Stephani Stamboroski scite author profile

Fibrinogen has become highly attractive for tissue engineering scaffolds since it is a naturally occurring blood protein, which contains important binding sites to facilitate cell adhesion. Here, we introduce a novel biofabrication technique to prepare three-dimensional, nanofibrous fibrinogen scaffolds by salt-induced self assembly. For the first time, we were able to fabricate either free-standing or immobilized fibrinogen scaffolds on demand by tailoring the underlying substrate material and adding a fixation and washing procedure after the fiber assembly. Using scanning electron microscopy we observed that different buffers including phosphate buffered saline and sodium phosphate reproducibly yielded dense fiber networks on bare and silanized glass surfaces, gold as well as polystyrene upon drying. Fibrillogenesis could be induced with a fibrinogen concentration of at least 2 mg ml−1 in a pH regime of 7–9. Fiber diameters ranged from 100 to 300 nm, thus resembling native fibrin and ECM protein fibers. By adjusting the salt concentration we could prepare fibrinogen scaffolds with overall dimensions in the centimeter range and a thickness of 3 to 5 μm. Using FTIR analysis we observed peak shifts of the amide bands for fibrinogen nanofibers in comparison to planar fibrinogen, which indicates changes in the secondary structure. Since fibrillogenesis was only induced upon drying when salt ions were present we assume that protein molecules were locally oriented in the respective buffers, which—in combination with the observed conformational changes—led to the assembly of individual molecules into fibers. In summary, our novel self assembly process offers a simple and well controllable method to prepare large scale 3D-scaffolds of fibrinogen nanofibers under physiological conditions. The unique possibility to chose between free-standing and immobilized scaffolds makes our novel biofabrication process highly attractive for the preparation of versatile tissue engineering scaffolds.

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Controlling the Multiscale Structure of Nanofibrous Fibrinogen Scaffolds for Wound Healing

Stapelfeldt

Stamboroski

Walter

et al. 2019

Nano Lett.

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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.

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Principles of Fibrinogen Fiber Assembly In Vitro

Stamboroski

Joshi

Noeske

et al. 2021

Macromolecular Bioscience

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Fibrinogen nanofibers hold great potential for applications in wound healing and personalized regenerative medicine due to their ability to mimic the native blood clot architecture. Although versatile strategies exist to induce fibrillogenesis of fibrinogen in vitro, little is known about the underlying mechanisms and the associated length scales. Therefore, in this manuscript the current state of research on fibrinogen fibrillogenesis in vitro is reviewed. For the first time, the manifold factors leading to the assembly of fibrinogen molecules into fibers are categorized considering three main groups: substrate interactions, denaturing and non‐denaturing buffer conditions. Based on the meta‐analysis in the review it is concluded that the assembly of fibrinogen is driven by several mechanisms across different length scales. In these processes, certain buffer conditions, in particular the presence of salts, play a predominant role during fibrinogen self‐assembly compared to the surface chemistry of the substrate material. Yet, to tailor fibrous fibrinogen scaffolds with defined structure–function‐relationships for future tissue engineering applications, it still needs to be understood which particular role each of these factors plays during fiber assembly. Therefore, the future combination of experimental and simulation studies is proposed to understand the intermolecular interactions of fibrinogen, which induce the assembly of soluble fibrinogen into solid fibers.

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New details of assembling bioactive films from dispersions of amphiphilic molecules on titania surfaces

et al. 2020

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