Hydrolytic nanozymes: Preparation, properties, and applications

“…The diversity in the materials used for nanozymes, ranging from metal oxide nanoparticles 16 and metal nanoparticles 17 to intricate single-atom X–N–C mimetic architectures 18 and biomolecular assemblies, 19,20 underscores the rapid expansion in both the quantity and variety of enzyme-like species. Nanozymes, mimicking oxidoreductases, 21 hydrolases, 22 lyases, 23 and isomerases, 24 exhibit a remarkable diversity that transcends traditional enzyme functionalities. This diversity has paved the way for the realization of artificial enzymes that surpass their natural counterparts.…”

Machine learning in nanozymes: from design to application

“…The diversity in the materials used for nanozymes, ranging from metal oxide nanoparticles 16 and metal nanoparticles 17 to intricate single-atom X–N–C mimetic architectures 18 and biomolecular assemblies, 19,20 underscores the rapid expansion in both the quantity and variety of enzyme-like species. Nanozymes, mimicking oxidoreductases, 21 hydrolases, 22 lyases, 23 and isomerases, 24 exhibit a remarkable diversity that transcends traditional enzyme functionalities. This diversity has paved the way for the realization of artificial enzymes that surpass their natural counterparts.…”

Machine learning in nanozymes: from design to application

Leveraging mechanistic insight to design hydrolytic nanozymes

Advances in nanohydrolase-based pollutant sensing