicklung von isolierenden Deckschichten aus Reaktionsprodukten wie LiF, Li\(_2\)O, Li\(_2\)CO\(_3\), was sich positiv auf die Alterung der Batteriezellen auswirkt. Die Funktion der Beschichtung wurde primär auf den Kathodenmaterialien demonstriert. Doch auch auf der Anodenseite wurde ihre Anwendungstauglichkeit aufgezeigt, was das große Potential der Beschichtung für eine breite Anwendung in Lithium-Ionen-Batterien verdeutlicht.
In der vorliegenden Arbeit wurden Untersuchungen an Rückständen von thermisch abgebauten, flammgeschützten Polymeren vorgenommen, mit dem Ziel, die Struktur und den Phasenbestand der eingebauten Flammschutzmittel und der Polymere sowie deren Wechselwirkungen als Funktion der Temperatur und umgebenden Atmosphäre (N2 und Luft) zu charakterisieren. Ein wichtiges Werkzeug, das Informationen über den amorphen Zustand der Abbauprodukte und deren thermisch bedingte Phasenumwandlungen in andere amorphe oder kristalline Strukturen sowie Aussagen über die Nahordnungen der betrachteten Kernspinsorte liefert, stellt in dieser Arbeit der Einsatz der Festkörper-NMR-Spektroskopie dar. Hierbei sind neben Einzelimpuls- (SP), rotor-synchronisierte Spin-Echo- (RSE) und Kreuzpolarisationstechniken (CP) auch REDOR- (Rotational echo double resonance) und TRAPDOR- (Transfer of population in double resonance) Messungen zur Anwendung gekommen. Zusätzlich konnten aus den 11B- und 31P-NMR-Experimenten quantitative Aussagen über den relativen Borat- und Phosphor bzw. Phosphat-Anteil im festen Rückstand getroffen werden, wobei insbesondere für die 31P-Kerne eine quantitative Erfassung der kristallinen und amorphen Phosphatphasen durchgeführt wurde. Im ersten System wurden die Flammschutzmittel roter Phosphor (Prot) und Mg(OH)2 in HIPS kombiniert. Aus den Ergebnissen umfangreicher NMR-Experimente konnte abgeleitet werden, dass der größte Teil des eingesetzten Prot hauptsächlich in amorphen (Mg-Ortho-, -Di-, -Ketten- und Ringphosphaten) und weniger in kristallinen Phosphatphasen verbleibt. Zudem konnte für den Parameter der Temperatur und aus der Verfügbarkeit von Sauerstoff (N2-Atmosphäre/Luft) einen deutlicher Einfluss auf den Abbauprozess und die Bildung der Phosphatphasen (kristallin/amorph) nachgewiesen werden. Aus dem Vergleich der Ergebnisse der Temperversuche mit den Ergebnissen der Verbrennungsversuche im Cone Calorimeter konnte ein anaerober Abbauweg bestätigt werden. In einem zweiten System wurden die thermischen Reaktionen zwischen den Flammschutzadditiven BDP und Zinkborat sowie ihren Einfluss auf den thermischen Abbau eines PC/ABS-Blends untersucht. Der thermisch belastete Rückstand wird unabhängig von der Atmosphäre von amorphen Phosphatgruppen dominiert. Dabei konnten die während der Temperprozesse gebildeten Verbindungen α Zn3(PO4)2 und BPO4 als Folge einer Festphasenreaktion zwischen den eingesetzten Flammschutzadditiven identifiziert werden, wobei das α Zn3(PO4)2/BPO4 Verhältnis als Indikator für einen aeroben bzw. anaeroben Abbauprozess dient, der für die Feuerrückstände eindeutig einen anaeroben Abbau liefert.
Serum half-life elongation as well as the immobilization of small proteins like cytokines is still one of the key challenges for biologics. This accounts also for cytokines, which often have a molecular weight between 5 and 40 kDa and are therefore prone to elimination by renal filtration and sinusoidal lining cells. To solve this problem biologics are often conjugated to poly(ethylene glycol) (PEG), which is the gold standard for the so called PEGylation. PEG is a synthetic, non-biodegradable polymer for increasing the hydrodynamic radius of the conjugated protein to modulate their pharmacokinetic performance and prolong their therapeutic outcome. Though the benefits of PEGylation are significant, they also come with a prize, which is a loss in bioactivity due to steric hindrance and most often the usage of heterogeneous bioconjugation chemistries. While PEG is a safe excipient in most cases, an increasing number of PEG related side-effects, such as immunological responses like hypersensitivity and accelerated blood clearance upon repetitive exposure occur, which highlights the need for PEG alternative polymers, that can replace PEG in such cases.
Another promising method to significantly prolong the residence time of biologics is to immobilize them at a desired location. To achieve this, the transglutaminase (TG) Factor XIIIa (FXIIIa), which is an important human enzyme during blood coagulation can be used. FXIIIa can recognize specific peptide sequences that contain a lysine as substrates and link them covalently to another peptide sequence, that contains a glutamine, forming an isopeptide bond. This mechanism can be used to link modified proteins, which have a N- or C-terminal incorporated signal peptide by mutation, to the extracellular matrix (ECM) of tissues.
Additionally, both above-described methods can be combined. By artificially introducing a TG recognition sequence, it is possible to attach an azide group containing peptide site-specifically to the TG, recognition sequence. This allows the creation of a site-selective reactive site at the proteins N- or C-terminus, which can then be targeted by cyclooctyne functionalized polymers, just like amber codon functionalized proteins.
