Tunable Interpenetrating Polymer Network Hydrogels Based on Dynamic Covalent Bonds and Metal–Ligand Bonds

Yang, Hui; Ghiassinejad, Sina; Ruymbeke, Evelyne Van; Fustin, Charles‐André

doi:10.1021/acs.macromol.0c00494

Cited by 58 publications

(55 citation statements)

References 66 publications

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“…Having said this, there is plenty of evidence in the literature on formation of IPNs with purely reversible cross-links. [50][51][52][53][54] Our results suggests that such IPNs are kinetically trapped states. The typical activation energies of the dynamic bonds in these IPNs are of several hundreds of kJ/mol, 54 i.e., of the order of 100k B T whereas in our simulations they are about 10k B T .…”

Section: Crowded Solutions and Phase Behaviormentioning

confidence: 53%

On the Validity of Effective Potentials in Crowded Solutions of Linear and Ring Polymers with Reversible Bonds

Paciolla,

Likos,

Moreno

2021

Preprint

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We perform simulations to compute the effective potential between the centers-of-mass of two polymers with reversible bonds. We investigate the influence of the topology on the potential by employing linear and ring backbones for the precursor (unbonded) polymer, finding that it leads to qualitatively different effective potentials. In the linear and ring cases the potentials can be described by Gaussians and generalized exponentials, respectively. The interactions are more repulsive for the ring topology, in analogy with known results in the absence of bonding.We also investigate the effect of the specific sequence of the reactive groups along the backbone (periodic or with different degrees of randomness), establishing that it has a significant impact on the effective potentials. When the reactive sites of both polymers are chemically orthogonal so that only intramolecular bonds are possible, the interactions become more repulsive the closer to periodic the sequence is. The opposite effect is found if both polymers have the same type of reactive sites and intermolecular bonds can be formed. We test the validity of the effective potentials in solution, in a broad range of concentrations from high dilution to far above the overlap concentration. For this purpose, we compare simulations of the effective fluid and test particle route calculations with simulations of the real all-monomer system. Very good agreement is found for the reversible linear polymers, indicating that unlike in their non-bonding counterparts many-body effects are minor even far above the overlap concentration. The agreement for the reversible rings is less satisfactory, and at high concentration the real system does not show the clustering behavior predicted by the effective potential. Results similar to the former ones are found for the partial self-correlations in ring/linear mixtures.Finally, we investigate the possibility of creating, at high concentrations, a gel of two interpenetrated reversible networks. For this purpose we simulate a 50/50 two-component mixture of reversible polymers with orthogonal chemistry for the reactive sites, so that intermolecular bonds are only formed between polymers of the same component. As predicted by both the theoretical phase diagram and the simulations of the effective fluid, the two networks in the all-monomer mixture do not interpenetrate and phase separation (demixing) is observed instead.

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Section: Crowded Solutions and Phase Behaviormentioning

confidence: 53%

On the Validity of Effective Potentials in Crowded Solutions of Linear and Ring Polymers with Reversible Bonds

Paciolla,

Likos,

Moreno

2021

Preprint

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“…Fustin and co‐workers [ 210 ] synthesized two copolymers based on poly( N , N ‐dimethyl acrylamide) to make an IPN hydrogels. Their first copolymer had ketone pendant groups and was crosslinked by dihydrazide or bishydroxylamine compounds to form acylhydrazone‐ or oxime‐based dynamic covalent networks.…”

