Multifunctional Silver-embedded Magnetic Nanoparticles As SERS Nanoprobes and Their Applications

Overview

Journal Small

Date 2009 Nov 12

PMID 19904763

Citations 34

Authors

Bong-Hyun Jun

Mi Suk Noh

Jaeyun Kim

Gunsung Kim

Homan Kang

Min-Soo Kim

Young-Tae Seo

Jongho Baek

Jong-Ho Kim

Juyoung Park

Seongyong Kim

Yong-Kweon Kim

Taeghwan Hyeon

Myung-Haing Cho

Dae Hong Jeong

Yoon-Sik Lee

Affiliations

Soon will be listed here.

Abstract

In this study, surface-enhanced Raman spectroscopy (SERS)-encoded magnetic nanoparticles (NPs) are prepared and utilized as a multifunctional tagging material for cancer-cell targeting and separation. First, silver-embedded magnetic NPs are prepared, composed of an 18-nm magnetic core and a 16-nm-thick silica shell with silver NPs formed on the surface. After simple aromatic compounds are adsorbed on the silver-embedded magnetic NPs, they are coated with silica to provide them with chemical and physical stability. The resulting silica-encapsulated magnetic NPs (M-SERS dots) produce strong SERS signals and have magnetic properties. In a model application as a tagging material, the M-SERS dots are successfully utilized for targeting breast-cancer cells (SKBR3) and floating leukemia cells (SP2/O). The targeted cancer cells can be easily separated from the untargeted cells using an external magnetic field. The separated targeted cancer cells exhibit a Raman signal originating from the M-SERS dots. This system proves to be an efficient tool for separating targeted cells. Additionally, the magnetic-field-induced hot spots, which can provide a 1000-times-stronger SERS intensity due to aggregation of the NPs, are studied.

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