2022
DOI: 10.1039/d2sm00255h
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Ionic group-dependent structure of complex coacervate hydrogels formed by ABA triblock copolymers

Abstract: This study investigates the nanostructure of complex coacervate core hydrogels (C3Gs) with varying compositions of cationic charged groups (i.e., ammonium and guanidinium) using small-angle X-ray/neutron scattering (SAX/NS). C3Gs were prepared...

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Cited by 6 publications
(17 citation statements)
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“…Typical PEC hydrogels comprise a bPE as at least one of the two (or more) oppositely charged components. As such, the simplest way to create a PEC hydrogel is by mixing a triblock polyelectrolyte with an oppositely charged homopolyelectrolyte (Figure a), ,,,, diblock polyelectrolyte (Figure b), , or triblock polyelectrolyte (Figure c). ,,,,,,,,, , It is also possible to create a PEC hydrogel by mixing a triblock polyelectrolyte with oppositely charged macroions , or multivalent metal ions (Figure d). , Hydrogels with assemblies of oppositely charged bPEs [i.e., diblock, triblock, and pentablock (Figure e)] have also been demonstrated. , Finally, in addition to linear polyelectrolytes, PEC hydrogels have also been created from oppositely charged bPEs possessing nonlinear architectures [e.g., three- and four-arm bPEs (Figure f)]. , It should be noted that these combinations are not an all-encompassing description of PEC hydrogel fabrication pathways; other combinations may exist.…”
Section: Recent Advances In Electrostatically Assembled Pec Hydrogelsmentioning
confidence: 99%
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“…Typical PEC hydrogels comprise a bPE as at least one of the two (or more) oppositely charged components. As such, the simplest way to create a PEC hydrogel is by mixing a triblock polyelectrolyte with an oppositely charged homopolyelectrolyte (Figure a), ,,,, diblock polyelectrolyte (Figure b), , or triblock polyelectrolyte (Figure c). ,,,,,,,,, , It is also possible to create a PEC hydrogel by mixing a triblock polyelectrolyte with oppositely charged macroions , or multivalent metal ions (Figure d). , Hydrogels with assemblies of oppositely charged bPEs [i.e., diblock, triblock, and pentablock (Figure e)] have also been demonstrated. , Finally, in addition to linear polyelectrolytes, PEC hydrogels have also been created from oppositely charged bPEs possessing nonlinear architectures [e.g., three- and four-arm bPEs (Figure f)]. , It should be noted that these combinations are not an all-encompassing description of PEC hydrogel fabrication pathways; other combinations may exist.…”
Section: Recent Advances In Electrostatically Assembled Pec Hydrogelsmentioning
confidence: 99%
“…Variation of the intrinsic parameters affects the network microstructure, including the PEC domain morphology and the distance between domains (i.e., mesh size), which in turn affects the moduli, salt resistance, and other physical properties of the hydrogels. , PEC hydrogels also benefit from another level of tunability provided by the variation of externally controlled parameters. For example, upon the addition of salt (e.g., NaCl), the electrostatic interactions can be screened, thus affecting the moduli and microstructure of the hydrogel. ,,,,,,,, For PEC hydrogels with functional groups that are weakly ionized, pH is another external parameter that can be used to tune their microstructure and properties. , Multiple levels of tunability distinguish PEC hydrogels as a clear choice for precisely designed materials.…”
Section: Recent Advances In Electrostatically Assembled Pec Hydrogelsmentioning
confidence: 99%
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