Conspectus
Nanozymes
are nanomaterials with intrinsic enzyme-like characteristics
that have been booming over the past decade because of their capability
to address the limitations of natural enzymes such as low stability,
high cost, and difficult storage. Along with the rapid development
and ever-deepening understanding of nanoscience and nanotechnology,
nanozymes hold promise to serve as direct surrogates of traditional
enzymes by mimicking and further engineering the active centers of
natural enzymes. In 2007, we reported the first evidence that Fe3O4 nanoparticles (NPs) have intrinsic peroxidase-mimicking
activity, and since that time, hundreds of nanomaterials have been
found to mimic the catalytic activity of peroxidase, oxidase, catalase,
haloperoxidase, glutathione peroxidase, uricase, methane monooxygenase,
hydrolase, and superoxide dismutase. Uniquely, a broad variety of
nanomaterials have been reported to simultaneously exhibit dual- or
multienzyme mimetic activity. For example, Fe3O4 NPs show pH-dependent peroxidase-like and catalase-like activities;
Prussian blue NPs simultaneously possess peroxidase-, catalase-, and
superoxide dismutase-like activity; and Mn3O4 NPs mimic all three cellular antioxidant enzymes including superoxide
dismutase, catalase, and glutathione peroxidase. Taking advantage
of the physiochemical properties of nanomaterials, nanozymes have
shown a broad range of applications from in vitro detection to replacing
specific enzymes in living systems. With the emergence of the new
concept of “nanozymology”, nanozymes have now become
an emerging new field connecting nanotechnology and biology.
Since the landmark paper on nanozymes was published in 2007, we
have extensively explored their catalytic mechanism, established the
corresponding standards to quantitatively determine their catalytic
activities, and opened up a broad range of applications from biological
detection and environmental monitoring to disease diagnosis and biomedicine
development. Here we mainly focus on our progress in the systematic
design and construction of functionally specific nanozymes, the standardization
of nanozyme research, and the exploration of their applications for
replacing natural enzymes in living systems. We also show that, by
combining the unique physicochemical
properties and enzyme-like catalytic activities, nanozymes can offer
a variety of multifunctional platforms with a broad of applications
from in vitro detection to in vivo monitoring and therapy. For instance,
targeting antibody-conjugated ferromagnetic nanozymes simultaneously
provide three functions: target capture, magnetic separation, and
nanozyme color development for target detection. We finally will address
the prospect of nanozyme research to become “nanozymology”.
We expect that nanozymes with unique physicochemical properties and
intrinsic enzyme-mimicking catalytic properties will attract broad
interest in both fundamental research and practical applications and
offer new opportunities for traditional enzymology.
