Litcius/Paper detail

Ta@Ag Porous Array with High Stability and Biocompatibility for SERS Sensing of Bacteria

Dongzhen Chen, Pan Ning, Yu Zhang, Jinyu Jing, Meng Zhang, Liang Zhang, Jian Huang, Xinhai He, Tao Fu, Zhongxiao Song, Guangyu He, Dan Qian, Xiaodong Zhu

2020ACS Applied Materials & Interfaces45 citationsDOI

Abstract

The reliable sensing of bacteria by surface-enhanced Raman scattering (SERS) technology necessitates a rational design of a substrate with high sensitivity, stability, and minimal invasion. Hence, a bimetallic Ta@Ag film with a porous array is developed by the magnetron sputtering technique and the structure could be controlled by a Ta dopant. A porous array connected by ligaments with compact granular nanoprotrusions is a fascinating substrate for SERS sensing. It makes steady SERS signals even in harsh chemical environments due to its high structural and chemical stability. The configuration of binary Ta@Ag has higher surface free energy than that of pure Ag, and the strong bactericidal activity of Ag is suppressed efficiently. Using E. coli as a model pathogen, the Ta@Ag porous film could maintain the long-term survival rate of E. coli up to 95% and a limit of SERS detection of E. coli down to 102 CFU/mL, which is measured by the standard colony-counting method. In sum, this work provides a promising strategy to fabricate a corrosion-resistant and biocompatible bimetallic Ta@Ag film with a porous array for the SERS sensing of microbial cells.

Topics & Concepts

Materials scienceBimetallic stripSubstrate (aquarium)Raman scatteringPorosityBiocompatibilityNanotechnologySputter depositionChemical engineeringDetection limitChemical stabilitySputteringRaman spectroscopyThin filmComposite materialMetalOpticsChromatographyChemistryOceanographyMetallurgyEngineeringPhysicsGeologyGold and Silver Nanoparticles Synthesis and ApplicationsBiosensors and Analytical DetectionExtracellular vesicles in disease