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Vom Monomer zum Polymer: Iterative Synthese und optische Spektroskopie von Squarain-Oligomeren
(2022)
Mittels einer Schutzgruppenstrategie wurden Squarain-basierte monodisperse Oligomere synthetisiert. Die lösungsmittelabhängigen Konformationen (Random Coil vs. Helix) wie auch der Faltungsprozess der Homooligomere wurden mittels optischer Spektroskopie, verschiedener NMR-Experimenten, Kleinwinkelneutronenstreuungsexperimenten sowie quantenchemischen Berechnungen näher beleuchtet. Die optisch-spektroskopischen Beobachtungen wurden mithilfe der Exzitonenkopplungstheorie und einer Orientierungs- und Winkelabhängigkeit der Übergangsdipolmomente der Oligomere erklärt. Der hohe Windungsabstand der helikalen Konformation führt zu einer Interkalation von Lösungsmittel, wodurch eine Art Klathrat gebildet wird. Zusätzlich wurden mittels eines Frenkel-Exzitonenmodells die Absorptions- und Fluoreszenzspektren modelliert. Es konnten die Exzitonendelokalisationslängen abgeschätzt und die Auswirkung der energetischen und strukturellen Unordnungen auf die Absorptions- und Fluoreszenzspektren bestimmt werden. Die Absorptionsspektren werden vorwiegend durch strukturelle Unordnungen verbreitert, die Fluoreszenzspektren dagegen von energetischen Übergangsenergieabweichungen.
Weiterhin wurden auch alternierende Squarain-Cooligomere synthetisiert und mittels optischer Spektroskopie untersucht. Es wurde, abhängig von dem gewählten Lösungsmittel, eine Verschiebung der Hauptbande beobachtet, was durch einen Random Coil vs. helikale-/schlaufenartige Konformation erklärt wird. Gestützt wurde dies mittels quantenchemischen Berechnungen der jeweiligen Konformationen.
Abschließend wurden alternierende Squarain-Copolymere synthetisiert, in verschiedenen Größen aufgetrennt und mittels optischer Spektroskopie untersucht. Mittels EEI2D-Experimenten wurde die Exzitonendynamik in Abhängigkeit von der Kettenlänge eingehender untersucht. Hierbei wird eine steigende, aber relativ abnehmende Kohärenzlänge bestimmt, die Auswirkungen auf die Exzitonendynamik hat. Der Exzitonentransport weist erst wellenförmiges und dann subdiffuses Verhalten auf.
Der Vernetzungsgrad von Klebstoffen und strahlenvernetzter Kunststoffformteile beeinflusst zahlreiche Materialeigenschaften und ist von essenzieller Bedeutung für die Funktionalität von Klebeverbindungen und die Beständigkeit medizinischer Implantate.
Die zerstörungsfreie Prüfung dieser Qualitätsgröße ist von großem industriellem Interesse, aber noch nicht Stand der Technik. Die unilaterale Kernspinresonanz (uNMR) ist ein vielversprechendes Verfahren zur Lösung dieser Problematik.
In diesem Buch wird die nicht-invasive Vernetzungsgradprüfung von strahlenvernetztem UHMWPE und verschiedenen Klebstoffen mittels uNMR demonstriert. Auf Basis der guten Korrelation mit praxisrelevanten Referenzmethoden (thermisch, rheologisch, dielektrisch) wurden Vergleichsmodelle entwickelt, welche Anwendern von Klebstoffen und vernetzten Kunststoffformteilen den Einsatz der uNMR zur zerstörungsfreien Qualitätssicherung ermöglichen.
Most medicines are taken orally. To enter the systemic circulation, they dissolve in the intestinal fluid, cross the epithelial barrier, and pass through the liver. Intestinal absorption is driven by the unique features of the gastrointestinal tract, including the bile colloids formed in the lumen and the mucus layer covering the intestinal epithelium. Neglecting this multifaceted environment can lead to poor drug development decisions, especially for poorly water-soluble drugs that interact with bile and mucus. However, there is a lack of a rationale nexus of molecular interactions between oral medicines and gastrointestinal components with drug bioavailability. Against this background, this thesis aims to develop biopharmaceutical strategies to optimize the presentation of oral therapeutics to the intestinal epithelial barrier.
In Chapter 1, the dynamics of bile colloids upon solubilization of the poorly-water soluble drug Perphenazine was studied. Perphenazine impacted molecular arrangement, structure, binding thermodynamics, and induced a morphological transition from vesicles to worm-like micelles. Despite these dynamics, the bile colloids ensured stable relative amounts of free drug substance. The chapter was published in Langmuir.
