Tzu‐Wei Wang scite author profile

In recent years, the utilization of nanomaterials such as carbon nanotubes (CNTs) in the field of neuroscience has forever changed the approach to nerve-related research. The array of novel properties CNTs possess allows them to interact with neurons at the nanodimensional scale. In this study, a CNT rope substrate is developed to allow the electrical stimulation of neural stem cells (NSCs) in culture medium and the in situ observation of the response of these stem cells after stimulation. CNTs are synthesized by chemical vapor deposition and prepared into a ropelike structure with a diameter of 1 mm and length of 1.5 cm. NSCs are differentiated on the CNT rope substrate while the direction of neurite outgrowth, phenotype, and maturity of the NSCs are analyzed. Fluorescence and scanning electron microscopy demonstrate that neurite extension favors the direction of the spiral topography on the CNT rope. NSCs plated on CNT ropes are boosted towards differentiated neurons in the early culture stage when compared to conventional tissue culture plates via the analysis of neuronal gene and protein expressions by quantitative polymerase chain reaction and immunostaining, respectively. Furthermore, a set of electrical stimulation parameters (5 mV, 0.5 mA, 25 ms intermittent stimulation) promotes neuronal maturity while also increasing the speed of neurite outgrowth. These results indicate that an electroconductive CNT rope substrate along with electrical stimulation may have a synergistic effect on promoting neurite elongation and boosting effects on the differentiation of NSCs into mature neuronal cells for therapeutic application in neural regeneration.

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A novel biomagnetic nanoparticle based on hydroxyapatite

Wu¹,

Wang²,

Sun³

et al. 2007

Nanotechnology

116

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In the present study, magnetic HAP was synthesized at different ratios of Fe:Ca (XFe/Ca) by the co-precipitation method. We have evaluated the present essential properties including the crystal structure and cell parameters by XRD, lattice arrangement by HR-TEM, composition analysis by ICP-MS, and functional groups by FTIR. The morphology and magnetization were investigated by SEM and AFM and SQUID, respectively. The in vitro biocompatibility was also investigated with a lactate dehydrogenase assay. The results showed that the crystal and molecular structure of the synthesized magnetic-HAP nanoparticle remained unaltered without collapse with the addition of iron ions. The lattice constants of m-HAP were similar to reference JCPDS card no. 9-432. The magnetization of m-HAP nanoparticles increased with increasing XFe/Ca and possessed the superparamagnetic property with size distribution around 20 nm. The hydroxyapatite-based magnetic nanoparticles were also examined with good biocompatibility. With the appropriate physico-chemical and biological properties, the magnetic-HAP nanoparticles would have great potential to be applied in biomedical applications.

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Tzu‐Wei Wang

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Control of three-dimensional substrate stiffness to manipulate mesenchymal stem cell fate toward neuronal or glial lineages

Carbon Nanotube Rope with Electrical Stimulation Promotes the Differentiation and Maturity of Neural Stem Cells

A novel biomagnetic nanoparticle based on hydroxyapatite

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