Section: Dynamic Materials Crosslinked By the Combination Of Dynamic ...mentioning

confidence: 99%

Complementary Dynamic Chemistries for Multifunctional Polymeric Materials

Zhang

Watuthanthrige

Wanasinghe

et al. 2021

Adv Funct Materials

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Dynamic materials (DMs) or dynamers have potential applications across a broad range of material science challenges. These applications include sustainable materials as a part of the circular plastics economy, advanced materials with tailored high stress properties and biomedical agents. DMs are comprised of polymers that crosslinked through reversible covalent and noncovalent linking groups. This group provides reversible bonds, which impart properties such as (re)healing, adaptability, toughness into a material. The nature of the linker dictates the dynamer's stability and dynamic properties, although for many applications one linker alone cannot give materials with complex multiresponsive functions. The combination of multiple dynamic linkers can introduce complementary functionalities into a single material. This combination of linkers enhances the collective material properties by matching their strengths and offsetting the weaknesses, or by selecting linkers for specific functions, such as one linker for rapid exchange and the other to respond to external stimuli. This contribution highlights the possibilities and unique features of materials containing multiple dynamic linkers, reviewing both fundamental discoveries of materials possessing multiple dynamic bonds and applications facilitated by the presence of multiple linking group chemistry.

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“…The motivation for this work was the development of a high toughness hydrogel that did not derive its toughness from sacrificial covalent bonds as in double networks [ 22 ]. Toward this end, it was desirable to create a hydrogel that achieved high toughness using self-healing ionic bonds [ 38 ]. While hydrogels with two oppositely charged groups have been synthesized previously [ 5 , 11 , 15 , 32 , 35 , 38 ], here, the creation of such a hydrogel starting from two thermodynamically compatible neutral networks has been demonstrated.…”

Section: Discussionmentioning

confidence: 99%

“…Toward this end, it was desirable to create a hydrogel that achieved high toughness using self-healing ionic bonds [ 38 ]. While hydrogels with two oppositely charged groups have been synthesized previously [ 5 , 11 , 15 , 32 , 35 , 38 ], here, the creation of such a hydrogel starting from two thermodynamically compatible neutral networks has been demonstrated. In general, polyelectrolyte mixtures undergo a degree of microphase separation [ 21 , 22 ].…”

Section: Discussionmentioning

confidence: 99%

Enhanced Mechanical Properties by Ionomeric Complexation in Interpenetrating Network Hydrogels of Hydrolyzed Poly (N-vinyl Formamide) and Polyacrylamide

Scalet

Suekama

Jeong

et al. 2021

Gels

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Tough hydrogels were made by hydrolysis of a neutral interpenetrating network (IPN) of poly (N-vinyl formamide) PNVF and polyacrylamide (PAAm) networks to form an IPN of polyvinylamine (PVAm) and poly (acrylic acid) (PAAc) capable of intermolecular ionic complexation. Single network (SN) PAAm and SN PNVF have similar chemical structures, parameters and physical properties. The hypothesis was that starting with neutral IPN networks of isomeric monomers that hydrolyze to comparable extents under similar conditions would lead to formation of networks with minimal phase separation and maximize potential for charge–charge interactions of the networks. Sequential IPNs of both PNVF/PAAm and PAAm/PNVF were synthesized and were optically transparent, an indication of homogeneity at submicron length scales. Both IPNs were hydrolyzed in base to form PVAm/PAAc and PAAc/PVAm IPNs. These underwent ~5-fold or greater decrease in swelling at intermediate pH values (3–6), consistent with the hypothesis of intermolecular charge complexation, and as hypothesized, the globally neutral, charge-complexed gel states showed substantial increases in failure properties upon compression, including an order of magnitude increases in toughness when compared to their unhydrolyzed states or the swollen states at high or low pH values. There was no loss of mechanical performance upon repeated compression over 95% strain.

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Tunable Interpenetrating Polymer Network Hydrogels Based on Dynamic Covalent Bonds and Metal–Ligand Bonds

Cited by 58 publications

References 66 publications

On the Validity of Effective Potentials in Crowded Solutions of Linear and Ring Polymers with Reversible Bonds

On the Validity of Effective Potentials in Crowded Solutions of Linear and Ring Polymers with Reversible Bonds

Complementary Dynamic Chemistries for Multifunctional Polymeric Materials

Enhanced Mechanical Properties by Ionomeric Complexation in Interpenetrating Network Hydrogels of Hydrolyzed Poly (N-vinyl Formamide) and Polyacrylamide

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