Chapter 2 examined the impact of pharmaceutical polymeric excipients on bile-mediated drug solubilization. Perphenazine and Imatinib were introduced as model compounds interacting with bile, whereas Metoprolol did not. Some polymers altered the arrangement and geometry of bile colloids, thereby affecting the molecularly soluble amount of those drugs interacting with bile. These insights into the bile-drug-excipient interplay provide a blueprint to optimizing formulations leveraging bile solubilization. The chapter was published in Journal of Controlled Release.
Chapter 3 deals with the impact of bile on porcine intestinal mucus. Mucus exposed to bile solution changed transiently, it stiffened, and the overall diffusion rate increased. The bile-induced changes eased the transport of the bile-interacting drug substance Fluphenazine, whereas Metoprolol was unaffected. This dichotomous pattern was linked to bioavailability in rats and generalized based on two previously published data sets. The outcomes point to a bile-mucus interaction relevant to drug delivery. The chapter is submitted.
The Appendix provides a guide for biopharmaceutical characterization of drug substances by nuclear magnetic resonance spectroscopy aiming at establishing a predictive algorithm.
In summary, this thesis deciphers bile-driven mechanisms shaping intestinal drug absorption. Based on these molecular insights, pharmaceuticals can be developed along a biopharmaceutical optimization, ultimately leading to better oral drugs of tomorrow.
The bile system in vertebrates is an evolutionary conserved endogenous solubilization system for hydrophobic fats and poorly water-soluble vitamins. Bile pours out from the gallbladder through the common bile duct into the duodenum triggered by cholecystokinin. Cholecystokinin is released from enteroendocrine cells after food intake. The small intestine is also the absorption site of many orally administered drugs. Most emerging drug candidates belong to the class of poorly water-soluble drugs (PWSDs). Like hydrophobic vitamins, these PWSDs might as well be solubilized by bile. Therefore, this natural system is of high interest for drug formulation strategies. Simulated intestinal fluids containing bile salts (e.g., taurocholate TC) and phospholipids (e.g., lecithin L) have been widely applied over the last decade to approximate the behavior of PWSDs in the intestine. Solubilization by bile can enhance the oral absorption of PWSDs being at least in part responsible for the positive “food effect”. The dissolution rate of PWSDs can be also enhanced by the presence of bile. Furthermore, some PWSDs profit from supersaturation stabilization by bile salts. Some excipients solubilizing PWSDs seemed to be promising candidates for drug formulation when investigated in vitro without bile. When tested in vivo, these excipients reduced the bioavailability of drugs. However, these observations have been hardly examined on a molecular level and general links between bile interaction in vitro and bioavailability are still missing.
This thesis investigated the interplay of bile, PWSDs, and excipients on a molecular level, providing formulation scientists a blueprint for rational formulation design taking bile/PWSD/excipient/ interaction into account. The first chapter focus on an in silico 1H nuclear magnetic resonance (NMR) spectroscopy-based algorithm for bile/drug interaction prediction. Chapter II to IV report the impact of excipients on bioavailability of PWSDs interacting with bile. At last, we summarized helpful in vitro methods for drug formulation excipient choice harnessing biopharmaceutic solubilization in chapter V.
Chapter I applies 1H NMR studies with bile and drugs on a large scale for quantitative structure-property relationship analysis. 141 drugs were tested in simulated intestinal media by 1H NMR. Drug aryl-proton signal shifts were correlated to in silico calculated molecular 2D descriptors. The probability of a drug interacting with bile was dependent on its polarizability and lipophilicity, whereas interaction with lipids in simulated intestinal media components was dependent on molecular symmetry, lipophilicity, hydrogen bond acceptor capability, and aromaticity. The probability of a drug to interact with bile was predictive for a positive food effect. This algorithm might help in the future to identify a bile and lipid interacting drug a priori.
Chapter II investigates the impact of excipients on bile and free drug fraction. Three different interaction patterns for excipients were observed. The first pattern defined excipients that interacted with bile and irreversibly bound bile. Therefore, the free drug fraction of bile interacting drugs increased. The second pattern categorized excipients that formed new colloidal entities with bile which had a high affinity to bile interacting drugs. These colloids trapped the drug and decreased the free drug fraction. The last excipient pattern described excipients that formed supramolecular structures in coexistence with bile and had no impact on the free drug fraction. These effects were only observed for drugs interacting with bile (Perphenazine and Imatinib). Metoprolol’s free drug fraction, a compound not interacting with bile, was unaffected by bile or bile/excipient interaction. We hypothesized that bile/excipient interactions may reduce the bioavailability of bile interacting drugs.
