Nanozyme Database

	ref	material	size	size err	size unit	size type	size comment	BET	b _nanozyme	b 10ⁿ	b unit	specific act	sa 10ⁿ	sa unit	comment
7875	659	Mn/Ni(OH)x LDHs	75.9		nm	TEM	After the coating procedure, transmission electron microscope (TEM) image in Figure 1b reveals a rough surface for the colloids, indicating the successful coating a layer of Mn/Ni-LDH on silica colloids. The thickness of the shell is ≈75.9 nm (Figure S2, Supporting Information).
7876	659	Mn/Ni(OH)x LDHs	37		nm	TEM	After the LDHs surface coating, Figure 1f,g; and Figure S6 (Supporting Information) reveals a rough surface for these silica rods. The shell thickness of the LDH coated on the silica rods is highly homogeneous with a value of ≈37 nm (Figure 1f).

	ref	material	enzyme type	substrate	pH	T	k_m	k_m err	k_m 10ⁿ	k_m unit	v_max	v_max err	v_max 10ⁿ	v_max unit	k_cat	k_cat err	k_cat 10ⁿ	k_cat unit	k_cat/k_m	k_cat/k_m 10ⁿ	k_cat/k_m unit	comment
6540	659	Mn/Ni(OH)x LDHs	OXD	TMB	3.6	RT	0.19			mM	63.77		-8	M/s					659

	ref	material	application	target	method	linear range	linear ran unit	LOD	lod unit	recovery	comment
5588	659	Mn/Ni(OH)x LDHs	antibacteria

	ref	title	DOI	material type	comment
3845	659	Colloidal Surface Engineering: Growth of Layered Double Hydroxides with Intrinsic Oxidase‐Mimicking Activities to Fight Against Bacterial Infection in Wound Healing	https://doi.org/10.1002/adhm.202000092	Composite	Here, a layer of Mn/Ni layered hydroxides (Mn/Ni(OH)x LDHs) can be successfully coated on various colloidal particles, such as silica spheres, silica rods, ferrite nanocrystal supraparticles, as well as FeOOH nanorods. Such layered hydroxides have intrinsic oxidase-mimetic activities, as demonstrated by catalytic oxidation of tetramethyl benzidine in the presence of oxygen.