Add to ORKGThe dynamic behavior of macromolecular networks dominates the mechanical properties of soft materials and influences biological processes at multiple length scales. In hydrogels prepared from self-assembling artificial proteins, stress relaxation and energy dissipation arise from the transient character of physical network junctions. Here we show that subtle changes in sequence can be used to program the relaxation behavior of end-linked networks of engineered coiled-coil proteins. Single-site substitutions in the coiled-coil domains caused shifts in relaxation time over 5 orders of magnitude as demonstrated by dynamic oscillatory shear rheometry and stress relaxation measurements. Networks with multiple relaxation time scales were also eng...
Artificial protein hydrogels made from a triblock protein (designated AC10A, where A is an acidic zi...
Biological materials combine stress relaxation and self-healing with non-linear stress-strain respon...
Engineering artificial protein hydrogels for medical applications requires precise control over thei...
Network relaxation dynamics of hydrogels formed from a genetically engineered multidomain protein (A...
Network relaxation dynamics of hydrogels formed from a genetically engineered multidomain protein (A...
Artificial proteins may be programmed to reversibly self-assemble into water-soluble networks, or “h...
Recombinant artificial proteins contain genetically encoded information that specifies their assembl...
Coiled-coil domains can direct the assembly of protein block copolymers into physically cross-linked...
A set of recombinant artificial proteins that can be cross-linked, by either covalent bonds or assoc...
A set of recombinant artificial proteins that can be cross-linked, by either covalent bonds or assoc...
Coiled-coil domains can direct the assembly of protein block copolymers into physically crosslinked,...
Artificial protein hydrogels made from a triblock protein (designated AC10A, where A is an acidic zi...
Globular folded proteins are versatile nanoscale building blocks to create biomaterials with mechani...
Engineering artificial protein hydrogels for medical applications requires precise control over thei...
Topological entanglements between polymer chains are achieved in associating protein hydrogels throu...
Artificial protein hydrogels made from a triblock protein (designated AC10A, where A is an acidic zi...
Biological materials combine stress relaxation and self-healing with non-linear stress-strain respon...
Engineering artificial protein hydrogels for medical applications requires precise control over thei...
Network relaxation dynamics of hydrogels formed from a genetically engineered multidomain protein (A...
Network relaxation dynamics of hydrogels formed from a genetically engineered multidomain protein (A...
Artificial proteins may be programmed to reversibly self-assemble into water-soluble networks, or “h...
Recombinant artificial proteins contain genetically encoded information that specifies their assembl...
Coiled-coil domains can direct the assembly of protein block copolymers into physically cross-linked...
A set of recombinant artificial proteins that can be cross-linked, by either covalent bonds or assoc...
A set of recombinant artificial proteins that can be cross-linked, by either covalent bonds or assoc...
Coiled-coil domains can direct the assembly of protein block copolymers into physically crosslinked,...
Artificial protein hydrogels made from a triblock protein (designated AC10A, where A is an acidic zi...
Globular folded proteins are versatile nanoscale building blocks to create biomaterials with mechani...
Engineering artificial protein hydrogels for medical applications requires precise control over thei...
Topological entanglements between polymer chains are achieved in associating protein hydrogels throu...
Artificial protein hydrogels made from a triblock protein (designated AC10A, where A is an acidic zi...
Biological materials combine stress relaxation and self-healing with non-linear stress-strain respon...
Engineering artificial protein hydrogels for medical applications requires precise control over thei...