Chapter III addresses the hypothesis from chapter II. A pharmacokinetic study in rats revealed that the absorption of Perphenazine was reduced by bile interacting excipients due to bile/excipient interaction. The simultaneous administration of excipient patterns I and II did not further reduce or enhance Perphenazine absorption. Conversely, the absorption of Metoprolol was not impacted by excipients. This reinforced the hypothesis, that drugs interacting with bile should not be formulated with excipients also interacting with bile.
Chapter IV further elaborates which in vitro methods using simulated intestinal fluids are predictive for a drug’s pharmacokinetic profile. The PWSD Naporafenib was analyzed in vitro with simulated intestinal fluids and in presence of excipients regarding solubility, supersaturation, and free drug fraction. Naporafenib showed a strong interaction with TC/L from simulated bile. Assays with TC/L, but not without identified one excipient as possibly bioavailability reducing, one as supersaturation destabilizing, and the last as bile not interacting and supersaturation stabilizing excipient. A pharmacokinetic study in beagle dogs outlined and confirmed the in vitro predictions.
The Appendix summarizes in vivo predictive methods as presented in chapter I to IV and rationalizes experimental design paving the way towards a biopharmaceutic excipient screening. The first presented preliminary decision tree is transformed into a step-by-step instruction. The presented decision matrix might serve as a blueprint for processes in early phase drug formulation development.
In summary, this thesis describes how a drug can be defined as bile interacting or non-interacting and gives a guide as well how to rate the impact of excipients on bile. We showed in two in vivo studies that bile/excipient interaction reduced the bioavailability of bile interacting drugs, while bile non-interacting drugs were not affected. We pointed out that the bile solubilization system must be incorporated during drug formulation design. Simulated gastrointestinal fluids offer a well-established platform studying the fate of drugs and excipients in vivo. Therefore, rational implementation of biopharmaceutic drug and excipient screening steers towards efficacy of oral PWSD formulation design.
Durch stetige Entwicklung der Mikroskopiemethoden in den letzten Jahrzehnten ist es nun möglich Strukturen und Abläufe in biologischen Systemen detaillierter darzustellen als mit der von Abbe entdeckten maximalen Auflösungsgrenze. Oft werden dabei Fluoreszenzmarker benutzt, welche die unsichtbare Welt der Mikrobiologie und deren biochemische Prozesse illuminieren. Diese werden entweder durch Expression, wie z.B. das grün fluoreszierende Protein (GFP), in das zu untersuchende Objekt eingebracht oder durch klassische Markierungsmethoden mithilfe von fluoreszierenden Immunkonjugaten installiert. Jedoch gewinnt eine alternative Strategie, die von der interdisziplinären Zusammenarbeit zwischen Chemikern, Physikern und Biologen profitiert, immer mehr an Bedeutung – die bioorthogonale Click-Chemie. Sie ermöglicht eine effiziente Fluoreszenzmarkierung der biologischen Strukturen unter minimalem Eingriff in die Abläufe der Zelle. Dazu müssen allerdings sowohl Farbstoffe als auch die biologisch aktiven Substanzen chemisch modifiziert werden, da nur dadurch die Bioorthogonalität gewährleistet werden kann.
Mittlerweile existiert eine breite Palette an fluoreszierenden Farbstoffen, die das komplette sichtbare Spektrum abdecken und sich für diverse Mikroskopiemethoden eignen. Allerdings gibt es zwei Farbstoffklassen, die sich aus der gesamten Fülle abheben und sich für hochauflösende bildgebende Experimente auf Einzelmolekülebene eignen. Zum einen ist es die Farbstofffamilie der Cyanine und insbesondere der wasserlöslichen Pentamethincyanine, die reversibel und kontrolliert zum Photoschalten animiert werden können und in der stochastisch optischen Rekonstruktionsmikroskopie Anwendung finden. Zum anderen ist es die Gruppe, der Rhodamine und Fluoresceine, die zu Xanthenfarbstoffen gehören und sich durch gute photophysikalische Eigenschaften auszeichnen.
