Physics of engineered protein hydrogels

Kim, Minkyu; Tang, Sheng; Olsen, Bradley D.

doi:10.1002/polb.23270

Cited by 36 publications

(28 citation statements)

References 210 publications

(243 reference statements)

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“…For polyelectrolyte gels, eqs and are equivalent expressions for anionic and cationic hydrogels prepared in the presence of a solvent. Artificially engineered protein‐based hydrogels present a challenge in polymer physics; however, work by Kim et al reviews some of the progress on the physics of the dynamic intermolecular interactions of protein hydrogels …”

Section: Theory Of Swellingmentioning

confidence: 99%

“…Artificially engineered protein-based hydrogels present a challenge in polymer physics; however, work by Kim et al reviews some of the progress on the physics of the dynamic intermolecular interactions of protein hydrogels. 25 Dynamic Swelling of Hydrogels The theories described above address the equilibrium swelling state of hydrogels; however, an understanding of the swelling dynamics through volume phase transitions may be useful for predicting the behavior of the hydrogel with time. There are many various models that simulate volume transitions, some of which have been recently reviewed.…”

Section: Equilibrium Swelling Theorymentioning

confidence: 99%

See 1 more Smart Citation

Advances in smart materials: Stimuli‐responsive hydrogel thin films

White

Yatvin

Grubbs

et al. 2013

J Polym Sci B Polym Phys

167

115

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This review highlights recent developments in the field of stimuli-responsive hydrogels, focusing primarily on thin films, with a thickness range between 100 nm to 10 lm. The theory and dynamics of hydrogel swelling is reviewed, followed by specific applications. Gels are classified based on the active stimulus-mechanical, chemical, pH, heat, and lightand fabrication methods, design constraints, and novel stimuliresponses are discussed. Often, these materials display large physiochemical reactions to a relatively small stimulus.Noteworthy materials larger than 10 lm, but with response times on the order of seconds to minutes are also discussed. Hydrogels have the potential to advance the fields of medicine and polymer science as useful substrates for "smart" devices.

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Section: Theory Of Swellingmentioning

confidence: 99%

Section: Equilibrium Swelling Theorymentioning

confidence: 99%

Advances in smart materials: Stimuli‐responsive hydrogel thin films

White

Yatvin

Grubbs

et al. 2013

J Polym Sci B Polym Phys

167

115

View full text Add to dashboard Cite

show abstract

“…[2][3][4][5][6][7][8] Among the OP hydrogels, taking advantage of the decomposition products released by nerve agents after reaction with oximes and the subsequent reaction with cross-linkers. [45][46][47][48] Recently, N,N-bis(acryloyl cystamine) (BAC) was used as the bridging molecule in radical polymerization, enabling numerous applications that are triggered by external stimuli such as pH, temperature, ionic strength, light, stress, and ligand binding (ligand-triggered actuators/sensors) to modulate the state of the disulfide bond. Many types of hydrogels have been engineered as building blocks for different stimuli-responsive materials due to their biocompatibility, biodegradability, tunability in mechanical properties, and molecular recognition abilities.…”

Section: Introductionmentioning

confidence: 99%

“…Many types of hydrogels have been engineered as building blocks for different stimuli-responsive materials due to their biocompatibility, biodegradability, tunability in mechanical properties, and molecular recognition abilities. [45][46][47][48] Recently, N,N-bis(acryloyl cystamine) (BAC) was used as the bridging molecule in radical polymerization, enabling numerous applications that are triggered by external stimuli such as pH, temperature, ionic strength, light, stress, and ligand binding (ligand-triggered actuators/sensors) to modulate the state of the disulfide bond. [49][50][51][52][53] Herein, the ability to couple oxime-based decontamination and disulfide chemistry is demonstrated, producing hydrogels that can decontaminate organophosphate compounds, sense the decontamination product, and transduce this sensing response into actuation of the gel which could be used to close pores in a gel layer or on a fabric coating.…”

