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Soft matter
Prof. Dr. Klaus Huber
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Self-assembly of dyestuffs and proteins

Numerous synthetic, low molecular weight compounds like organic azo-dyestuffes form fiber-like aggregates in aqueous solution in close analogy to the self-assembly of various proteins in living systems. The underlying processes can be regarded as physical polymerisations leading to a structural diversity, just as complex as in case of macromolecular chemistry. Several low molecular weight gelators and dyestuffs, with the cationic dyestuff pseudo-isocynanine chloride (PIC) as the most recent example, have been selected for a detailed investigation of their self-assembly with time-resolved light scattering. These systems are compared with corresponding experiments on the behaviour of Ab-amyloid responsible for the Alzheimer disease or on vimentin, an intermediary filament protein from the cytoskeleton. It is the final goal to unravel general principles of such self-assembly mechanisms which facilitates to control aggregate size and aggregate morphology and to develop synthetic systems in analogy to hierarchical structure formation in nature.

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Effect of ionic strength on the structure and elongational kinetics of vimentin filaments
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Hämisch, B. et al.
Self-Assembly of Fibrinogen in Aequos, Thrombin-Free Solutions of Variable Ionic Strenghts
Langmuir (2019) 35, 12113-12122 DOI: 10.1021/acs.langmuir.9b01515

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