This thesis has focused on the two cytokines human Interferon-α2a (IFN-α2a) and human, as well as murine Interleukin-4 (IL-4) as model proteins to investigate the above-described challenges. IFN-α2a has been chosen as a model protein because it is an approved drug since 1986 in systemic applications against some viral infections, as well as several types of cancer. Furthermore, IFN-α2 is also approved in three PEGylated forms, which have different molecular weights and use different conjugation techniques for polymer attachment. This turns it into an ideal candidate to compare new polymers against the gold standard PEG. Interleukin-4 (IL-4) has been chosen as the second model protein due to its similar size and biopotency. This allows to compare found trends from IFN-α2a with another bioconjugate platform and distinguish between IFN-α2a specific, or general trends. Furthermore, IL-4 is a promising candidate for clinical applications as it is a potent anti-inflammatory protein, which polarizes macrophages from the pro-inflammatory M1 state into the anti-inflammatory M2 state.
This thesis concerned the design and examination of a scaffold for tissue engineering applications. The template for the presented scaffold came from nature itself: the intercellular space in tissues that provides structure and support to the cells of the respective tissue, known as extracellular matrix (ECM). Fibres are a predominant characteristic feature of ECM, providing adhesion sites for cell-matrix interactions. In this dissertation a fibrous mesh was generated using the electrospinning technique to mimic the fibrous structure of the ECM. Two base polymers were explored: a biodegradable polyester, poly(D,L-lactide-co-glycolide); and a functional PEG-based star polymer, NCO-sP(EO-stat-PO). This topic was described in three major parts: the first part was materials based, concerning the chemical design and characterisation of the polymer scaffolds; the focus was then shifted to the cellular response to this fibrous scaffold; and finally the in vivo performance of the material was preliminarily assessed. The first steps towards an electrospun mesh started with adjusting the spinning parameters for the generation of homogeneous fibres. As reported in Chapter 3 a suitable setup configuration was on the one hand comprised of a spinning solution that consisted of 28.5 w/v% PLGA RG 504 and 6 w/v% NCO-sP(EO-stat-PO) in 450 µL acetone, 50 µL DMSO and 10 µL of an aqueous trifluoroacetic acid solution. On the other hand an ideal spinning behaviour was achieved at process parameters such as a flow rate of 0.5 mL/h, spinneret to collector distance of 12-16 cm and a voltage of 13 kV. The NCO-sP(EO-stat-PO) containing fibres proved to be highly hydrophilic as the functional additive was present on the fibre surface. Furthermore, the fibres featured a bulk degradation pattern as a consequence of the proportion of PLGA. Besides the morphologic similarity to ECM fibres, the functionality of the electrospun fibres is also decisive for a successful ECM mimicry. In Chapter 4, the passive as well as active functionality of the fibres was investigated. The fibres were required to be protein repellent to prevent an unspecific cell adhesion. This was proven as even 6.5 % sP(EO-stat-PO) in the PLGA fibres reduced any unspecific protein adsorption of bovine serum albumin and foetal calf serum to less than 1 %. However, avidin based proteins attached to the fibres. This adhesion process was avoided by an additional fibre surface treatment with glycidol. The active functionalisation of NCO-sP(EO-stat-PO)/PLGA fibres was investigated with two fluorescent dyes and biocytin. A threefold, chemically orthogonal, fibre modification was achieved with these dyes. The chapters about the chemical and mechanical properties laid the basis for the in vitro chapters where a specific fibre functionalisation with peptides was conducted to analyse the cell adhesion and biochemical expressions. Beginning with fibroblasts in Chapter 5 the focus was on the specific cell adhesion on the electrospun fibres. While NCO-sP(EO-stat-PO)/PLGA fibres without peptides did not allow any adhesion of fibroblasts, a fibre modification with GRGDS (an adhesion mediating peptide sequence) induced the adhesion and spreading of human dermal fibroblasts on the fibrous scaffolds. The control sequence GRGES that has no adhesion mediating qualities did not lead to any cell adhesion as observed on fibres without modifications. While the experiments of Chapter 5 were a proof-of-concept, in Chapter 6 a possible application in cartilage tissue engineering was examined. Therefore, primary human chondrocytes were seeded on fibrous scaffolds with various peptide sequences. Though the chondrocytes exhibited high viability on all scaffolds, an active interaction of cells and fibres was only found for the decorin derived sequence CGKLER. Live-cell-imaging revealed both cell attachment and migration within CGKLER-modified meshes. As chondrocytes undergo a de-differentiation towards a fibroblast-like phenotype, the chondrogenic re-differentiation on these scaffolds was investigated in a long term cell culture experiment of 28 days. Therefore, the glycosaminoglycan production was analysed as well as the mRNA expression of genes coding for collagen I and II, aggrecan and proteoglycan 4. In general only low amounts of the chondrogenic markers were measured, suggesting no chondrogenic differentiation. For conclusive evidence follow-up experiments are required that support or reject the findings. The success of an implant for tissue engineering relies not only on the response of the targeted cell type but also on the immune reaction caused by leukocytes. Hence, Chapter 7 dealt with primary human macrophages and their behaviour and phenotype on two-dimensional (2D) surfaces compared to three-dimensional (3D) fibrous substrates. It was found that the general non-adhesiveness of NCO-sP(EO-stat-PO) surfaces and fibres does not apply to macrophages. The cells aligned along the fibres on surfaces or resided in the pores of the meshes. On flat surfaces without 3D structure the macrophages showed a retarded adhesion kinetic accompanied with a high migratory activity indicating their search for a topographical feature to adhere to. Moreover, a detailed investigation of cell surface markers and chemokine signalling revealed that macrophages on 2D surfaces exhibited surface markers indicating a healing phenotype while the chemokine release suggested a pro-inflammatory phenotype. Interestingly, the opposite situation was found on 3D fibrous substrates with pro-inflammatory surface markers and pro-angiogenic cytokine release. As the immune response largely depends on cellular communication, it was concluded that the NCO-sP(EO-stat-PO)/PLGA fibres induce an adequate immune response with promising prospects to be used in a scaffold for tissue engineering. The final chapter of this thesis reports on a first in vivo study conducted with the presented electrospun fibres. Here, the fibres were combined with a polypropylene mesh for the treatment of diaphragmatic hernias in a rabbit model. Two scaffold series were described that differed in the overall surface morphology: while the fibres of Series A were incorporated into a thick gel of NCO-sP(EO-stat-PO), the scaffolds of Series B featured only a thin hydrogel layer so that the overall fibrous structure could be retained. After four months in vivo the treated defects of the diaphragm were significantly smaller and filled mainly with scar tissue. Thick granulomas occurred on scaffolds of Series A while the implants of Series B did not induce any granuloma formation. As a consequence of the generally positive outcome of this study, the constructs were enhanced with a drug release system in a follow-up project. The incorporated drug was the MMP-inhibitor Ilomastat which is intended to reduce the formation of scar tissue. In conclusion, the simple and straight forward fabrication, the threefold functionalisation possibility and general versatile applicability makes the meshes of NCO-sP(EO-stat-PO)/PLGA fibres a promising candidate to be applied in tissue engineering scaffolds in the future.
