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Increasing the diversity of nylonases for poly(ester amide) degradation
Jan de Witt
, Maike-Elisa Ostheller
, Kenneth Jensen
, Christian A. M. R. van Slagmaat
, Tino Polen
,
Gunnar Seide
, Stephan Thies
, Benedikt Wynands
, Nick Wierckx
*
*
Corresponding author for this work
AMIBM
Aachen-Maastricht Institute for Biobased Materials
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INIS
increasing
100%
esters
100%
amides
100%
polyamides
100%
recycling
80%
polymers
60%
depolymerization
60%
enzymes
40%
performance
40%
screening
20%
detection
20%
comparative evaluations
20%
space
20%
production
20%
libraries
20%
tuning
20%
engineering
20%
plastics
20%
hydrolysis
20%
nylon
20%
compost
20%
Keyphrases
Polyesteramide
100%
Nylonase
100%
Polyamide
83%
Biodegradability
33%
Recycling Rate
33%
Catalytic Depolymerization
33%
In Silico Analysis
16%
Strategies to Overcome
16%
Hydrolysis
16%
Sequence Identity
16%
Degradation Products
16%
Depolymerization
16%
Cutinase
16%
Nylon
16%
Global Production
16%
Enzyme Engineering
16%
Chemical Recycling
16%
Library Screening
16%
Mechanical Recycling
16%
Low Activity
16%
Engineering Strategies
16%
Arthrobacter Ureafaciens
16%
Plastic Crisis
16%
Sequence Spaces
16%
Enzymatic Recycling
16%
Chemistry
Polyamide
100%
Carboxamide
100%
Depolymerization
60%
Biodegradability
40%
Degradation Product
20%
Enzymatic Hydrolysis
20%
Oligomer
20%
Chemical Engineering
Polyester
100%
Amide
100%
Polyamide
100%
Oligomer
20%
Biochemistry, Genetics and Molecular Biology
Depolymerization
100%
Biodegradability
66%
Enzyme
33%
Enzymatic Hydrolysis
33%
Enzyme Engineering
33%
Cutinase
33%
Pharmacology, Toxicology and Pharmaceutical Science
Polyamide
100%
Carboxamide
100%
Oligomer
20%
Cutinase
20%