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Using the High-Entropy Approach to Obtain Multimetal Oxide Nanozymes: Library Synthesis, In Silico Structure-Activity, and Immunoassay Performance.

Thuong Phan-XuanSimon SchweidlerSteffen HirteMoritz SchüllerLing LinAnurag KhandelwalKai WangJan SchuetzkeMarkus ReischlChristian KübelHorst HahnGianluca BelloJohannes KirchmairJasmin Aghassi-HagmannTorsten BrezesinskiBen BreitungLea Ann Dailey
Published in: ACS nano (2024)
High-entropy nanomaterials exhibit exceptional mechanical, physical, and chemical properties, finding applications in many industries. Peroxidases are metalloenzymes that accelerate the decomposition of hydrogen peroxide. This study uses the high-entropy approach to generate multimetal oxide-based nanozymes with peroxidase-like activity and explores their application as sensors in ex vivo bioassays. A library of 81 materials was produced using a coprecipitation method for rapid synthesis of up to 100 variants in a single plate. The A and B sites of the magnetite structure, (AA')(BB'B'') 2 O 4 , were substituted with up to six different cations (Cu/Fe/Zn/Mg/Mn/Cr). Increasing the compositional complexity improved the catalytic performance; however, substitutions of single elements also caused drastic reductions in the peroxidase-like activity. A generalized linear model was developed describing the relationship between material composition and catalytic activity. Binary interactions between elements that acted synergistically or antagonistically were identified, and a single parameter, the mean interaction effect, was observed to correlate highly with catalytic activity, providing a valuable tool for the design of high-entropy-inspired nanozymes.
Keyphrases
  • hydrogen peroxide
  • nitric oxide
  • molecular docking
  • physical activity
  • mental health
  • risk assessment
  • growth factor
  • sensitive detection
  • copy number
  • room temperature
  • low cost
  • aqueous solution
  • recombinant human