This thesis identifies how the printing conditions for a high-resolution additive manufacturing technique, melt electrowriting (MEW), needs to be adjusted to process electroactive polymers (EAPs) into microfibers. Using EAPs based on poly(vinylidene difluoride) (PVDF), their ability to be MEW-processed is studied and expands the list of processable materials for this technology.
Polymer-Biokonjugationen, vornehmlich mit dem Goldstandard PEG, führen zu einer verbesserten Pharmakokinetik, beeinflussen aber auch die konformative Stabilität von Proteinen. Bisherige Mutationsstudien, in denen überwiegend (Asn)PEG4 -Konjugate der Beta-faltblattstrukturreichen, humanen Pin 1 WW-Domäne untersucht wurden, postulieren auf einer Proteindesolvatation beruhende Stabilisierungsmechanismen: eine Stärkung intramolekularer Salzbrücken und NH-pi-Bindungen, sowie entropisch günstige Wasserverdrängungen um apolare Aminosäuren und Hydroxylgruppen. Ziel dieser Arbeit ist es, die Protein-Polymer-Dynamik auf molekularer Ebene zu charakterisieren, um damit rationale Ansätze zum Design neuer Biokonjugate voranzutreiben und mögliche PEG-Alternativen zu etablieren. Hierzu wurde eine Vielzahl an Deskriptoren mittels Molekulardynamik-Simulationen der WW-Konjugate gewonnen und mit publizierten Stabilitätsdaten in multivariaten Regressions- und logistischen Klassifikationsmodellen korreliert. Die gewonnenen QSPR-Modelle decken im Vergleich zu einer bereits publizierten, kristallstrukturbasierten Richtlinie einen größeren und strukturell vielfältigeren Datensatz an Konjugaten ab und zeigen gleichzeitig, auch für ein Konjugat der Src SH3-Domäne, eine deutlich verbesserte Leistung. Die Modelldeskriptoren beschreiben sowohl eine Modulation der Solvatation als auch Protein-Polymer-Interaktionen. Metadynamik-Simulationen zeigten zudem die Polymerdynamik während einer partiellen Proteinentfaltung auf. Mithilfe weiterer Simulationen von Konjugaten des alpha-helikalen Her2-Affibodys wurde die Dynamik von PEG und verschiedener Alternativen (LPG, PEtOx, PMeOx) systematisch studiert. PEG interagierte mit positiv geladenen Lysinen und Argininen in der Nähe hydrophober Aminosäuren. LPG zeigte zusätzliche Wechselwirkungen der Hydroxylgruppen mit Aspartaten und Glutamaten. POx-Polymere interagierten mit Phenylalaninen, Tyrosinen und über Carbonylgruppen mit HB-Donatoren. Größere Konjugate (10 - 50 kDa PEG/LPG/PEtOx) des antiviralen Biologikums Interferon-alpha2a wurden mittels gaußbeschleunigter MDs und einer CG-Simulation analysiert. Charakteristische Wechselwirkungspartner stimmten mit den Beobachtungen zu Oligomer-Konjugaten überein. In Einklang mit experimentellen Daten der Kooperationspartner zu den 10-kDa-Varianten deuteten zusätzliche Constrained-Network-Analysen, welche die Proteinflexibilität evaluieren, auf eine thermische Destabilisierung hin. Die Bioaktivität der untersuchten Konjugate wurde weiterhin erfolgreich mit den Gyrationsdurchmessern der modellierten Strukturen korreliert.
Intraperitoneal adhesions are fibrous bands that connect tissues in the peritoneal cavity that are usually separated. These adhesions form as a consequence of trauma, inflammation or surgical interventions and often result in severe consequences such as chronic pain, small bowel obstructions or female infertility.
The aim of this thesis was to develop a synthetic barrier device for adhesion prevention made of modified poly(lactide) [PLA]. Solid PLA films (SurgiWrap®) are already successfully in clinical use due to the good biocompatibility and the biodegradability of the material resulting in non-toxic degradation products since lactic acid is naturally part of the metabolic circles of the human body. Considering the brittleness and stiffness of the films, the long degradation time of several months as well as the need for suturing, there is potential for optimization. Through a copolymerization with the hydrophilic poly(ethylene glycol) [PEG], a reduction of the degradation time was intendend. Moreover, the copolymerization should also lead to an improvement of the mechanical properties of the films since PEG acts as plasticizer for PLA. Linear PLA-PEG-PLA triblock copolymers as well as star-shaped PEG-PLA copolymers were synthesized via standard ring opening polymerization to tailor the barrier properties. Besides solid films, solution electrospun meshes from PLA and the synthesized PEG-PLA copolymers were investigated for a potential application as well. Since suturing of a barrier additionally induces adhesion formation, alginate coated membranes were prepared in order to achieve self-adhesiveness. With the intention to reduce infections and consequently inflammation, electrospun meshes and solvent cast films were loaded with the antibacterial drug triclosan and drug release as well as antibacterial efficacy was investigated.
