posted on 2017-02-21, 00:00authored byJunji Zhang, Wenjing Ma, Xiao-Peng He, He Tian
Photoresponsive
smart surfaces are promising candidates for a variety of applications
in optoelectronics and sensing devices. The use of light as an order
signal provides advantages of remote and noninvasive control with
high temporal and spatial resolutions. Modification of the photoswitches
with target biomacromolecules, such as peptides, DNA, and small molecules
including folic acid derivatives and sugars, has recently become a
popular strategy to empower the smart surfaces with an improved detection
efficiency and specificity. Herein, we report the construction of
photoswitchable self-assembled monolayers (SAMs) based on sugar (galactose/mannose)-decorated
azobenzene derivatives and determine their photoswitchable, selective
protein/cell adhesion performances via electrochemistry. Under alternate
UV/vis irradiation, interconvertible high/low recognition and binding
affinity toward selective lectins (proteins that recognize sugars)
and cells that highly express sugar receptors are achieved. Furthermore,
the cis-SAMs with a low binding affinity toward selective
proteins and cells also exhibit minimal response toward unselective
protein and cell samples, which offers the possibility in avoiding
unwanted contamination and consumption of probes prior to functioning
for practical applications. Besides, the electrochemical technique
used facilitates the development of portable devices based on the
smart surfaces for on-demand disease diagnosis.