Trotz der Beliebtheit stellt ihre Darstellung immer noch eine Herausforderung dar und limitiert deren Einsatz. Deshalb war es notwendig im Rahmen der vorliegenden Arbeit Möglichkeiten zur Syntheseoptimierung beider Farbstoffklassen zu finden, damit diese im Folgenden weiterentwickelt und an die biologische Fragestellung angepasst werden können. Die Arbeit unterteilt sich deshalb in Relation an die oben genannten Farbstoffklassen in zwei Bereiche. Im ersten Teil wurden Projekte basierend auf den wasserlöslichen Pentamethincyaninen behandelt. Im zweiten Teil beschäftigte sich die Arbeit mit Projekten, die auf Xanthen-Farbstoffen aufbauen.
In the past decade, poly(2-oxazoline)s (POx) and very recently poly(2-oxazine)s (POzi) based amphiphiles have shown great potential for medical applications. Therefore, the major aim of this thesis was to further explore the pharmaceutical and biomedical applications of POx/POzi based ABA triblock and AB diblock copolymers, respectively with the special emphasis on structure property relationship (SPR). ABA triblock copolymers (with shorter side chain length in the hydrophobic block) have shown high solubilizing capacity for hydrophobic drugs. The issue of poor aqueous solubility was initially addressed by developing a (micellar) formulation library of 21 highly diverse, hydrophobic drugs with POx/POzi based ABA triblock copolymers. Theoretically, the extent of compatibility between polymers and drug was determined by calculating solubility parameters (SPs). The SPs were thoroughly investigated to check their applicability in present systems. The selected formulations were further characterized by various physico-chemical techniques. For the biomedical applications, a novel thermoresposive diblock copolymer was synthesized which has shown promising properties to be used as hydrogel bioink or can potentially be used as fugitive support material. The most important aspect i.e. SPR, was studied with respect to hydrophilic block in either tri- or di-block copolymers. In triblock copolymer, the hydrophilic block played an important role for ultra high drug loading, while in case of diblock, it has improved the printability of the hydrogels. Apart from the basic research, the therapeutic applications of two formulations i.e. mitotane (commercially available as tablet dosage form for adrenocortical carcinoma) and BT-44 (lead compound for nerve regeneration) were studied in more detail.
Paclitaxel (PTX) is one of the leading drugs against breast and ovarian cancer. Due to its low solubility, treatment of the patients with this drug requires a very well-suited combination with a soluble pharmaceutical excipient to increase the bioavailability and reduce the strong side ef-fects. One efficient way to achieve this in the future could be the incorporation of PTX into pol-ymeric micelles composed of poly(2-oxazoline) based triblock copolymers (POL) which ena-bles PTX loadings of up to 50 wt.%. However, structural information at an atomic level and thus the knowledge of interaction sites within these promising but complex PTX-POL formula-tions were not yet available. Such results could support the future development of improved excipients for PTX and suitable excipients for other pharmaceutical drugs. Therefore, a solid-state MAS NMR investigation of these amorphous formulations with different POL-PTX com-positions was performed in this thesis as this gives insights of the local structure at an atomic level in its solid state. NMR in solution showed very broad 13C signals of PTX for this system due to the reduced mobility of the incorporated drug which exclude this as an analytical meth-od.
In a first study, crystalline PTX was structurally characterized by solid-state NMR as no com-plete 13C spectrum assignment and no 1H NMR data existed for the solid state. In addition, the asymmetric unit of the PTX crystal structure consists of two molecules (Z'=2) that can only be investigated in its solid state. As crystalline PTX in total has about 100 different 13C and 1H chemical shifts with very small differences due to Z’=2, and furthermore, its unit cell consisting of more than 900 atoms, accompanying GIPAW (CASTEP) calculations were required for NMR signal assignments. These calculations were performed using the first three available purely hydrous and anhydrous PTX structures, which were determined by XRD and published by Vel-la-Zarb et al. in 2013. Within this thesis, is was discovered that two investigated batches of commercially available PTX from the same supplier both contained an identical and so far un-known PTX phase that was elucidated by PXRD as well as solid-state NMR data. One of the two batches consists of an additional phase that was shown to be very similar to a known hy-drated phase published in 2013.[1] By heating the batch with the mixture of the two phases un-der vacuum, it is transformed completely to the new dry phase occurring in both PTX batches. Since the drying conditions to obtain anhydrous PTX in-situ on the PXRD setup described by Vella-Zarb et. al.[1] were much softer than ours, we identify our dry phase as a relaxed version of their published anhydrate structure. The PXRD data of the new anhydrate phase was trans-ferred into a new structural model, which currently undergoes geometry optimization. Based on solid-state NMR data at MAS spinning frequencies up to 100 kHz, a 13C and a partial 1H signal assignment for the new anhydrous structure were achieved. These results provided sufficient structural information for further investigations of the micellar POL-PTX system.
