L. James Lee scite author profile

Polyaniline nanofibres can be prepared by a number of methods based on chemical oxidative polymerization and in situ adsorption polymerization. However, the lack of alignment in these nanostructures makes them unsuitable for many applications. Here, we report a simple approach to chemical oxidative polymerization that can control the growth and simultaneous alignment of polyaniline nanofibres grown on a range of conducting and non-conducting substrates in a wide variety of sizes. The diameters of the tips of the nanofibres can be controlled within the range 10-40 nm, and the average length can be controlled within the range 70-360 nm. Moreover, the coatings display a range of properties including superhydrophilicity and superhydrophobicity. Such nanostructured coatings may be useful for applications such as anti-fog coatings, self-cleaning surfaces, DNA manipulation, transparent electrodes for low-voltage electronics, and chemical and biological sensors.

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Cationic lipid-coated magnetic nanoparticles associated with transferrin for gene delivery

Pan

Guan

Yoo

et al. 2008

International Journal of Pharmaceutics

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Cationic lipid-coated magnetic nanoparticles (MPs) associated with transferrin were evaluated as gene transfer vectors in the presence of a static magnetic field. MPs were prepared by chemical precipitation and were surface-coated with cationic lipids, composed of DDAB/soy PC (60:40 mole/mole). These cationic MPs were then combined with polyethylenimine (PEI) condensed plasmid DNA, followed by transferrin. The resulting magnetic electrostatic complexes retained relatively compact particle size and showed complete DNA condensation. Their transfection activity in the presence of a static magnetic field was evaluated by luciferase and green fluorescent protein (GFP) reporter genes. The magnetic complexes exhibited up to 300-fold higher transfection activity compared to commonly used cationic liposomes or cationic polymer complexes, based on luciferase assay. The enhancement in transfection activity was maximized when the cells were exposed to the vectors for a relatively short period of time (15 min), or were treated in media containing 10% serum. Incorporation of transferrin further improved transfection efficiency of the cationic MPs. However, when cells were incubated for 4 h in serum-free media, magnetic and non-magnetic vectors showed similar transfection efficiencies. In conclusion, transferrin-associated cationic MPs are excellent gene transfer vectors that can mediate very rapid and efficient gene transfer in vitro in the presence of a magnetic field.

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Mold filling analysis in vacuum‐assisted resin transfer molding. Part I: SCRIMP based on a high‐permeable medium

Sun

Lee

1998

Polymer Composites

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Mold filling in SCRIMP based on a high‐permeable medium is complicated because of the considerable difference in the permeabilities of the fiber reinforcement, the peel ply and the high permeable medium. The objectives of this paper are to understand the flow mechanism through flow visualization experiments and to present models that can be used to predict the filling time and flow pattern. Permeabilities of a stitched fiber mat, a high‐permeable medium and a peel ply were measured. Flow visualization of SCRIMP mold filling was carried out under various molding conditions. It was found that although the resin flowed faster in the high‐permeable medium than in the fiber reinforcement, the flow front lead‐lag was not very large and it remained nearly constant through the entire mold filling process. A three‐dimensional Control Volume/Finite Element Method (CV/FEM) was adopted to solve the flow governing equations, i.e. the Darcy's law, and the influences of the flow properties of the high‐permeable medium, the fiber reinforcement and the peel ply on filling time were investigated. Based on experimental observations and CV/FEM simulation, a simplified leakage flow model is also presented. The comparison of experimental and simulation results show good agreement.

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Effect of Carbon Nanofibers on Mold Filling in a Vacuum Assisted Resin Transfer Molding System

Movva

Zhou

Guerra

et al. 2009

Journal of Composite Materials

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In this article, a new manufacturing method was used to prepare the hybrid composite, wherein carbon nanofibers were sprayed and bonded onto continuous fiber mats instead of pre-mixing them in the polymer resin. The effect of carbon nanofibers on the mold filling characteristics in a vacuum assisted resin transfer molding system was investigated. A simple one-dimensional flow model was used to correlate the permeability and porosity to the mold filling time. It was found that the dispersion and loading of the carbon nanofibers affected the permeability and porosity of the reinforcement system, and hence the mold filling time.

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Porous membrane controlled polymerization of nanofibers of polyaniline and its derivatives

2008

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L. James Lee

Growth and alignment of polyaniline nanofibres with superhydrophobic, superhydrophilic and other properties

Cationic lipid-coated magnetic nanoparticles associated with transferrin for gene delivery

Mold filling analysis in vacuum‐assisted resin transfer molding. Part I: SCRIMP based on a high‐permeable medium

Effect of Carbon Nanofibers on Mold Filling in a Vacuum Assisted Resin Transfer Molding System

Porous membrane controlled polymerization of nanofibers of polyaniline and its derivatives

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