Comparison of Coatings from Reactive Star Shaped PEG-<i>s</i><i>tat</i>-PPG Prepolymers and Grafted Linear PEG for Biological and Medical Applications

Cataract surgery is a routine ophthalmologic intervention resulting in replacement of the opacified natural lens by a polymeric intraocular lens (IOL). A main postoperative complication, as a result of protein adsorption and lens epithelial cell (LEC) adhesion, growth, and proliferation, is the secondary cataract, referred to as posterior capsular opacification (PCO). To avoid PCO formation, a poly(ethylene glycol) (PEG) chemical coating was created on the surface of hydrogel IOLs. Attenuated total reflectance Fourier transform infrared spectroscopy, “captive bubble” and “water droplet” contact angle measurements, and atomic force microscopy analyses proved the covalent grafting of the PEG chains on the IOL surface while keeping unchanged the optical properties of the initial material. A strong decrease of protein adsorption and cell adhesion depending on the molar mass of the grafted PEG (1100, 2000, and 5000 g/mol) was observed by performing the relevant in vitro tests with green fluorescent protein and LECs, respectively. Thus, the study provides a facile method for developing materials with nonfouling properties, particularly IOLs.

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“…Otsuka et al 38,39 reported a contact angle of water-in-air of 47°, to be compared to 40°in this work, for a PEG 5000 coating.…”

Section: Resultsmentioning

confidence: 50%

Improved Performances of Intraocular Lenses by Poly(ethylene glycol) Chemical Coatings

et al. 2007

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“…[33,34] The non-fouling properties of star PEG coatings were compared to surfaces modified with linear methoxy-terminated PEO chains and BSA. [33,73] In both cases, the star PEG system exhibited superior non-fouling properties. In contrast to the prevention of protein adsorption, films with thicknesses between 3 and 10 nm were not able to prevent non-specific cell adhesion under standard cell culture conditions (10% fetal calf serum).…”

Section: The Star Peg Systemmentioning

confidence: 99%

“…These amino groups have been detected by reaction with the non-fluorescent 4-chloro-7-nitrobenzofurazan (NBF) to the fluorescent derivative [34] and by gas-phase derivatization with pentafluorobenzaldehyde followed by X-ray photoelectron spectroscopy (XPS) analysis. [73] Thus, the surface will be covered by a densely crosslinked layer of PEG chains that contains a fraction of free amine groups that can be further functionalized. [74] Figure 3 shows the chemical reactions that occur during film formation and presents a model of the resulting surface coatings.…”

Section: The Star Peg Systemmentioning

confidence: 99%

Surface Grafting of PEO‐Based Star‐Shaped Molecules for Bioanalytical and Biomedical Applications

Gasteier

Reska

Schulte

et al. 2007

Macromolecular Bioscience

101

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This article reviews surface grafting of star-shaped PEO. The use of star-shaped polymers is compared to linear PEO chains regarding the layer preparation and the ability of the resulting surfaces to resist protein adsorption. We then focus on the use of end-functionalized, star-shaped, PEO-based prepolymers that are able to form covalent crosslinks and functional polymer networks on the substrate. Examples are given for specific protein adsorption as well as for cell adhesion on such layers by covalent embedding of biofunctional molecules. The possibility of coating biomedically relevant polymer substrates in three-dimensional geometries is discussed and examples are shown for poly(ethylene terephthalate) monofilament constructs.

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“…Recently, they have been widely investigated in terms of micellar aggregation in solution because of their well-defined macromolecular architecture [27,28]. In addition, the aggregates of star polymers which have amino groups, hydroxyl groups or carboxylic acid groups in the side chains have versatile applications in medicine and biology [29][30][31], catalytical chemistry [32][33][34], and nanotechnology [35,36]. For example, Kumacheva's group recently reported fast photoactivated synthesis of stable fluorescent silver nanoclusters [37] and other semiconductor or magnetic nanoparticles [38] by employing polymer microgels with concentrated carboxyl groups as templates.…”

Section: Introductionmentioning

confidence: 99%

Water-soluble starlike poly(acrylic acid) graft polymer: preparation and application as templates for silver nanoclusters

et al. 2011

Polym. Bull.

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Water-soluble starlike polymers containing concentrated carboxyl groups were conveniently synthesized via the combination of ''click'' chemistry and atom transfer radical polymerization. The starlike polymer was composed of a shorter polyacrylate main chain and longer poly(acrylic acid) side chains. Alkyne and azide groups were introduced to the structure units of the main chain by esterification and the chain end of the side chain by substitution reaction of NaN 3 to bromine, respectively. By click chemistry between alkyne and azide group, welldefined starlike polymers were obtained. FT-IR, gel permeation chromatography, and 1 H NMR were used to characterize the resulting polymers. Aggregation behavior demonstrated by transmission electron microscopy was observed when the starlike polymers were dispersed in water at pH 7.0-7.5. Using the starlike polymers as templates, water-soluble silver nanoclusters mainly consisting of Ag 2 supported by the generated nanoparticles and carboxyl groups were successfully synthesized. Also, their optical properties and morphology were characterized by UV-vis absorption spectra and TEM.

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Comparison of Coatings from Reactive Star Shaped PEG-stat-PPG Prepolymers and Grafted Linear PEG for Biological and Medical Applications

Cited by 106 publications

References 24 publications

Improved Performances of Intraocular Lenses by Poly(ethylene glycol) Chemical Coatings

Improved Performances of Intraocular Lenses by Poly(ethylene glycol) Chemical Coatings

Surface Grafting of PEO‐Based Star‐Shaped Molecules for Bioanalytical and Biomedical Applications

Water-soluble starlike poly(acrylic acid) graft polymer: preparation and application as templates for silver nanoclusters

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