From Strain Stiffening to Softening—Rheological Characterization of Keratins 8 and 18 Networks Crosslinked via Electron Irradiation

Abstract: Networks of crosslinked keratin filaments are abundant in epithelial cells and tissues, providing resilience against mechanical forces and ensuring cellular integrity. Although studies of in vitro models of reconstituted keratin networks have revealed important mechanical aspects, the mechanical properties of crosslinked keratin structures remain poorly understood. Here, we exploited the power of electron beam irradiation (EBI) to crosslink in vitro networks of soft epithelial keratins 8 and 18 (k8–k18) filame… Show more

“…This properties can be related to the fact that disulfide bonds of keratin was broken following oxidative extraction of keratin and its stiffness is dependent on the side chain chemical groups. It was previously revealed that, for keratin, the strands joining between thick bundles is fragile [60], this weak coupling results more strand slipping under forces and thus does not follow strain stiffening.…”

Multiprotein collagen/keratin hydrogel promoted myogenesis and angiogenesis of injured skeletal muscles in a mouse model

“…This properties can be related to the fact that disulfide bonds of keratin was broken following oxidative extraction of keratin and its stiffness is dependent on the side chain chemical groups. It was previously revealed that, for keratin, the strands joining between thick bundles is fragile [60], this weak coupling results more strand slipping under forces and thus does not follow strain stiffening.…”

Multiprotein collagen/keratin hydrogel promoted myogenesis and angiogenesis of injured skeletal muscles in a mouse model

“…This is possibly due to the fact that the GWLC model is designed to explain mutual interactions between filaments in a homogeneous, entangled network of semiflexible polymers. The limitations of the GWLC have been demonstrated in previous studies on networks of the cytoskeletal intermediate fila-ment keratin 15,24,34 and were explained with network architectures which were incompatible with the prerequisites of the theory. We suspect that the inability to account for the jump for the 6 base-pair crosslinkers in this case has a similar cause.…”

“…22 In relation to the engineering of biomaterials, chemical crosslinking, for example via electron beam radiation, can also be used to permanently alter and crosslink collagen networks. [23][24][25] Reconstituted networks of filamentous actin (F-actin) are experimentally well-characterized and were used as an ideal for the development of theoretical models. 9,12,16,21,26,27 The concentration-dependent scaling of the elastic plateau modulus, G 0 ∝ c 7/5 , for entangled F-actin solutions is theoretically described within the frame of the tube model 28 and has been experimentally verified.…”

Systematic altering of semiflexible DNA-based polymer networks via tunable crosslinking

“…Fig. 4 shows the experimental data obtained for (a) keratin gel, 52 (b) silk fibroin gel, 24 (c) neurofilament-based hydrogel, 22 Table 1 Here, n e , q c and DE are parameters obtained from a fit procedure of eqn (2) to the experimental data extracted from ref. 21, where the stress-strain of samples of PEG hydrogels with different hydrophobic ratios r are presented.…”

Revisiting the strain-induced softening behaviour in hydrogels