posted on 2024-04-29, 15:33authored byMinli Mo, Yashuo Jiang, Aichun Kang, Kai Song, Hongbin Qi, Jing Li, Shanyue Guan, Shuyun Zhou
Redox nanozymes have demonstrated tremendous promise
in disrupting
cellular homeostasis toward cancer therapy, but a dysfunctional competition
of diverse activities makes it normally restricted by the complex
tumor microenvironment (TME). As palladium nanocrystals can achieve
the precise regulation of the enzyme-like activity by regulating exposed
crystal planes, noble metal nanoalloys can enhance the enzyme-like
activity by promoting electron transfer and enhanced active sites.
Herein, bimetallic nanoalloys with optimized enzymatic activity were
intelligently designed via the interaction between
the Pd and layered double hydroxide, denoted as PdCux@LDH. This PdCux@LDH is able to
produce long-lived singlet oxygen (1O2) with
high efficiency and selectivity for ultrasound-improved cancer therapy.
In addition, this PdCux@LDH nanozyme demonstrated
unique surface-dependent multienzyme-mimicking activities for catalyzing
cascade reactions: oxidase (OXD)- and catalase (CAT)-mimicking activities.
Interestingly, ultrasound (US) stimulation can further improve the
dual-enzyme-mimicking activities and impart superior reactive oxygen
species (ROS) generation activity, thereby further consuming nicotinamide
adenine dinucleotide (NADH) to cause mitochondrial dysfunction, resulting
in a highly efficient alloy nanozyme-mediated cancer therapy. This
work opens a new research avenue to apply nanozymes for effective
sonodynamic therapies (SDT).