Jeong-Ho An scite author profile

The fabrication of ultrathin silicon wafers at low cost is crucial for advancing silicon electronics toward stretchability and flexibility. However, conventional fabrication techniques are inefficient because they sacrifice a large amount of substrate material. Thus, advanced silicon electronics that have been realized in laboratories cannot move forward to commercialization. Here, a fully bottom‐up technique for producing a self‐releasing ultrathin silicon wafer without sacrificing any of the substrate is presented. The key to this approach is a self‐organized nanogap on the substrate fabricated by plasma‐assisted epitaxial growth (plasma‐epi) and subsequent hydrogen annealing. The wafer thickness can be independently controlled during the bulk growth after the formation of plasma‐epi seed layer. In addition, semiconductor devices are realized using the ultrathin silicon wafer. Given the high scalability of plasma‐epi and its compatibility with conventional semiconductor process, the proposed bottom‐up wafer fabrication process will open a new route to developing advanced silicon electronics.

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Dual drug-loaded nanoparticles on self-integrated scaffold for controlled delivery

Bennet¹,

Marimuthu²,

Kim³

et al. 2012

IJN

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Antioxidant (quercetin) and hypoglycemic (voglibose) drug-loaded poly-D,L-lactideco-glycolide nanoparticles were successfully synthesized using the solvent evaporation method. The dual drug-loaded nanoparticles were incorporated into a scaffold film using a solvent casting method, creating a controlled transdermal drug-delivery system. Key features of the film formulation were achieved utilizing several ratios of excipients, including polyvinyl alcohol, polyethylene glycol, hyaluronic acid, xylitol, and alginate. The scaffold film showed superior encapsulation capability and swelling properties, with various potential applications, eg, the treatment of diabetes-associated complications. Structural and light scattering characterization confirmed a spherical shape and a mean particle size distribution of 41.3 nm for nanoparticles in the scaffold film. Spectroscopy revealed a stable polymer structure before and after encapsulation. The thermoresponsive swelling properties of the film were evaluated according to temperature and pH. Scaffold films incorporating dual drug-loaded nanoparticles showed remarkably high thermoresponsivity, cell compatibility, and ex vivo drug-release behavior. In addition, the hybrid film formulation showed enhanced cell adhesion and proliferation. These dual drugloaded nanoparticles incorporated into a scaffold film may be promising for development into a transdermal drug-delivery system.

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Jeong-Ho An

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Dual drug-loaded nanoparticles on self-integrated scaffold for controlled delivery

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