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In this work, a toolbox was provided to create three-component polymer conjugates with a defined architecture, designed to bear different biocomponents that can interact with larger biological systems in biomacromolecular recognition experiments. The target architecture is the attachment of two biomolecule ‘arms’ to the alpha telechelic end point of a polymer and fixating the conjugate to the gold surface of SAW and SPR sensor chips with the polymer’s other omega chain end. This specific design of a conjugate will be implemented by using a strategy to yield novel double alpha as well as omega telechelic functionalized POx and the success of all cascade reaction steps leading to the final conjugation product will be proven through affinity measurements between covalently bound mannose and ConA. All reactions were performed on a low molecular model level first and then transferred to telechelic and also side chain functionalized polymer systems.
This thesis aimed to evaluate the possibility to use nanoparticles as antifungal drug carriers as well as their potential application in screening and diagnostics of invasive aspergillosis. The interaction of nanogels, superparamagnetic iron oxide nanoparticles (SPIOs) and gold nanoparticles (GNP) with fungal-specific polysaccharides, cells and biofilms was investigated.
Firstly, it was evaluated how the charge of nanogels influence their interaction with fungal cells. Linear poly(glycidol)s (pG) and poly(2-methyl-2-oxazoline) (pMOx) polymers were synthesized and further functionalized with thiol groups for preparation of redox responsive nanogels. Results showed that negatively charged nanogels were internalized by the fungi to a much greater extent than positively charged ones.
Furthermore, it was investigated how amphiphilicity of polymers used for preparation of nanogels influences nanogel-fungi interaction. It was concluded that nanogels prepared from polymers with degree of functionalization of 10% had the strongest interaction, regardless the length of the alkyl chain. Moreover, amphotericin B-loaded nanogels had a higher antifungal effect and lower toxicity towards mammalian cells than the free drug. In addition, inverse nanoprecipitation of thiol functionalized pGs was shown to be successful for preparation of nanogels with narrow size distribution.
It was also demonstrated that crosslinking of the polymeric coating in hydrogel-like network with thiol functionalized pGs improved the SPIOs imaging performance.
Finally, it was investigated whether GNPs could be used as model particles for the assessment of targeting to fungi. Fc dectin-1 was conjugated covalently to GNPs decorated with pGs, and binding affinity towards β-glucans was tested by surface plasmon resonance.
In summary, this thesis demonstrated evidence for the potential of pG nanogels and pG coated nanoparticles for antifungal therapy and diagnostics of fungal infections caused by A. fumigatus.