RESUMEN

The presence of approximately 200-bp cell-free DNA (cfDNA) in the urine has attracted attention as a biomarker for liquid biopsy. However, it is currently useful only for diagnoses of cancers in which a large amount of cfDNA is excreted in the urine. Therefore, the development of an efficient method for extracting cfDNA existing in small amounts in the urine is essential for diagnosing many other diseases. We examined the effect of particle size, small pore size (surface area), and surface modification of porous silica particles on the efficiency of DNA extraction. Our observations suggested that cfDNA could be captured by tertiary amine-modified particles and then removed from the particles by repeatedly washing with sodium bicarbonate (pH 11). Using this method with 30 mg of triamine-modified particles, we succeeded in extracting a few hundred nanograms of cfDNA from 15 mL urine. Furthermore, we could detect ~ 67 fg/mL caries DNA (211 bp) in 15 mL urine sample, suggesting that this method may be suitable for the extraction of genetic biomarkers for cfDNA-based liquid biopsy.

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RESUMEN

Broadband tunability is a central theme in contemporary nanophotonics and metamaterials research. Combining metamaterials with phase change media offers a promising approach to achieve such tunability, which requires a comprehensive investigation of the electromagnetic responses of novel materials at subwavelength scales. In this work, we demonstrate an innovative way to tailor band-selective electromagnetic responses at the surface of a heavy fermion compound, samarium sulfide (SmS). By utilizing the intrinsic, pressure sensitive, and multi-band electron responses of SmS, we create a proof-of-principle heavy fermion metamaterial, which is fabricated and characterized using scanning near-field microscopes with <50 nm spatial resolution. The optical responses at the infrared and visible frequency ranges can be selectively and separately tuned via modifying the occupation of the 4f and 5d band electrons. The unique pressure, doping, and temperature tunability demonstrated represents a paradigm shift for nanoscale metamaterial and metasurface design.

RESUMEN

We report the anisotropic changes in the electronic structure of a Kondo semiconductor CeOs(2)Al(10) across an anomalous antiferromagnetic ordering temperature (T(0)) of 29 K, using optical conductivity spectra. The spectra along the a and c axes indicate that an energy gap due to the hybridization between conduction bands and nearly local 4f states, namely the c-f hybridization gap, emerges from a higher temperature continuously across T(0). Along the b axis, on the other hand, another energy gap with a peak at 20 meV becomes visible at 39 K (>T(0)) and fully opens at T(0) because of a charge instability. This result implies that the appearance of the energy gap, as well as the change in the electronic structure along the b axis, induces the antiferromagnetic ordering below T(0).