Engineering
Hydroxylation
100%
Aromatics
100%
Strain
66%
Aeration
66%
Substrates
66%
Limitations
33%
Process Development
33%
Inhibition
33%
High Potential
33%
Oxygen Specie
33%
Influencing Factor
33%
Chemistry
Aromatic Hydroxylation
100%
Water Type
100%
Procedure
66%
Biocatalyst
50%
Aeration
33%
Carbon
33%
Dioxygen
33%
Reactive Oxygen Species
16%
Chemical Reaction Product
16%
Donor
16%
Benzoate
16%
Cofactor
16%
Liquid
16%
% Inhibition
16%
Material Science
Molybdenum
100%
Water
100%
Biocatalyst
100%
Oxygenase
66%
Enzyme
33%
Liquid
33%
Toxicity
33%
Chemical Engineering
Water
100%
Molybdenum
100%
Oxygen
100%
Carbon
66%
Hydrocarbon
33%
Mass Transfer
33%
INIS
oxidases
100%
quinaldine
100%
molybdenum
50%
dehydrogenases
50%
oxygenases
33%
benzoates
16%
Pharmacology, Toxicology and Pharmaceutical Science
Pseudomonas putida
100%
Quinaldine
100%
Molybdenum
42%
Oxygenase
28%
Benzoic Acid
14%
Reactive Oxygen Metabolite
14%