In a second study, the applicability and benefit of two-dimensional solid-state 14N-1H HMQC MAS NMR spectra for the characterization of amorphous POL-PTX formulations was investi-gated. The mentioned technique has never been applied to a system of similar complexity be-fore and was chosen because around 84% of the small-molecule drugs contain at least one nitrogen atom. In addition, the number of nitrogen atoms in both POL and PTX is much smaller than the number of carbons or hydrogens, which significantly reduces the spectral complexity. 14N has a natural abundance of 99.6% but leads to quadrupolar broadening due to its nuclear spin quantum number I = 1. While this is usually undesirable due to broadening in the resulting 1D 14N NMR spectra, this effect is explicitly used in the 2D 14N-1H HMQC MAS experiment. The indirect 14N measurement can avoid the broadening while maintaining the advantage of the high natural abundance and making use of the much more dispersed signals due to the additional quadrupolar shifts as compared to 15N.
This measurement method could be successfully applied to the complex amorphous POL-PTX mixtures. With increasing PTX loading of the formulations, additional peaks arise as spatial proximities of the amide nitrogens of POL to NH or OH groups of PTX. In addition, the 14N quadrupolar shift of these amide nitrogens decreases with increasing PTX content indicating a more symmetric nitrogen environment. The latter can be explained by a transformation of the trigonal planar coordination of the tertiary amide nitrogen atoms in pure POL towards a more tetrahedral environment upon PTX loading induced by the formation of hydrogen bonds with NH/OH groups of PTX.
In the third and last project, the results of the two abovementioned studies were used and ex-tended by solid state 13C and two-dimensional 1H-13C as well as 1H-1H MAS NMR data with the aim to derive a structural model of the POL-PTX formulations at an atomic level. The knowledge of the NMR signal assignments for crystalline PTX was transferred to amorphous PTX (present in the micelles of the formulations). The 13C solid-state NMR signals were evalu-ated concerning changes in chemical shifts and full widths of half maximum (FWHM) for the different PTX loadings. In this way, the required information about possible interaction sites at an atomic level becomes available. Due to the complexity of these systems, such proximities often cannot be assigned to special atoms, but more to groups of atoms, as the individual de-velopments of line widths and line shifts are mutually dependent. An advantageous aspect for this analysis was that pure POL already forms unloaded micelles. The evaluation of the data showed that the terminal phenyl groups of PTX seem to be most involved in the interaction by the establishment of the micelle for lowest drug loading and that they are likely to react to the change in the amount of PTX molecules as well. For the incorporation of PTX in the micelles, the following model could be obtained: For lowest drug loading, PTX is mainly located in the inner part of the micelles. Upon further increasing of the loading, it progressively extends to-ward the micellar shell. This could be well shown by the increasing interactions of the hydro-phobic butyl chain of POL and PTX, proceeding in the direction of the polymer backbone with rising drug load. Furthermore, due to the size of PTX and the hydrodynamic radius of the mi-celles, even at the lowest loading, the PTX molecules partially reach the core-shell interface of the micelle. Upon increasing the drug loading, the surface coverage with PTX clusters increas-es based on the obtained model approach. The latter result is supported by DLS and SANS data of this system. The abovementioned results of the 14N-1H HMQC MAS investigation of the POL-PTX formulations support the outlined model.
As an outlook, the currently running geometry optimization and subsequently scheduled calcu-lation of the chemical shieldings of the newly obtained anhydrous PTX crystal structure can further improve the solid-state NMR characterization through determination of further spatial proximities among protons using the existing 2D 1H(DQ)-1H(SQ) solid-state MAS NMR spec-trum at 100 kHz rotor spinning frequency. The 2D 14N-1H HMQC MAS NMR experiments were shown to have great potential as a technique for the analysis of other disordered and amor-phous drug delivery systems as well. The results of this thesis should be subsequently applied to other micellar systems with varying pharmaceutical excipients or active ingredients with the goal of systematically achieving higher drug loadings (e.g., for the investigated PTX, the similar drug docetaxel or even different natural products). Additionally, it is planned to transfer the knowledge to another complex polymer system containing poly(amino acids) which offers hy-drogen bonding donor sites for additional intermolecular interactions. Currently, the POL-PTX system is investigated by further SANS studies that may provide another puzzle piece to the model as complementary measurement method in the future. In addition, the use of MD simu-lations might be considered in the future. This would allow a computerized linking of the differ-ent pieces of information with the aim to determine the most likely model.
