As a key player in
blood coagulation and tissue repair, fibrinogen
has gained increasing attention to develop nanofibrous biomaterial
scaffolds for wound healing. Current techniques to prepare protein
nanofibers, like electrospinning or extrusion, are known to induce
lasting changes in the protein conformation. Often, such secondary
changes are associated with amyloid transitions, which can evoke unwanted
disease mechanisms. Starting from our recently introduced technique
to self-assemble fibrinogen scaffolds in physiological salt buffers,
we here investigated the morphology and secondary structure of our
novel fibrinogen nanofibers. Aiming at optimum self-assembly conditions
for wound healing scaffolds, we studied the influence of fibrinogen
concentration and pH on the protein conformation. Using circular dichroism
and Fourier-transform infrared spectroscopy, we observed partial transitions
from α-helical structures to β-strands upon fiber formation.
Interestingly, a staining with thioflavin T revealed that this conformational
transition was not associated with any amyloid formation. Toward novel
scaffolds for wound healing, which are stable in aqueous environment,
we also introduced cross-linking of fibrinogen scaffolds in formaldehyde
vapor. This treatment allowed us to maintain the nanofibrous morphology
while the conformation of fibrinogen nanofibers was redeveloped toward
a more native state after rehydration. Altogether, self-assembled
fibrinogen scaffolds are excellent candidates for novel wound healing
systems since their multiscale structures can be well controlled without
inducing any pathogenic amyloid transitions.
Vibrational circular dichroism (VCD) spectra of anisotropic thin solid samples are often superimposed with large contributions of linear birefringence and linear dichroism. In this study a theoretical approach is given on how to extract the true VCD spectrum out of such superimposed spectra. To verify this approach, the VCD spectra of achiral polymer films were examined. The polymers are supposed to give a zero line as VCD spectrum after eliminating the linear contributions. Applying our approach, in which four VCD spectra in different but selected sample orientations are recorded, and calculating their average, leads to the expected result, i.e., a zero line for achiral polymers. The advantage of this method for the elimination of artifacts from solid-state VCD spectra is that no further measurements are required (e.g., linear dichroism measurements or the determination of the orientation with the maximum anisotropy).
Different mono- and bifunctional amine ligands have been used to stabilize Pt NPs for catalytic H2 gas sensing. Depending on the chemical structure and properties of the ligand, the catalysts show different overall sensor performances, activation periods, and long-term stabilities. These sensor characteristics are put into relation with chemical processes like cleaning of the surface, degradation processes of the ligands and nanoparticle (NP) sintering. It has been found that during activation free adsorption sites are formed primarily due to desorption of synthetic residues. Furthermore, partial desorption of the ligands followed by their degradation may occur. For monoamines the latter process results in destabilization of the NPs followed by catalyst deactivation through particle sintering. The use of bifunctional ligands that link individual NPs shows significantly enhanced stabilities which can be related to the reduction of the ligand desorption rates and degradation. Besides the functionality of the ligands it was observed that the chemical nature of their hydrocarbon skeleton affects the catalyst stability: aromatic substructures remain intact upon H2 oxidation, while alkyl fragments undergo oxidation and decomposition. The advantages of bifunctionality and an aromatic hydrocarbon skeleton can be combined by the use of para-phenylenediamine (PDA) as a linking ligand. Networks formed by this ligand were indeed found to be stable under the applied catalytic conditions for more than 24 h.
The goose barnacle Dosima fascicularis produces an excessive amount of adhesive (cement), which has a double function, being used for attachment to various substrata and also as a float (buoy). This paper focuses on the chemical composition of the cement, which has a water content of 92%. Scanning electron microscopy with EDX was used to measure the organic elements C, O and N in the foam-like cement. Vibrational spectroscopy (FTIR, Raman) provided further information about the overall secondary structure, which tended towards a β-sheet. Disulphide bonds could not be detected by Raman spectroscopy. The cystine, methionine, histidine and tryptophan contents were each below 1% in the cement. Analyses of the cement revealed a protein content of 84% and a total carbohydrate content of 1.5% in the dry cement. The amino acid composition, 1D/2D-PAGE and MS/MS sequence analysis revealed a de novo set of peptides/proteins with low homologies with other proteins such as the barnacle cement proteins, largely with an acidic pI between 3.5 and 6.0. The biochemical composition of the cement of D. fascicularis is similar to that of other barnacles, but it shows interesting variations.
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