Section: Introductionmentioning

confidence: 99%

Hydrogels That Actuate Selectively in Response to Organophosphates

Gkikas

Avery

Mills

et al. 2016

Adv Funct Materials

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1 of 10) 1602784 compounds, the V-type nerve agents are the most toxic, rendering the development of novel decontamination and protection technologies highly important. Decontamination or sequestration of high toxicity OP compounds can be accomplished through hydrolysis of the phosphate ester bond [9][10][11][12] with the enzyme organophosphorus hydrolase, [9][10][11][12][13][14][15] entrapment in nanoporous materials, [16,17] enzyme/ polymer conjugates [18][19][20][21][22][23][24] and highly bioactive enzyme/amphiphilic polymer formulations, [25] chemically modified fluorescent probes, [26][27][28] and oxime reactivators. [29][30][31][32] V-type organophosphates contain a P-S bond and a choline-like moiety and are hydrolyzed very slowly by natural enzymes. Therefore, new and efficient approaches that target VX are necessary for mitigation of the agent.A major challenge in the mitigation of threats from OP compounds is developing protective garments that can eliminate exposure of the wearer to the toxic chemical. Some rubbers can serve as effective barrier materials, [33] but in sufficient thickness they are not breathable and extremely uncomfortable to wear for an extended period of time. Therefore, there is a strong interest in a garment or barrier membrane that could remain in a porous state when it is not in the presence of an organophosphate, but close its pores autonomously in the presence of the toxic agent to prevent its passage. Such a smart barrier needs to be able to efficiently sense the OP compound and also transduce the sensing response into an actuated change of state without an external input of energy.The reactivity of oximes with OP compounds, yielding phosphorylated adducts, [34][35][36][37][38][39][40][41][42][43][44] provides a potential basis for detection and response in an autonomous material. As part of antidotal therapy against OP poisoning, oximes help reactivate phosphorylated AChE. Quaternary pyridine aldoximes substituted in the para position have been shown to be highly reactive in reversing poisoning from different OP compounds, screened over AChE of different origins. [36] Polymeric materials with enhanced nucleophilic activity provided by N-alkyl 4-pyridinium aldoximes also recently showed significant detoxification of diisopropyl fluorophosphate. [31] Coupling oxime decontamination with responsive crosslinkers could potentially enable the triggering of responsive Nerve agents and pesticides represent a category of extremely toxic organo phosphate compounds (OPs) that irreversibly inhibit the enzyme acetyl cholinesterase, disturbing transmission in the synaptic clefts of muscles and nerves. Protection from these compounds necessitates the development of breathable barriers that can selectively block the passage of OPs. Hydrogels prepared from acrylamide, N,N′methylenebis(acrylamide), N,N′bis(acryloyl) cystamine, and hydrophilic pendant oximes are herein prepared, showing the ability to decontaminate and respond to the presence of OPs through a change in swelling. The oximebased h...

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“…As this method only modifies the amino acid residues participating in junction formation, the protein strands can retain most of their function (e.g., elasticity and stimuli responsivity). In addition, many mechanical properties at equilibrium, such as modulus and maximum swelling ratio, can be controlled by varying the dosage of the crosslinking agents according to well-known laws of hydrogel physics and network theories (Graessley, 2004; Tanaka, 2011; Kim et al, 2013). In a typical crosslinking reaction, however, the formation of network imperfections, such as dangling chains and inelastic loops, is usually uncontrollable and difficult to quantify (Zhou et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Controlling topological entanglement in engineered protein hydrogels with a variety of thiol coupling chemistries

Tang

Olsen

2014

Front. Chem.

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Topological entanglements between polymer chains are achieved in associating protein hydrogels through the synthesis of high molecular weight proteins via chain extension using a variety of thiol coupling chemistries, including disulfide formation, thiol-maleimide, thiol-bromomaleimide and thiol-ene. Coupling of cysteines via disulfide formation results in the most pronounced entanglement effect in hydrogels, while other chemistries provide versatile means of changing the extent of entanglement, achieving faster chain extension, and providing a facile method of controlling the network hierarchy and incorporating stimuli responsivities. The addition of trifunctional coupling agents causes incomplete crosslinking and introduces branching architecture to the protein molecules. The high-frequency plateau modulus and the entanglement plateau modulus can be tuned by changing the ratio of difunctional chain extender to the trifunctional branching unit. Therefore, these chain extension reactions show promise in delicately controlling the relaxation and mechanical properties of engineered protein hydrogels in ways that complement their design through genetic engineering.

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Physics of engineered protein hydrogels

Cited by 36 publications

References 210 publications

Advances in smart materials: Stimuli‐responsive hydrogel thin films

Advances in smart materials: Stimuli‐responsive hydrogel thin films

Hydrogels That Actuate Selectively in Response to Organophosphates

Controlling topological entanglement in engineered protein hydrogels with a variety of thiol coupling chemistries

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