Mechanical tests confirmed that through the variation of the PEG content and branching the mechanical properties can be tailored and are in good accordance with the glass transition temperatures [Tg] of the polymers. Consequently, potentially adequate mechanical properties for surgical handling as well as for the performance within the patient’s body were successfully achieved. Degradation studies revealed that the degradation time was significantly shorter for PEG-PLA membranes than for PLA films and with an appropriate PEG content could be adjusted to the intended time frame. Cell adhesion and viability tests confirmed the non-toxicity of the clinically used PLA films as well as of PEG-PLA films and meshes. With a bioadhesion test the benefit of an alginate coated side towards the pure PLA film concerning self-adhesiveness was successfully demonstrated. Moreover, optical evaluations and a T-peel test of different alginate coated PLA films showed that the cohesion between the chemically different layers was distinctly enhanced by the use of an appropriate PEG-PLA mesh as intermediate cohesion promoting layer. In in vitro release studies with triclosan loaded films a higher release was determined for PEG-PLA than for PLA films. In agar diffusion tests a higher and longer inhibition of staphylococcus aureus growth was observed confirming the release results. Moreover, drug loaded meshes (especially drug loaded after electrospinning) showed enhanced and elongated bacterial inhibition in comparison to films.
Thermoplastische Kunststoffe (sog. Thermoplaste) lassen sich in einem be-stimmten Temperaturbereich beliebig oft schmelzen und in einer gewünschten Form erstarren. Grundvoraussetzung für eine bestimmte Anwendung eines thermoplastischen Bauteils sind die Gebrauchseigenschaften des Materials, die im Wesentlichen vom Ablauf der Erstarrung abhängen.
Die Moleküle einiger Thermoplaste können bei der Erstarrung geordnete kristalline Bereiche bilden. Dies sind die sog. teilkristallinen Kunststoffe, deren Erstarrungsprozess Kristallisation genannt wird. Die dabei entstehenden Kristallstrukturen werden zusammen mit deren Charakteristiken allgemein als Morphologie der teilkristallinen Kunststoffe bezeichnet. Die Morphologie hat einen signifikanten Einfluss auf die mechanischen, thermischen und optischen Eigenschaften des Materials. Dementsprechend stellen Kenntnisse über die Kristallisation eine wertvolle Hilfe bei der Vorhersage der Gebrauchseigenschaften eines teilkristallinen Kunststoffs dar.
Um die Kristallisation zu starten, muss zunächst eine Energiebarriere überwunden werden, die an erster Stelle vom molekularen Aufbau des Kunststoffs abhängt. Somit weisen beispielsweise Kunststoffe mit linearen, regelmäßigen Molekülen und kleinen Seitengruppen eine niedrigere Energiebarriere und aus diesem Grund eine starke Neigung zur Kristallisation auf. Einige Zusatzstoffe wie z. B. unterschiedliche Additive, Farbstoffe oder Füllstoffe können die Energiebarriere und infolgedessen die Kristallisation eines teilkristallinen Kunststoffs wesentlich beeinflussen.
Das Ziel dieser Dissertation war es, ein bestehendes Kristallisationsmodell zu erweitern und es an gefüllte oder additivmodifizierte teilkristalline Kunststoffe anzupassen. Das erweiterte Modell soll die Ermittlung eines Kristallisationspa-rameters, des sog. Keimbildungsexponenten, eines gefüllten oder additivmodifizierten teilkristallinen Kunststoffs bei der nicht-isothermen Kristallisation ermöglichen. Der Keimbildungsexponent ist mit der erwähnten Energiebarriere eng verbunden und bestimmt somit den Ablauf des Kristallisationsprozesses bzw. die daraus folgende Morphologie. Ein wesentlicher Schwerpunkt der Arbeit lag darin, die vorgeschlagene Modellerweiterung bei verschiedenen Abkühlgeschwindigkeiten zu überprüfen. Im Anschluss sollten die Beziehungen zwischen den berechneten Keimbildungsexponenten und experimentell ermittelten me-chanischen Eigenschaften (E-Modul, Streckspannung und Schlagzähigkeit) überprüft werden. Für die Untersuchungen wurden drei verschiedene Polymersysteme verwendet: PP / Talkum, HDPE / Talkum sowie PA6 / Bentonit. Hierbei weist der Füllstoff eine stark positive, schwach positive bzw. inhibierende Wirkung auf die Kristallisation der entsprechenden Polymermatrix auf.
Hinsichtlich reiner Polymere wurde eine gute Übereinstimmung zwischen den ermittelten und Literaturwerten des Keimbildungsexponenten festgestellt. Die Zugabe von positiv wirkendem Talkum in PP bzw. HDPE führt zu einer Abnah-me des Keimbildungsexponenten, was zu dickeren Kristallen des jeweiligen Kunststoffs führte. Im Gegensatz dazu bewirkte die Bentonitzugabe einen zu-nehmenden Keimbildungsexponenten, was anschließend dünnere PA6-Kristalle zur Folge hat. Die durchgeführten Untersuchungen zeigen außerdem, dass die Füllstoffpartikelgröße einen ausgeprägten Einfluss auf den ermittelten Keimbildungsexponenten hat.
Weiterhin wurde festgestellt, dass der ermittelte Keimbildungsexponent durch die (DSC)-Abkühlgeschwindigkeit beeinflusst wird. Es wurde ferner gezeigt, dass sich dieser Einfluss ab einer bestimmten Abkühlgeschwindigkeit (20 K/min im Falle des PP und HDPE bzw. 15 K/min im Falle des PA6) nicht mehr ändert, was zu einem konstanten Keimbildungsexponenten führt. Um den Einfluss der Abkühlgeschwindigkeit auf die modellierte Größe zu berücksichtigen, sind weitere Untersuchungen nötig.
Die Ergebnisse der Arbeit zeigen weiterhin, dass der berechnete Keimbildungsexponent mit den experimentell ermittelten Werten für E-Modul, Streckspannung und Charpy-Schlagzähigkeit bei talkumgefülltem PP gut korreliert. Solche Korrelationen wurden jedoch bei den HDPE- und PA6-Proben nicht gefunden. Der Grund hierfür könnte eine ausgeprägte Orientierung der HDPE-Makromoleküle bzw. ein starker mikromechanischer Effekt des exfolierten Bentonits sein. Diese Effekte konnten im Rahmen der Arbeiten bestätigt werden.
