The coagulation cascade represents a sophisticated and highly choreographed series of molecular events taking place in the blood with important clinical implications. One key player in coagulation is fibrinogen, a highly abundant soluble blood protein that is processed by thrombin proteases at wound sites, triggering self-assembly of an insoluble protein hydrogel known as a fibrin clot. By forming the key protein component of blood clots, fibrin acts as a structural biomaterial with biophysical properties well suited to its role inhibiting fluid flow and maintaining hemostasis.
View Article and Find Full Text PDFWe report a simple method of preparing autonomous and rapid self-adhesive hydrogels and their use as building blocks for additive manufacturing of functional tissue scaffolds. Dynamic cross-linking between 2-aminophenylboronic acid-functionalized hyaluronic acid and poly(vinyl alcohol) yields hydrogels that recover their mechanical integrity within 1 min after cutting or shear under both neutral and acidic pH conditions. Incorporation of this hydrogel in an interpenetrating calcium-alginate network results in an interfacially stiffer but still rapidly self-adhesive hydrogel that can be assembled into hollow perfusion channels by simple contact additive manufacturing within minutes.
View Article and Find Full Text PDFTuning the properties of in situ-gelling injectable hydrogels based on synthetic polymers typically involves changing the chemistry of polymer backbones or the density of reactive functional groups on precursor polymers. Herein, we describe injectable, hydrazone crosslinked hydrogels based on well-defined poly(oligoethylene glycol methacrylate) (POEGMA) precursors prepared via reversible addition-fragmentation chain transfer (RAFT). These hydrogels have different molecular weights but similar functional group content, enabling engineering of hydrogel properties without substantially changing the chemistry of the precursor polymer.
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