Infection Resistant Surface Coatings by Polymer Brushes: Strategies to Construct and Applications

Dhingra, Sunil; Sharma, Shivangi; Saha, Sampa

doi:10.1021/acsabm.1c01006

Cited by 27 publications

(19 citation statements)

References 180 publications

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“…This may be attributed to the hydrated zwitterionic head group present in the polyDMAPS brush as revealed from its higher water uptake data (19.9%) as compared to the polyPEGMA brush (11.4%). [78][79][80][81] As expected, no antiadherent/antibacterial activity was observed for the P2 and P1 surface suggesting the role of hydrophilic brushes in repelling bacterial cells.…”

Section: Analysis Of Protein Adsorption On a Patterned Surfacesupporting

confidence: 64%

Photoinduced micropatterning on biodegradable aliphatic polyester surfaces for anchoring dual brushes and its application in bacteria and cell patterning

et al. 2023

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Section: Analysis Of Protein Adsorption On a Patterned Surfacesupporting

confidence: 64%

Photoinduced micropatterning on biodegradable aliphatic polyester surfaces for anchoring dual brushes and its application in bacteria and cell patterning

et al. 2023

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“…The past decade has witnessed the evolution of polymeric surface coatings from a simple protection barrier to a functional interface, which imparts functional attributes to the material through specific interactions and communication with its environment. In particular, polymeric coatings bearing bioactive ligands ranging from small molecules to biomacromolecules play a critical role in realizing various diagnostic and biosensing platforms. − For such applications, a polymeric coating that is stable in an aqueous environment, inherently anti-biofouling, and can be easily conjugated with biological probes is often desirable. In light of the demand for workability under aqueous conditions, as a general approach, hydrophilic polymers are chemically tethered onto the underlying inorganic substrate through either a “graft-to” or “graft-from” approach.…”

Section: Introductionmentioning

confidence: 99%

“Clickable” Polymer Brush Interfaces: Tailoring Monovalent to Multivalent Ligand Display for Protein Immobilization and Sensing

et al. 2022

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Facile and effective functionalization of the interface of polymer-coated surfaces allows one to dictate the interaction of the underlying material with the chemical and biological analytes in its environment. Herein, we outline a modular approach that would enable installing a variety of “clickable” handles onto the surface of polymer brushes, enabling facile conjugation of various ligands to obtain functional interfaces. To this end, hydrophilic anti-biofouling poly(ethylene glycol)-based polymer brushes are fabricated on glass-like silicon oxide surfaces using reversible addition–fragmentation chain transfer (RAFT) polymerization. The dithioester group at the chain-end of the polymer brushes enabled the installation of azide, maleimide, and terminal alkene functional groups, using a post-polymerization radical exchange reaction with appropriately functionalized azo-containing molecules. Thus, modified polymer brushes underwent facile conjugation of alkyne or thiol-containing dyes and ligands using alkyne–azide cycloaddition, Michael addition, and radical thiol–ene conjugation, respectively. Moreover, we demonstrate that the radical exchange approach also enables the installation of multivalent motifs using dendritic azo-containing molecules. Terminal alkene groups containing dendrons amenable to functionalization with thiol-containing molecules using the radical thiol–ene reaction were installed at the interface and subsequently functionalized with mannose ligands to enable sensing of the Concanavalin A lectin.

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“…Polymer brushes are increasingly being utilized for a broad range of biomedical applications, [1][2][3][4][5] ranging from tissue engineering and implant coatings, to cell patterning for cell-based assay development, or to regulate physico-chemical properties and the biofunctionalisation of biosensors. To a large extent, an essential theories, and coarse grain molecular dynamics simulations predicting an impact of the brush thickness, grafting density, solvation, and chemistry (impacting brush-macromolecule interactions) on the infiltration of brushes by proteins, particles, and polyelectrolytes.…”

Section: Introductionmentioning

confidence: 99%

“…Polymer brushes are increasingly being utilized for a broad range of biomedical applications, [ 1–5 ] ranging from tissue engineering and implant coatings, to cell patterning for cell‐based assay development, or to regulate physico‐chemical properties and the biofunctionalisation of biosensors. To a large extent, an essential brush property shared by most of these applications is the ability to regulate protein interactions and diffusion to substrates from which brushes are tethered.…”

Section: Introductionmentioning

confidence: 99%

The Architecture of Oligonucleotide‐Polycationic Brush Complexes – A Neutron Reflectometry Study

Gautrot

Chang

Alexis

et al. 2022

Adv Materials Inter

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brush property shared by most of these applications is the ability to regulate protein interactions and diffusion to substrates from which brushes are tethered. Hence, the exceptional protein resistance of polymer brushes enables to control their specificity of binding for biorecognition [6,7] or to promote cell adhesion, [8][9][10] whereas other brushes modulate the mechanism of adsorption and ultimate conformation of bioactive proteins. [11] In many cases, the ability of brushes to modulate protein-surface interactions and adsorption is associated with neutral brushes that do not promote strong interactions with other macromolecules.In contrast, densely charged polyelectrolyte brushes, such as those based on poly(dimethylaminoethyl methacrylate) (PDMAEMA) and poly(2-methacrylolyloxyethyltrimethylammonium iodide) (PMETAI), are expected to promote strong interactions, in particular with low isoelectric point proteins, at neutral pH, [12][13][14][15] a useful property to maximize the loading of surfaces with enzymes, for example. In addition, polycationic brushes have found application for gene delivery, owing to their ability to capture negatively charged DNA and RNA macromolecules. [16][17][18] Nanoparticles can be decorated with polycationic brushes that can capture genetic materials to be delivered upon internalization, presenting different core chemistries for imaging or to control degradation. [19,20] These nanomaterials, once loaded with oligonucleotides or plasmid DNA, can then be delivered to cells for evaluation of transfection efficiencies. [21,22] A range of different brush design parameters have been found to play crucial roles in regulating transfection efficiencies. Hence the grafting density and thickness of brushes were found to modulate the binding and infiltration of oligonucleotides and, in turn, the knockdown efficiency of siRNAs. [21] The type of buffer used to complex plasmid DNA was also found to regulate the morphology and surface density of adsorbed plasmids. [16] In turn, the brush chemistry was found to modulate the adsorption of oligonucleotides, and their rate of desorption upon internalization, through competitive binding with cytosolic macromolecules. [22] Therefore, the macromolecular structure and solution morphology of polymer brushes have been found to play important roles in regulating the adsorption and intercalation of oligonucleotides and plasmid DNA, and are proposed to control not only the complexation but also the cytosolic release of the genetic cargos. Such impact of polymer brush chemistry, structure, and morphology on macromolecular interactions is in good agreement with self-consistent field theories, scaling Polycationic brushes are attractive systems for the design of nanomaterials for gene delivery as they enable rational design of their architecture with a broad range of grafting densities, thicknesses, and chemistries. Recently, their performance for siRNA delivery is highlighted and the strong impact of their molecular architecture on RNA binding and transfecti...

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Infection Resistant Surface Coatings by Polymer Brushes: Strategies to Construct and Applications

Cited by 27 publications

References 180 publications

Photoinduced micropatterning on biodegradable aliphatic polyester surfaces for anchoring dual brushes and its application in bacteria and cell patterning

Photoinduced micropatterning on biodegradable aliphatic polyester surfaces for anchoring dual brushes and its application in bacteria and cell patterning

“Clickable” Polymer Brush Interfaces: Tailoring Monovalent to Multivalent Ligand Display for Protein Immobilization and Sensing

The Architecture of Oligonucleotide‐Polycationic Brush Complexes – A Neutron Reflectometry Study

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