1 research outputs found
A Localized Surface Plasmon Resonance Imaging Instrument for Multiplexed Biosensing
Localized
surface plasmon resonance (LSPR) spectroscopy has been
widely used for label-free, highly sensitive measurements of interactions
at a surface. LSPR imaging (LSPRi) has the full advantages of LSPR
but enables high-throughput, multiplexed measurements by simultaneously
probing multiple individually addressable sensors on a single sample
surface. Each spatially distinct sensor can be tailored to provide
data regarding different surface functionalities or reaction environments.
Previously, LSPRi has focused on single-particle sensing where the
size scale is very small. Here, we create defined macroscale arrays
of nanoparticles that are compatible with common patterning methods
such as dip-pen nanolithography and multichannel microfluidic delivery
devices. With this new LSPR sensing format, we report the first demonstration
of multiplexed LSPR imaging and show that the increased throughput
of our instrument enables the collection of a complete Langmuir binding
curve on a single sensor surface. In addition, the multiplexed LSPR
sensor is highly selective, as demonstrated by the hybridization of
single-stranded DNA to complementary sequences immobilized on the
sensor surface. The LSPR arrays described in this work exhibit uniform
sensitivity and tailorable optical properties, making them an ideal
platform for high-throughput, label-free analysis of a variety of
molecular binding interactions