Die in dieser Arbeit erzielten Ergebnisse zeigen, dass die vorgeschlagene Mo-dellerweiterung auch bei gefüllten oder additivmodifizierten Kunststoffen zufriedenstellende Resultate liefert. Die entsprechende Berechnung erfordert dabei lediglich eine DSC-Messung, was im Vergleich zum Stand der Technik in einen niedrigeren Messaufwand resultiert. Die vorliegende Arbeit liefert daher einen signifikanten Beitrag zur Erstellung des Zusammenhangs zwischen der Kristallisation, der Morphologie und dem mechanischen Verhalten von teilkristallinen Polymeren.
Silbernanodrähte (AgNW) wurden in verschiedene Hybridpolymere und in eine als Referenz dienende Silikonzusammensetzung eingebaut. Durch Spincoating konnten transparente leitfähige Filme erhalten werden. Deren jeweilige Nanodrahtverteilung, thermische Aktivierung und visuelle Transparenz wurden charakterisiert. Die Perkolationsschwelle der Filme hängt dabei von der individuellen durchschnittlichen AgNW-Länge ab. Eine beträchtliche Leitfähigkeit wurde während des mechanischen Streckens bis zu 30 % aufrechterhalten. Mikrostrukturierte Hybridpolymer-Verbundfilme wurden durch UV-Lithographie erhalten. ...
The aim of the thesis was to develop water soluble poly(2-oxazoline) (POx) copolymers with new side group functionalities, which can be used for the formation of hydrogels in biomedical applications and for the development of peptide-polymer conjugates.
First, random copolymers of the monomer MeOx or EtOx with ButEnOx and EtOx with DecEnOx were synthesized and characterized. The vinyl functionality brought into the copolymer by the monomers ButEnOx and DecEnOx would later serve for post-polymerization functionalization. The synthesized copolymers were further functionalized with thiols via post-polymerization functionalization using a newly developed synthesis protocol or with a protected catechol molecule for hydrogel formation. For the formation of peptide-polymer conjugates, a cyclic thioester, namely thiolactone acrylamide and an azlactone precursor, whose synthesis was newly developed, were attached to the side chain of P(EtOx-co-ButEnOx) copolymers.
The application of the functionalized thiol copolymers as hydrogels using thiol-ene chemistry for cross-linking was demonstrated. The swelling behavior and mechanical properties were characterized. The hydrophilicity of the network as well as the cross-linking density strongly influenced the swelling behavior and the mechanical strength of the hydrogels. All hydrogels showed good cell viability results.
The hydrogel networks based on MeOx and EtOx were loaded with two dyes, fluorescein and methylene blue. It was observed that the uptake of the more hydrophilic dye fluorescein depended more on the ability of the hydrogel to swell. In contrast, the uptake of the more hydrophobic dye methylene blue was less dependent on the swelling degree, but much more on the hydrophilicity of the network.
For the potential application as cartilage glue, (biohybrid) hydrogels were synthesized based on the catechol-functionalized copolymers, with and without additional fibrinogen, using sodium periodate as the oxidizing agent. The system allowed for degradation due to the incorporated ester linkages at the cross-linking points. The swelling behavior as well as the mechanical properties were characterized. As expected, hydrogels with higher degrees of cross-linking showed less swelling and higher elastic modulus. The addition of fibrinogen however increased the elasticity of the network, which can be favorable for the intended application as a cartilage glue. Biological evaluation clearly demonstrated the advantage of degradable ester links in the hydrogel network, where chondrocytes were able to bridge the artificial gap in contrast to hydrogels without any ester motifs.
Lastly, different ways to form peptide-polymer conjugates were presented. Peptides were attached with the thiol of the terminal cysteine group to the vinyl side chain of P(EtOx-co-ButEnOx) copolymers by radical thiol-ene chemistry. Another approach was to use a cyclic thioester, thiolactone, or an azlactone functionality to bind a model peptide via native chemical ligation. The two latter named strategies to bind peptides to POx side chains are especially interesting as one and in the case of thiolactone two free thiols are still present at the binding site after the reaction, which can, for example, be used for further thiol-ene cross-linking to form POx hydrogels.
In summary, side functional poly(oxazoline) copolymers show great potential for numerous biomedical applications. The various side chain functionalities can be introduced by an appropriate monomer or by post-polymerization functionalization, as demonstrated. By their multi-functionality, hydrogel characteristics, such as cross-linking degree and mechanical strength, can be fine-tuned and adjusted depending on the application in the human body. In addition, the presented chemoselective and orthogonal reaction strategies can be used in the future to synthesize polymer conjugates, which can, for example, be used in drug delivery or in tissue regeneration.
Motivated by the great potential which is offered by the combination of additive manufacturing and tissue engineering, a novel polymeric bioink platform based on poly(2 oxazoline)s was developed which might help to further advance the young and upcoming field of biofabrication. In the present thesis, the synthesis as well as the characteristics of several diblock copolymers consisting of POx and POzi have been investigated with a special focus on their suitability as bioinks.
In general, the copolymerization of 2-oxazolines and 2-oxazines bearing different alkyl side chains was demonstrated to yield polymers in good agreement with the degree of polymerization aimed for and moderate to low dispersities.
For every diblock copolymer synthesized during the present study, a more or less pronounced dependency of the dynamic viscosity on temperature could be demonstrated. Diblock copolymers comprising a hydrophilic PMeOx block and a thermoresponsive PnPrOzi block showed temperature induced gelation above a degree of polymerization of 50 and a polymer concentration of 20 wt%. Such a behavior has never been described before for copolymers solely consisting of poly(cyclic imino ether)s.
