posted on 2022-02-25, 16:34authored byZhanglu Lu, Na Lu, Yang Xiao, Yunqing Zhang, Zisheng Tang, Min Zhang
Convenient,
precise, and high-throughput discrimination of multiple
bioanalytes is of great significance for an early diagnosis of diseases.
Array-based pattern recognition has proven to be a powerful tool to
detect diverse analytes, but developing sensing elements featuring
favorable surface diversity still remains a challenge. In this work,
we presented a simple and facile method to prepare programmable metal-nanoparticle
(NP)-supported nanozymes (MNNs) as artificial receptors for the accurate
identification of multiple proteins and oral bacteria. The in situ
reduction of metal NPs on hierarchical MoS2 on polypyrrole
(PPy), which generated differential nonspecific interactions with
bioanalytes, was envisaged as the encoder to break through the limited
supply of the receptor’s quantity. As a proof of concept, three
metal NPs, i.e., Au, Ag, and Pd NPs, were taken as examples to deposit
on PPy@MoS2 as colorimetric probes to construct a cross-reactive
sensor array. Based on the principal component analysis (PCA), the
proposed MNN sensor array could well discriminate 11 proteins with
unique fingerprint-like patterns at a concentration of 250 nM and
was sufficiently sensitive to determine individual proteins with a
detection limit down to the nanomolar level. Remarkably, two highly
similar hemoglobins from different species (hemoglobin and bovine
hemoglobin) have been precisely identified. Additionally, five oral
bacteria were also well separated from each other without cross-classification
at the level of 107 CFU mL–1. Furthermore,
the sensor array allowed effective discrimination of complex protein
mixtures either at different molar ratios or with minor varying components.
Most importantly, the blind samples, proteins in human serums, proteins
in simulated body fluid environment, the heat-denatured proteins,
and even clinical cancer samples all could be well distinguished by
the sensor array, demonstrating the real-world applications in clinical
diagnosis.