Protein Interactions with Polymer Coatings and Biomaterials

Wei, Qiang; Becherer, Tobias; Angioletti‐Uberti, Stefano; Dzubiella, Joachim; Wischke, Christian; Neffe, Axel T.; Lendlein, Andreas; Ballauff, Matthias; Haag, Rainer

doi:10.1002/anie.201400546

Cited by 640 publications

(624 citation statements)

References 302 publications

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“…Description of all these methods would go far beyond the scope of this review; therefore, we direct the reader to excellent reviews on instrumental methods for protein-surface interactions including the orientation and conformation of adsorbed proteins. [9,34] …”

Section: Adsorption Influenced By Protein Molecular Propertiesmentioning

confidence: 99%

“…[37] Commonly applied strategies to functionalize materials' surfaces to control protein adsorption include monolayer (self-assembly, noncovalent physiosorption, and covalent chemisorption), and multilayer (layer-bylayer) coatings with polymers containing head anchor groups and functional tail chains. [9] Although a promising reduction in protein adsorption and thrombocyte activation has been reported, [38,39] homogeneous and long-term stable monolayer coatings on chemically inert surfaces, like those of polydimethylsiloxane (PDMS) and polytetrafluoroethylene (PTFE) polymers used in cardiovascular applications, still remain a challenge. For an overview on functional-groupmediated protein-biomaterial interactions as well as chemistryrelated surface modification techniques, the reader is referred to other reviews.…”

Section: Protein Adsorption Guided By Surface Physicochemical Factorsmentioning

confidence: 99%

“…For an overview on functional-groupmediated protein-biomaterial interactions as well as chemistryrelated surface modification techniques, the reader is referred to other reviews. [9,40] Surface wettability, generally referred to as hydrophobicity/ hydrophilicity, is another important factor affecting protein adsorption. As widely documented in the literature, the average footprint (unfolding) of a protein molecule [14] and the overall surface coverage [41] are larger on hydrophobic surfaces than on hydrophilic surfaces.…”

Section: Protein Adsorption Guided By Surface Physicochemical Factorsmentioning

confidence: 99%

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Controlling Protein Adsorption through Nanostructured Polymeric Surfaces

Firkowska‐Boden

Zhang

Jandt

2017

Adv Healthcare Materials

105

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The initial host response to healthcare materials' surfaces after implantation is the adsorption of proteins from blood and interstitial fluids. This adsorbed protein layer modulates the biological/cellular responses to healthcare materials. This stresses the significance of the surface protein assembly for the biocompatibility and functionality of biomaterials and necessitates a profound fundamental understanding of the capability to control protein–surface interactions. This review, therefore, addresses this by systematically analyzing and discussing strategies to control protein adsorption on polymeric healthcare materials through the introduction of specific surface nanostructures. Relevant proteins, healthcare materials' surface properties, clinical applications of polymer healthcare materials, fabrication methods for nanostructured polymer surfaces, amorphous, semicrystalline and block copolymers are considered with a special emphasis on the topographical control of protein adsorption. The review shows that nanostructured polymer surfaces are powerful tools to control the amount, orientation, and order of adsorbed protein layers. It also shows that the understanding of the biological responses to such ordered protein adsorption is still in its infancy, yet it has immense potential for future healthcare materials. The review, which is—as far as it is known—the first one discussing protein adsorption on nanostructured polymer surfaces, concludes with highlighting important current research questions.

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Section: Adsorption Influenced By Protein Molecular Propertiesmentioning

confidence: 99%

Section: Protein Adsorption Guided By Surface Physicochemical Factorsmentioning

confidence: 99%

Section: Protein Adsorption Guided By Surface Physicochemical Factorsmentioning

confidence: 99%

See 1 more Smart Citation

Controlling Protein Adsorption through Nanostructured Polymeric Surfaces

Firkowska‐Boden

Zhang

Jandt

2017

Adv Healthcare Materials

105

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“…[6] Due to the inherent low functionality of PEG (two end groups), no degradability, undesired oxidative degradation, and the presence of antibodies against PEGylated drugs make the search for alternatives valuable. [7] One promising material is poly(glycerol) (PG) derivative, which is accessible by highly controlled anionic polymerization with multiple functionality and architecture. [7,8] Also some commercial PG-based surfactants, such as poly glycerolpolyricinoleate, are known.…”

Section: Introductionmentioning

confidence: 99%

“…[7] One promising material is poly(glycerol) (PG) derivative, which is accessible by highly controlled anionic polymerization with multiple functionality and architecture. [7,8] Also some commercial PG-based surfactants, such as poly glycerolpolyricinoleate, are known. [9] Up to now, PG-based Pluronics are www.advancedsciencenews.com www.mbs-journal.…”

Section: Introductionmentioning

confidence: 99%

Polyglycerol Surfmers and Surfactants for Direct and Inverse Miniemulsion

Wald

Simon

Dietz

et al. 2017

Macromolecular Bioscience

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studied as promising surfactants for emulsions. [10] Furthermore, vinyl-terminated polyglycerols were used as surfmers to synthesize stable polystyrene (PS) microspheres for medical diagnostics for possible postfunctionalization with proteins. [11,12] Hyperbranched and linear surfmers based on polyglycerols were additionally used to generate stable PS nanoparticles. [13] However, for the miniemulsion approach only less multifunctional PG-based surfactants or surfmers are known.Here, we use the versatility of the anionic polymerization of glycidyl ethers to prepare a series of multifunctional (additional OH-groups or polymerizable CC-groups) surfactants with adjustable hydrophiliclipophilic balance (HLB) that allows the stabilization of direct (oil-in-water) or inverse (water-in-oil) (mini)emulsions or can be used simultaneously for both systems.Two known orthogonal protection strategies, reported by Möller and coworkers, [14] were used to synthesize linear completely poly glycerol-based block copolymers as surfactants or surfmers for direct, inverse, or both types of miniemulsions (Scheme 1). The orthogonal-protected block copolymers were generated by anionic ring-opening polymerization in bulk using ethoxyethyl glycidyl ether (EEGE) and allyl glycidyl ether (AGE) or tert-butyl glycidyl ether (tBuGE) with defined block length ratios to tune their HLB. After acidic hydrolysis of the acetal groups, the water-soluble allyl-functionalized PG block copolymers were established as surfmers in the radical miniemulsion poly merization of styrene to generate polystyrene nanoparticles with decreased protein adsorption behavior due to incorporated PG surfactants (Scheme 1). In addition, oil-soluble allyl-functionalized block copolymers were introduced as surfmers to produce polyurea/urethane nanocapsules by interfacial polyaddition reactions of hydroxyethyl starch (HES) with toluene diisocyanate (TDI) (Scheme 1). [15] Furthermore, the allyl-protection groups on the polyurethane nanocarrier surface were utilized for surface functionalization by thiol-ene addition in water. For this purpose, the nanocarriers were transferred into water including a tert-butyl-protected poly glycerol block copoly mer. The tert-butyl-protected polyglycerol block copolymers were applied as surfactant to generate polystyrene nanoparticles in direct miniemulsions for comparison with the allyl-protected surfmer and in inverse miniemulsions to produce stable poly(hydroxyethyl methacrylate) (PHEMA)

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