Physically cross linked hydrogels based on POx b POzi copolymers exhibit reverse thermal gelation properties like described for solutions of PNiPAAm and Pluronic F127. However, by applying SANS, DLS, and SLS it could be demonstrated that the underlying gel formation mechanism is different for POx b POzi based hydrogels. It appears that polymersomes with low polydispersity are formed already at very low polymer concentrations of 6 mg/L. Increasing the polymer concentration resulted in the formation of a bicontinuous sponge like structure which might be formed due to the merger of several vesicles. For longer polymer chains a phase transition into a gyroid structure was postulated and corresponds well with the observed rheological data.
Stable hydrogels with an unusually high mechanical strength (G’ ~ 4 kPa) have been formed above TGel which could be adjusted over a range of 20 °C by changing the degree of polymerization if maintaining the symmetric polymer architecture. Variations of the chain ends revealed only a minor influence on TGel whereas the influence of the solvent should not be neglected as shown by a comparison of cell culture medium and MilliQ water.
Rotationally as well as oscillatory rheological measurements revealed a high suitability for printing as POx b POzi based hydrogels exhibit strong shear thinning behavior in combination with outstanding recovery properties after high shear stress.
Cell viability assays (WST-1) of PMeOx b PnPrOzi copolymers against NIH 3T3 fibroblasts and HaCat cells indicated that the polymers were well tolerated by the cells as no dose-dependent cytotoxicity could be observed after 24 h at non-gelling concentrations up to 100 g/L.
In summary, copolymers consisting of POx and POzi significantly increased the accessible range of properties of POx based materials. In particular thermogelation of aqueous solutions of diblock copolymers comprising PMeOx and PnPrOzi was never described before for any copolymer consisting solely of POx or POzi. In combination with other characteristics, e.g. very good cytocompatibility at high polymer concentrations and comparably high mechanical strength, the formed hydrogels could be successfully used for 3D bioprinting. Although the results appear promising and the developed hydrogel is a serious bioink candidate, competition is tough and it remains an open question which system or systems will be used in the future.
Structure-property relationships in poly(2-oxazoline)/poly(2-oxazine) based drug formulations
(2020)
According to estimates, more than 40% of all new chemical entities developed in pharmaceutical industry are practically insoluble in water. Naturally, the demand for excipients which increase the water solubility and thus, the bioavailability of such hydrophobic drugs is enormous. Poly(2-oxazoline)s (POx) are currently intensively discussed as highly versatile class of biomaterials. Although selected POx based micellar drug formulations exhibit extraordinarily high drug loadings > 50 wt.% enabling high anti-tumor efficacies in vivo, the formulation of other hydrophobic compounds has failed. This casts doubt on the general understanding in which a hydrophobic active pharmaceutical ingredient is dissolved rather unspecifically in the hydrophobic core of the micelles following the fundamental concept of “like dissolves like”. Therefore, a closer look at the interactions between all components within a formulation becomes increasingly important. To do so, a large vehicle platform was synthesized, loaded with various hydrophobic drugs of different structure, and the formulations subsequently characterized with conventional and less conventional techniques. The obtained in-depth insights helped to develop a more thorough understanding about the interaction of polymer and incorporated API finally revealing morphologies deviating from a classical core/shell structure. During these studies, the scarcely investigated polymer class of poly(2-oxazine)s (POzi) was found as promising drug-delivery vehicle for hydrophobic drugs. Apart from this fundamental research, the anti-tumor efficacy of the two APIs curcumin and atorvastatin has been studied in more detail. To increase the scope of POx and POzi based formulations designed for intravenous administration, a curcumin loaded hydrogel was developed as injectable drug-depot.
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]
Several transition metal ions, like Fe2+, Co2+, Ni2+, and Zn2+ complex to the ditopic ligand 1,4-bis(2,2’:6’,2’’-terpyridin-4’-yl)benzene. Due to the high association constant, metal ion induced self-assembly of Fe2+, Co2+, and Ni2+ leads to extended, rigid-rod like metallo-supramolecular coordination polyelectrolytes (MEPEs) even in aqueous solution. Here, the kinetics of coordination and the kinetics of growth of MEPEs are presented. The species in solutions are analyzed by stopped-flow fluorescence spectroscopy, light scattering, viscometry and cryogenic transmission electron microscopy. At near-stoichiometric amounts of the reactants, high molar masses are obtained, which follow the order Ni-MEPE ~ Co-MEPE < Fe-MEPE. Furthermore, a way is presented to adjust the average molar mass, chain-length and viscosity of MEPEs using the monotopic chain stopper 4’-(phenyl)-2,2’:6’,2’’-terpyridine.
The aim of this thesis was the preparation of a biomaterial ink for the fabrication of chemically crosslinked hydrogel scaffolds with low micron sized features using melt electrowriting (MEW). By developing a functional polymeric material based on 2-alkyl-2-oxazine (Ozi) and 2-alkyl-2-oxazoline (Ox) homo- and copolymers in combination with Diels-Alder (DA)-based dynamic covalent chemistry, it was possible to achieve this goal. This marks an important step for the additive manufacturing technique melt electrowriting (MEW), as soft and hydrophilic structures become available for the first time. The use of dynamic covalent chemistry is a very elegant and efficient method for consolidating covalent crosslinking with melt processing. It was shown that the high chemical versatility of the Ox and Ozi chemistry offers great potential to control the processing parameters. The established platform offers straight forward potential for modification with biological cues and fluorescent markers. This is essential for advanced biological applications. The physical properties of the material are readily controlled and the potential for 4D-printing was highlighted as well. The developed hydrogel architectures are excellent candidates for 3D cell culture applications. In particular, the low internal strength of some of the scaffolds in combination with the tendency of such constructs to collapse into thin strings could be interesting for the cultivation of muscle or nerve cells. In this context it was also possible to show that MEW printed hydrogel scaffolds can withstand the aspiration and ejection through a cannula. This allows the application as scaffolds for the minimally invasive delivery of implants or functional tissue equivalent structures to various locations in the human body.
