ABSTRACT
Fibrinogen dissolved in 0.12 M aqueous NaCl solution at a pH of 6.6 exhibits self-assembly in response to a lowering of the NaCl concentration to values equal to or lower than 60 mM. As has been established in a preceding work (Langmuir 2019, 35, and 12113), a characteristic signature of the self-assembly triggered by a drop in ionic strength is the formation of large globular particles. Growth of these particles most likely obeys a coalescence-like process also termed a step growth process. In order to extend this knowledge, the present work first optimized the protocol, leading to highly reproducible self-assembly experiments. Based on this optimization, the work succeeded in identifying an initial stage, not yet accessible, during which rigid short fibrils grow in close analogy to the thrombin-catalyzed polymerization of fibrin. In addition, first suggestions could be made on the transformation of these fibrils into larger aggregates, which upon drying turn into thick fiber-like ropes.
ABSTRACT
Self-assembly of the blood protein fibrinogen is a highly relevant topic in materials science and medical research. This originates from fibrinogen's beneficial material properties such as cell interaction and biocompatibility. Within recent decades, several enzyme-free strategies to create fibers and hydrogels out of fibrinogen have been presented, broadening the spectrum of fibrinogen-based material enormously. Herein, we describe a further method to obtain such a material by adding specifically MgSO4 to fibrinogen. The key of this material is the combination of Mg2+ and a kosmotropic anion, for example sulfate or (hydrogen)phosphate. This effect is most likely related to occupancy of fibrinogen's well-known binding sites for Mg2+, resulting in a significant increase in fiber yield and gel stability. Here, we shine light on the question of how electrostatic interactions via Mg2+ enhance fibrillogenesis and the gelation of fibrinogen and discuss first insights into the material's properties.
ABSTRACT
Fibrin is considered a highly promising biomaterial for manifold medical applications. Although it is a well-established material in this field, the required enzyme thrombin bears some striking downsides such as high costs and health risks. Current research discovers more and more ways to use fibrin's precursor fibrinogen as a substitute. Fibrinogen's full potential is, however, only retained when using it as fibrous gel, as it is the case for fibrin. In our previous work, we introduced such a kind of material for the first time. This material, called pseudo-fibrin, shows striking similarities to fibrin regarding its supramolecular structure and is created in a facile salt-induced process, which we further improved in this study. In particular, we shine light on the role of Ca2+ in pseudo-fibrin buildup, which turned out to drastically improve the outcome. Never before has it been observed that Ca2+ can induce fibrillogenesis and the gelation of native, enzyme-free fibrinogen. Enzyme catalysis was ruled out by the addition of thrombin and factor XIII inhibitors. Even more striking, Ca2+ induces gelation even under physiological conditions, leading again to stable and fibrous hydrogels. Although this latter approach is possibly co-induced by residual factor XIII, the resulting gels are for the first time recognized as promising materials and not discounted as unwanted side effects. The finding that these gels again consist of fibers especially renders a new perspective on the role of factor XIII and fibrinogen's well-known Ca2+ binding sites. In this study, we aim to provide first insights into this highly feasible material and its characteristics.
ABSTRACT
The natural blood protein fibrinogen is a highly potent precursor for the production of various biomaterials due to its supreme biocompatibility and cell interaction. To gain actual materials from fibrinogen, the protein needs to undergo fibrillogenesis, which is mostly triggered via enzymatic processing to fibrin, electrospinning, or drying processes. All of those techniques, however, strongly limit the available structures or the applicability of the material. To overcome the current issues of fibrin(ogen) as material, we herein present a highly feasible, quick, and inexpensive technique for self-assembly of fibrinogen in solution into defined, nanofibrous three-dimensional (3D) patterns. Upon interaction with specific anions in controlled environments, stable and flexible hydrogel-like structures are formed without any further processing. Moreover, the material can be converted into highly porous and elastic aerogels by lyophilization. Both of these material classes have never been described before from native fibrinogen. The observed phenomenon also represents the first enzyme-free process of fibrillogenesis from fibrinogen with significant yield in solution. The produced hydrogels and aerogels were investigated via electron microscopy, IR spectroscopy, and fluorescence spectroscopy, which also confirms the native state of the protein. Additionally, their mechanical properties were compared with actual fibrin and unstructured fibrinogen. The structural features show a striking analogy to actual fibrin, both as hydro- and aerogel. This renders the new material a highly promising alternative for fibrin in biomaterial applications. A much faster initiation of fiber formation, exclusion of possible thrombin residuals, and low-cost reagents are great advantages.
