In this work, we fabricated a monodisperse nanocomposite by coating gold nanorods (AuNRs) with a layer of biocompatible, stable carbon, obtaining AuNR@Carbon core-shell nanocapsules, which without any functionalizat...In this work, we fabricated a monodisperse nanocomposite by coating gold nanorods (AuNRs) with a layer of biocompatible, stable carbon, obtaining AuNR@Carbon core-shell nanocapsules, which without any functionalization could be used as a molecule loading material due to its high surface areas. In this system, the AuNR core had a high-absorption cross section for con- version of near-infrared light to heat, which could be ex- plored for local hyperthermia. The carbon shell, which was biocompatible and stable even under concentrated acidic and alkaline conditions, was able to adsorb molecules with n-n interactions or electrostatic interactions. In comparison with AuNR@SiO2, AuNR@Carbon nanocapsules demon- strate the following merits: (1) simple and green synthesis method, (2) far more stable with respect to high-tem- perature stability and (3) larger molecule loading capacity, which indicate great potential in the biomedical applications.展开更多
基金supported by the National Basic Research Program of China(2013CB932702)the Program on National Key Scientific Instruments and Equipment Development(2011YQ0301241402)+1 种基金the Science and Technology Development Fund of Macao S.A.R(FDCT,067/2014/A)the Hunan Innovation and Entrepreneurship Program
文摘In this work, we fabricated a monodisperse nanocomposite by coating gold nanorods (AuNRs) with a layer of biocompatible, stable carbon, obtaining AuNR@Carbon core-shell nanocapsules, which without any functionalization could be used as a molecule loading material due to its high surface areas. In this system, the AuNR core had a high-absorption cross section for con- version of near-infrared light to heat, which could be ex- plored for local hyperthermia. The carbon shell, which was biocompatible and stable even under concentrated acidic and alkaline conditions, was able to adsorb molecules with n-n interactions or electrostatic interactions. In comparison with AuNR@SiO2, AuNR@Carbon nanocapsules demon- strate the following merits: (1) simple and green synthesis method, (2) far more stable with respect to high-tem- perature stability and (3) larger molecule loading capacity, which indicate great potential in the biomedical applications.