In order to shrink the size of semiconductor devices and improve their
efficiency at the same time, silicon-based semiconductor devices have
been engineered, until the material almost reaches its performance
limits. As the candidate to be used next in semiconducting devices,
single-wall carbon nanotubes show a great potential due to their
promise of increased device efficiency and their high charge carrier
mobilities in the nanometer size active areas. However, there are
material based problems to overcome in order to imply SWNTs in the
semiconductor devices. SWNTs tend to aggregate in bundles and it is
not trivial to obtain an electronically or chirally homogeneous SWNT
dispersion and when it is done, a homogeneous thin film needs to be
produced with a technique that is practical, easy and scalable. This
work was aimed to solve both of these problems.
In the first part of this study, six different polymers, containing
fluorene or carbazole as the rigid part and bipyridine, bithiophene or
biphenyl as the accompanying copolymer unit, were used to selectively
disperse semiconducting SWNTs. With the data obtained from
absorption and photoluminescence spectroscopy of the corresponding
dispersions, it was found out that the rigid part of the copolymer plays a
primary role in determining its dispersion efficiency and electronic
sorting ability. Within the two tested units, carbazole has a higher π
electron density. Due to increased π−π interactions, carbazole
containing copolymers have higher dispersion efficiency. However, the
electronic sorting ability of fluorene containing polymers is superior.
Chiral selection of the polymers in the dispersion is not directly
foreseeable from the selection of backbone units. At the end, obtaining a monochiral dispersion is found to be highly dependent on the used raw
material in combination to the preferred polymer.
Next, one of the best performing polymers due to high chirality
enrichment and electronic sorting ability was chosen in order to
disperse SWNTs. Thin films of varying thickness between 18 ± 5 to
755o±o5 nm were prepared using vacuum filtration wet transfer method
in order to analyze them optically and electronically.
The scalability and efficiency of the integrated thin film production
method were shown using optical, topographical and electronic
measurements. The relative photoluminescence quantum yield of the
radiative decay from the SWNT thin films was found to be constant for
the thickness scale. Constant roughness on the film surface and linearly
increasing concentration of SWNTs were also supporting the scalability
of this thin film production method. Electronic measurements on bottom
gate top contact transistors have shown an increasing charge carrier
mobility for linear and saturation regimes. This was caused by the
missing normalization of the mobility for the thickness of the active
layer. This emphasizes the importance of considering this dimension for
comparison of different field effect transistor mobilities.
In this work, the trap states in the conjugated polymer P3HT, often used as electron donor in organic bulk heterojunction solar cells, three commonly used fullerene based electron acceptors and P3HT:PC61BM blends were investigated. Furthermore, the trap states in the blend were compared with these of the pure materials. Concerning the lifetime of organic solar cells the influence of oxygen on P3HT and P3HT:PC61BM blends was studied. The experimental techniques used to investigate the trap states in the organic semiconductors were (fractional) thermally stimulated current (TSC) and current based deep level transient spectroscopy (Q-DLTS). Fractional TSC measurements on P3HT diodes revealed a quasi-continuous trap distribution. The distribution suggested two different traps in P3HT with approximately Gaussian energy distributions and maxima at about 50 meV and 105 meV. Thereby, the former was attributed to the tail states within the regular Gaussian density of states due to the low activation energy. The latter, deeper traps, however, exhibited a strong dependence on oxygen. Exposure of the P3HT diodes to oxygen, ambient air and synthetic (dry) air all revealed an increase of the deeper traps density with exposure time in the same manner. While the lower limit of the trap density in non aged P3HT samples was in the range of (1.0 − 1.2)×10^22 m^−3, it was more than doubled after an exposure of 50 h to air. An increase of the trap density with oxygen exposure time was also seen in the Q-DLTS measurements accompanied with an increase of the temperature dependence of the emission rates, indicating an enhanced formation of deeper traps. Due to the raise in density of the deeper traps, the charge carrier mobility in P3HT significantly decreased, as revealed by photo-CELIV measurements, resulting in a loss in mobility of about two orders of magnitude after 100 h exposure to synthetic air. The increased trap density was attributed to p-doping of P3HT by the transfer of an electron to adsorbed oxygen. This effect was partially reversible by applying vacuum to the sample for several hours or, more significantly, by a thermal treatment of the devices in nitrogen atmosphere. The trap states in the methanofullerenes PC61BM, bisPC61BM and PC71BM were investigated by TSC measurements. PC61BM yielded a broad quasi-continuous trap distribution with the maximum of the distribution at about 75 meV. The comparison of the TSC spectra of the three methanofullerenes exhibited significant differences in the trap states with higher activation energies of the most prominent traps in bisPC61BM and PC71BM compared to PC61BM. This probably originates from the different isomers bisPC61BM and PC71BM consist of. Each of the isomers yields different LUMO energies, where the lower ones can act as traps. The lower limit of the trap density of all of the three investigated fullerene derivatives exhibited values in the order of 10^22 m^−3, with the highest for bisPC61BM and the lowest for PC61BM. By applying fractional TSC measurements on P3HT:PC61BM solar cells, it was shown that the trap distribution in the blend is a superposition of the traps in pure P3HT and PC61BM and additional deeper traps in the range of about 250 meV to 400 meV. The origin of these additional traps, which can not be related to the pure materials, was attributed to a higher disorder in the blend and P3HT/PC61BM interfaces. This conclusion was supported by standard TSC and Q-DLTS measurements performed on pristine and annealed P3HT:PC61BM blends, exhibiting a higher ratio of the deep traps in the pristine samples. The lower limit of the trap density of the investigated annealed solar cells was in the range of (6−8)×10^22 m^−3, which was considerably higher than in the pure materials. The influence of oxygen on P3HT:PC61BM solar cells was investigated by exposure of the devices to synthetic air under specific conditions. Exposure of the solar cells to oxygen in the dark resulted in a strong decrease in the power conversion efficiency of 60 % within 120 h, which was only caused by a loss in short-circuit current. Simultaneous illumination of the solar cells during oxygen exposure strongly accelerated the degradation, resulting in an efficiency loss of 30 % within only 3 h. Thereby, short-circuit current, open-circuit voltage and fill factor all decreased in the same manner. TSC measurements revealed an increase of the density of deeper traps for both degradation conditions, which resulted in a decrease of the mobility, as investigated by CELIV measurements. However, these effects were less pronounced than in pure P3HT. Furthermore, an increase of the equilibrium charge carrier density with degradation time was observed, which was attributed to oxygen doping of P3HT. With the aid of macroscopic simulations, it was shown that the doping of the solar cells is the origin of the loss in short-circuit current for both degradation conditions.
