Abstract: Enhanced, specific nucleic acid targeting complexes comprising endo and exonuclease activity, and related methods that allow both targeted degradation of specific and/or non-specific nucleic acids in vivo and specific temporal regulation of nuclease activity to prevent off-target activity are disclosed herein. Through practice of the disclosure, nucleic acids, and cells harboring them, such as cancer cells or pathogens, are selectively degraded in vivo.

Abstract: Enhanced, specific nucleic acid targeting complexes comprising endo and exonuclease activity, and related methods that allow both targeted degradation of specific and/or non-specific nucleic acids in vivo and specific temporal regulation of nuclease activity to prevent off-target activity are disclosed herein. Through practice of the disclosure, nucleic acids, and cells harboring them, such as cancer cells or pathogens, are selectively degraded in vivo.

Abstract: Enhanced, specific nucleic acid targeting complexes comprising endo and exonuclease activity, and related methods that allow both targeted degradation of specific and/or non-specific nucleic acids in vivo and specific temporal regulation of nuclease activity to prevent off-target activity are disclosed herein. Through practice of the disclosure, nucleic acids, and cells harboring them, such as cancer cells or pathogens, are selectively degraded in vivo.

Abstract: Disclosed is a fabrication method of a metal nanoplate using metal, metal halide or a mixture thereof as a precursor. The single crystalline metal nanoplate is fabricated on a single crystalline substrate by performing heat treatment on a precursor including metal, metal halide or a mixture thereof and placed at a front portion of a reactor and the single crystalline substrate placed at a rear portion of the reactor under an inert gas flowing condition. A noble metal nanoplate of several micrometers in size can be fabricated using a vapor-phase transport process without any catalyst. The fabricated nanoplate is a single crystalline metal nanoplate having high crystallinity, high purity and not having a two-dimensional defect. Morphology and orientation of the metal nanoplate with respect to the substrate can be controlled by controlling a surface direction of the single crystalline substrate. The metal nanoplate of several micrometer size is mass-producible.

Abstract: Disclosed is a fabrication method of a metal nanoplate using metal, metal halide or a mixture thereof as a precursor, wherein the single crystalline metal nanoplate is fabricated on a single crystalline substrate by performing heat treatment on a precursor including metal, metal halide or a mixture thereof and placed at a front portion of a reactor and the single crystalline substrate placed at a rear portion of the reactor under an inert gas flowing condition.