Nucleic acids are one of the important classes of biomolecules together with carbohydrates, proteins and lipids. Both deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) are most well known for their respective roles in the storage and expression of genetic information.
Over the course of the last decades, nucleic acids with a variety of other functions have been discovered in biological organisms or created artificially. Examples of these functional nucleic acids are riboswitches, aptamers and ribozymes. In order to gain information regarding their function, several analytical methods can be used.
Electron paramagnetic resonance (EPR) spectroscopy is one of several techniques which can be used to study nucleic acid structure and dynamics. However, EPR spectroscopy requires unpaired electrons and because nucleic acids themselves are not paramagnetic, the incorporation of spin labels which carry a radical is necessary.
Here, three new spin labels for the analysis of nucleic acids by EPR spectroscopy are presented. All of them share two important design features. First, the paramagnetic center is located at a nitroxide, flanked by ethyl groups to prevent nitroxide degradation, for example during solid phase synthesis. Furthermore, they were designed with rigidity as an important quality, in order to be useful for applications like pulsed electron double resonance (PELDOR) spectroscopy, where independent motion of the spin labels relative to the macromolecule has a noticeable negative effect on the precision of the measurements.
Benzi-spin is a spin label which differs from most previous examples of rigid spin labels in that rather than being based on a canonical nucleoside, with a specific base pairing partner, it is supposed to be a universal nucleoside which is sufficiently rigid for EPR measurements when placed opposite to a number of different nucleosides. Benzi-spin was successfully incorporated into a 20 nt oligonucleotide and its base pairing behavior with seven different nucleosides was examined by UV/VIS thermal denaturation and continuous wave (CW) EPR experiments. The results show only minor differences between the different nucleosides, thus confirming the ability of benzi-spin to act as a universally applicable spin label.
Lumi-spin is derived from lumichrome. It features a rigid scaffold, as well as a free 2'-hydroxy group, which should make it well suited for PELDOR experiments once it is incorporated into RNA oligonucleotides.
EÇr is based on the Ç family of spin labels, which contains the most well known rigid spin labels for nucleic acids to this day. It is essentially a version of EÇm with a free 2'-hydroxy group. It was converted to triphosphate EÇrTP and used for primer extension experiments to test the viability of enzymatic incorporation of rigid spin labels into oligonucleotides as an alternative to solid-phase synthesis. Incorporation into DNA by Therminator III DNA polymerase in both single-nucleotide and full-length primer extensions was achieved.
All three of these spin labels represent further additions to the expanding toolbox of EPR spectroscopy on nucleic acids and might prove valuable for future research.
Herein described is the discovery of three novel types of dimeric naphthylisoquinoline alkaloids, named mbandakamines, cyclombandakamines, and spirombandakamines. They were found in the leaves of a botanically as yet unidentified, potentially new Ancistrocladus species, collected in the rainforest of the Democratic Republic of the Congo (DRC). Mbandakamines showed an exceptional 6′,1′′-coupling, in the peri-position neighboring one of the outer axes, leading to an extremely high steric hindrance at the central axis, and to U-turn-like molecular shape, which – different from all other dimeric NIQs, whose basic structures are all quite linear – brings three of the four bicyclic ring systems in close proximity to each other. This created an unprecedented follow-up chemistry, involving ring closure reactions, leading to two further, structurally even more intriguing subclasses, the cyclo- and the spirombandakamines, displaying eight stereogenic elements (the highest total number ever found in naphthylisoquinoline alkaloids). The metabolites exhibited pronounced antiplasmodial and antitrypanosomal activities. Likewise reported in this doctoral thesis are the isolation and structural elucidation of naphthylisoquinoline alkaloids from two further potentially new Ancistrocladus species from DRC. Some of these metabolites have shown pronounced antiausterity activities against human pancreatic cancer PANC-1 cells.
The thesis is mainly about the reactivities of borylene complexes. Including the investigation of the reaction of base stabilized terminal borylene with elemental chalcogens. On the other hand the are also the reactivity of borylene with bipyridine species is also studies. A C-H activation of the Cp2WH2 using borylene is also discovered. Finally the reaction of a borylene with Lewis acids such as GaCl3 and InBr3 is also studied.