Im Rahmen dieser Arbeit wurden Elektronentransferprozesse in Systemen, die auf Triphenylaminredoxzentren basieren, mit Hilfe spektroskopischer und elektrochemischer sowie spektroelektrochemischer Methoden studiert. Im ersten Teil der vorliegenden Arbeit wurden Bistriarylaminsysteme analog zu N,N,N’,N’-Tetra(4-methoxyphenyl)-1,4-phenylendiamin (1) untersucht, deren Radikalkationen eine für gemischtvalente Systeme typische breite und insbesondere bei 1 stark asymmetrische IVCT-Absorptionsbande zeigen. Die Analyse dieser Banden nach Hush sowie einem modifizierten Modell, das der Vibronic coupling-Theorie angelehnt ist, deutet auf die Abnahme der elektronischen Kopplung mit zunehmender Vergrößerung des zentralen Phenylenspacers durch Naphthalin- (2) bzw. Anthracenspacer (3) und damit größerer sterischer Hinderung hin. Gleichzeitig nimmt aber mit der Vergrößerung des -Systems des Spacers auch die Reorganisationsenergie  ab. Insgesamt verhalten sich alle drei Verbindungen sehr ähnlich, was insbesondere das Verhältnis von Absorptionsmaximum der IVCT-Bande zum zweifachen Wert der elektronischen Kopplung betrifft. Legt man vor allem das modifizierte Vibronic coupling-Modell zugrunde, so liegt dieses Verhältnis bei 1+, 2+ und 3+ sehr nahe bei 1, so daß alle drei Systeme sehr nahe am Übergang von Robin-Day-Klasse II zu Klasse III liegen. Weiterhin wurden über einen 1,4-Diethinylphenyl-Spacer verbrückte Bistriarylaminsysteme untersucht, bei denen durch Variation der Spacereinheit (1,4-Diethinylphenyl (5), 1,4-Diethinylnaphthalin (6), 1,4-Diethinyl-2,5-dimethoxyphenyl (10)) die Energie eines Brückenzustandes im Vergleich zu Zuständen, bei denen das Radikal an einem Triarylaminzentrum lokalisiert ist, schrittweise abgesenkt wird. Die auftretenden Elektronentransferprozesse können mit Hilfe eines Dreiniveaumodells mit zwei voneinander unabhängigen Elektronentransferkoordinaten beschrieben werden. Es zeigt sich, daß bei elektronenarmen Spacern, wie z.B. bei 5+, der Elektronentransfer nach einem Superexchange-Mechanismus erfolgt. Bei der Verwendung einer elektronenreichen Dimethoxy-substituierten Brücke wie in 10+ kann der Elektronentransfer neben dem Superexchange- auch nach einem Hopping-Mechanismus erfolgen. Bei Verbindungen, die einen 9,10-Diethinylanthracenspacer (8+ und 9+) enthalten, liegt der Brückenzustand energetisch sogar deutlich tiefer als der Zustand mit einem oxidierten Triphenylaminredoxzentrum. Im zweiten Abschnitt wurden gerichtete Elektronentransferprozesse an Redoxkaskaden und Dendrimeren, die auf Triarylaminredoxzentren basieren, studiert. Die Möglichkeit, die Redoxpotentiale von Triphenylaminzentren durch Substituenten zu beeinflussen, erlaubt die Synthese von Kaskaden mit einem vorgegebenen Redoxgradienten. Innerhalb einer Kaskade, die ein Acridin-Fluorophor, ein 4-Chlor-substituiertes sowie ein 4-Methoxy-substituiertes Triphenylaminredoxzentrum enthält (18), kann nach Anregung des Acridin-Chromophors in polaren Lösungsmitteln ein ladungsgetrennter Zustand erreicht werden, worauf sowohl statische und zeitaufgelöste Fluoreszenzmessungen als auch transientenspektroskopische Untersuchungen hinweisen. Die Lebensdauer kann durch Verlängerung der Redoxkaskade durch ein weiteres Aminzentrum deutlich vergrößert werden. In unpolaren Lösungsmitteln erfolgt dagegen keine Ladungstrennung über die gesamte Kaskade. Ebenso tritt bei 20 (Kaskade aus Acridin, 4 Methoxy-substituiertem Triphenylamin und 4-Chlor-substituiertem Aminzentrum), wo der Redoxgradient entgegen zu 18 gerichtet ist, kein Ladungstransfer auf. Im dritten Teil dieser Arbeit wurden Verbindungen untersucht, die neben 1,4 Phenylendiamineinheiten in para-Position unsubstituierte Triphenylamine enthalten und sich elektrochemisch polymerisieren lassen. Die Eigenschaften der dotierten redoxaktiven Polymere werden durch die enthaltenen p-Phenylendiamin- und Benzidin-Substrukturen dominiert, wofür hauptsächlich die geringe Wechselwirkung der einzelne Redoxzentren untereinander verantwortlich ist. Impedanzspektroskopische Untersuchungen zeigen eine Zunahme der Leitfähigkeit der dotierten Polymerfilme, wobei der Ladungstransfer vermutlich durch Hopping zwischen den p-Phenylendiamin- und Benzidinuntereinheiten erfolgt.