Xia‐Chao Chen scite author profile

Layer‐by‐layer (LbL) self‐assemblies have inherent potential as dynamic coatings because of the sensitivity of their building blocks to external stimuli. Here, humidity serves as a feasible trigger to activate the self‐healing of a microporous polyethylenimine/poly(acrylic acid) multilayer film. Microporous structures within the polyelectrolyte multilayer (PEM) film are created by acid treatment, followed by freeze‐drying to remove water. The self‐healing of these micropores can be triggered at 100% relative humidity, under which condition the mobility of the polyelectrolytes is activated. Based on this, a facile and versatile method is suggested for directly integrating hydrophobic drugs into PEM films for surface‐mediated drug delivery. The high porosity of microporous film enables the highest loading (≈303.5 μg cm−2 for a 15‐bilayered film) of triclosan to be a one‐shot process via wicking action and subsequent solvent removal, thus dramatically streamlining the processes and reducing complexities compared to the existing LbL strategies. The self‐healing of a drug‐loaded microporous PEM film significantly reduces the diffusion coefficient of triclosan, which is favorable for the long‐term sustained release of the drug. The dynamic properties of this polymeric coating provide great potential for its use as a delivery platform for hydrophobic drugs in a wide variety of biomedical applications.

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Bactericidal and Hemocompatible Coating via the Mixed-Charged Copolymer

Fan

Qin

et al. 2018

ACS Appl. Mater. Interfaces

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Cationic antibacterial coating based on quaternary ammonium compounds, with an efficient and broad spectrum bactericidal property, has been widely used in various fields. However, the high density of positive charges tends to induce weak hemocompatibility, which hinders the application of the cationic antibacterial coating in blood-contacting devices and implants. It has been reported that a negatively charged surface can reduce blood coagulation, showing improved hemocompatibility. Here, we describe a strategy to combine the cationic and anionic groups by using mixed-charged copolymers. The copolymers of poly (quaternized vinyl pyridine- co- n-butyl methacrylate- co-methacrylate acid) [P(QVP- co- nBMA- co-MAA)] were synthesized through free radical copolymerization. The cationic group of QVP, the anionic group of MAA, and the hydrophobic group of nBMA were designed to provide bactericidal capability, hemocompatibility, and coating stability, respectively. Our findings show that the hydrophilicity of the copolymer coating increased, and its zeta potential decreased from positive charge to negative charge with the increase of the anionic/cationic ratio. Meanwhile, the bactericidal property of the copolymer coating was kept around a similar level compared with the pure quaternary ammonium copolymer coating. Furthermore, the coagulation time, platelet adhesion, and hemolysis tests revealed that the hemocompatibility of the copolymer coating improved with the addition of the anionic group. The mixed-charged copolymer combined both bactericidal property and hemocompatibility and has a promising potential in blood-contacting antibacterial devices and implants.

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Self-wrinkling polyelectrolyte multilayers: construction, smoothing and the underlying mechanism

Chen

Ren

Chen

et al. 2016

Phys. Chem. Chem. Phys.

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Introducing wrinkling or rough features into substrates is of great practical significance to construct various functional surfaces. Due to the sensitivity of assembled units towards environmental stimuli, the internals of layer-by-layer films can be readily adjusted to generate various micro- and nanostructures. We previously described a self-roughening polyelectrolyte multilayer (PEM) to facilitate the introduction of surface microstructures. In the present work, the growth process of PEI/PAA multilayer films was investigated and the mean size of the surface microstructures was found to increase linearly with the film thickness. The spontaneous formation of these surface features can be attributed to swelling-induced film deformation during the assembling process, which is similar to the surface wrinkling of hydrogels undergoing a volume phase transition. When exposed to saturated humidity, the internal stress as well as the surface microstructures can be diminished spontaneously, leading to a flat surface over the substrates. Given the effect of the underlying film thickness on the characteristic wavelength of the surface wrinkles, multiscale surface microstructures can be readily realized by means of spatially presetting the distribution of the film thickness.

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Surface modulation of complex stiffness via layer-by-layer assembly as a facile strategy for selective cell adhesion

Chang

Zhang

et al. 2015

Biomater. Sci.

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In-stent restenosis and thrombosis are the main severe problems that occur after the percutaneous vascular intervention. The competition between endothelial cells (ECs) and smooth muscle cells (SMCs) plays a key role during these pathological changes. The regulation of this competition offers new opportunities to design biomaterials in the cardiovascular fields. Bioactive molecules have been typically employed to increase EC adhesion and thereafter to enhance EC competitiveness; however, this method is associated with limitations from the point of view of practical and industrial applications. Herein, we present an approach to enhance EC competitiveness over that of SMC through the selective EC adhesion, which is achieved by modulating a complex surface stiffness based on the technique of layer-by-layer (LbL) assembly. This complex stiffness can be achieved by regulating the thickness of multilayer films coordinating with a rigid underlying substrate. The selective cell adhesion is attributed to changes in the complex surface stiffness and a different intrinsic property between ECs and SMCs. This study provides a facile and broadly applicable approach for the purpose of the enhancement of EC competitiveness over that of SMC, which has great potential for the development of cell-based functional biomaterials in the cardiovascular field.

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Xia‐Chao Chen

Polydopamine Nanocoating for Effective Photothermal Killing of Bacteria and Fungus upon Near‐Infrared Irradiation

Humidity‐Triggered Self‐Healing of Microporous Polyelectrolyte Multilayer Coatings for Hydrophobic Drug Delivery

Bactericidal and Hemocompatible Coating via the Mixed-Charged Copolymer

Self-wrinkling polyelectrolyte multilayers: construction, smoothing and the underlying mechanism

Surface modulation of complex stiffness via layer-by-layer assembly as a facile strategy for selective cell adhesion

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