Interactive Polymer Gels as Biomimetic Sensors for Carbohydrate Interactions and Capture–Release Devices for Pathogens

Schmidt, Stephan; Paul, Tanja J.; Strzelczyk, Alexander K.

doi:10.1002/macp.201900323

Cited by 16 publications

(17 citation statements)

References 79 publications

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“…Ligand-modified surfaces are probably enhanced due to multivalent interactions between surface-anchored clusters composed of many saccharide units. This phenomenon is denoted as a glycocluster effect and is able to multiply avidity and activity in biologic systems [ 19 ]. On the other hand, the mechanical properties and mobility of a ligand can affect the biorecognition process to a great extent.…”

Section: Glycan-functionalized Nanoparticles (Nps)mentioning

confidence: 99%

“…In the next study from the same group, AuNPs were rendered responsive towards lectins and Ca 2+ ions [89]. A similar strategy using microgels instead of AuNPs was used in the detection of Con A and E. coli, which could be separated after binding by filtration [19,90]. Many pathogen-related diseases are caused by food-borne bacterial strains.…”

Section: Gold Nanoparticles (Aunps)mentioning

confidence: 99%

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Glycan Nanobiosensors

et al. 2020

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This review paper comprehensively summarizes advances made in the design of glycan nanobiosensors using diverse forms of nanomaterials. In particular, the paper covers the application of gold nanoparticles, quantum dots, magnetic nanoparticles, carbon nanoparticles, hybrid types of nanoparticles, proteins as nanoscaffolds and various nanoscale-based approaches to designing such nanoscale probes. The article covers innovative immobilization strategies for the conjugation of glycans on nanoparticles. Summaries of the detection schemes applied, the analytes detected and the key operational characteristics of such nanobiosensors are provided in the form of tables for each particular type of nanomaterial.

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Section: Glycan-functionalized Nanoparticles (Nps)mentioning

confidence: 99%

Section: Gold Nanoparticles (Aunps)mentioning

confidence: 99%

Glycan Nanobiosensors

et al. 2020

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“…[ 39 ] Quite similarly to thermosensitive polymers, by increasing the temperature above the LCST carbohydrate functionalized microgels form polymer−polymer contacts and collapse, thereby decreasing the steric repulsion while increasing the carbohydrate density and the elastic modulus, [ 34,35,40 ] which increases E. coli clustering in solution and carbohydrate binding overall. [ 38,41,42,43 ] The temperature dependent shifts in the microgels’ elastic modulus and surface roughness can be used to create switchable cell culture surfaces that enable the controlled attachment and detachment of cells even without addressing specific cell adhesion receptors. [ 35,40,44 ] However, microgel coatings specifically targeting selected cells, e.g.…”

Section: Introductionmentioning

confidence: 99%

Temperature‐Controlled Adhesion to Carbohydrate Functionalized Microgel Films: An E. coli and Lectin Binding Study

Paul

Strzelczyk

Schmidt

2021

Macromolecular Bioscience

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The preparation of thermoresponsive mannose functionalized monolayers of poly(N‐isopropylacrylamide) microgels and the analysis of the specific binding of concanavalin A (ConA) and E. coli above and below the lower critical solution temperature (LCST) are shown. Via inhibition and direct binding assays it is found that ConA binding is time‐dependent, where at short incubation times binding is stronger above the LCST. Given larger incubation times, the interaction of ConA to the microgel network is increased below the LCST when compared to temperatures above the LCST, possibly due to increased ConA diffusion and multivalent binding in the more open microgel network below the LCST. For E. coli, which presents only monovalent lectins and is too large to diffuse into the network, binding is always enhanced above the LCST. This is due to the larger mannose density of the microgel layer above the LCST increasing the interaction to E. coli. Once bound to the microgel layer above the LCST, E. coli cannot be released by cooling down below the LCST. Overall, this suggests that the carbohydrate presenting microgel layers enable specific binding where the temperature‐induced transition between swollen and collapsed microgels may increase or decrease binding depending on the receptor size.

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“…on multivalent macromolecular glycoconjugates presenting many carbohydrate subunits, thus binding to bacterial lectins with high avidity [20][21][22][23][24][25]. Microgel scaffolds have recently been developed as a platform to study carbohydrate-lectin interactions and to capture carbohydrate-binding bacteria [26][27][28][29][30]. In addition to their straightforward synthesis, microgels allow for preparing robust surface coatings through simple physisorption methods, e.g., via drop-casting, spin coating or dip-coating [31] Carbohydrate-functionalized microgels are highly hydrated and soft, thus mimicking properties of the extracellular matrix or glycocalyx, which sets them apart from other glycan-presenting scaffolds.…”

Section: Introductionmentioning

confidence: 99%

Lectin and E. coli Binding to Carbohydrate-Functionalized Oligo(ethylene glycol)-Based Microgels: Effect of Elastic Modulus, Crosslinker and Carbohydrate Density

et al. 2021

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The synthesis of carbohydrate-functionalized biocompatible poly(oligo(ethylene glycol) methacrylate microgels and the analysis of the specific binding to concanavalin A (ConA) and Escherichia coli (E. coli) is shown. By using different crosslinkers, the microgels’ size, density and elastic modulus were varied. Given similar mannose (Man) functionalization degrees, the softer microgels show increased ConA uptake, possibly due to increased ConA diffusion in the less dense microgel network. Furthermore, although the microgels did not form clusters with E. coli in solution, surfaces coated with mannose-functionalized microgels are shown to bind the bacteria whereas galactose (Gal) and unfunctionalized microgels show no binding. While ConA binding depends on the overall microgels’ density and Man functionalization degree, E. coli binding to microgels’ surfaces appears to be largely unresponsive to changes of these parameters, indicating a rather promiscuous surface recognition and sufficiently strong anchoring to few surface-exposed Man units. Overall, these results indicate that carbohydrate-functionalized biocompatible oligo(ethylene glycol)-based microgels are able to immobilize carbohydrate binding pathogens specifically and that the binding of free lectins can be controlled by the network density.

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Interactive Polymer Gels as Biomimetic Sensors for Carbohydrate Interactions and Capture–Release Devices for Pathogens

Cited by 16 publications

References 79 publications

Glycan Nanobiosensors

Glycan Nanobiosensors

Temperature‐Controlled Adhesion to Carbohydrate Functionalized Microgel Films: An E. coli and Lectin Binding Study

Lectin and E. coli Binding to Carbohydrate-Functionalized Oligo(ethylene glycol)-Based Microgels: Effect of Elastic Modulus, Crosslinker and Carbohydrate Density

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