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1.
Genome Characterization of Pseudomonas aeruginosa KT1115, a High Di-rhamnolipid-Producing Strain with Strong Oils Metabolizing Ability.
Curr Microbiol
; 77(8): 1890-1895, 2020 Aug.
Artículo
en Inglés
| MEDLINE | ID: mdl-32356168
2.
Enhancing rhamnolipid production through a two-stage fermentation control strategy based on metabolic engineering and nitrate feeding.
Bioresour Technol
; 388: 129716, 2023 Nov.
Artículo
en Inglés
| MEDLINE | ID: mdl-37689118
3.
Priority changes between biofilm exopolysaccharides synthesis and rhamnolipids production are mediated by a c-di-GMP-specific phosphodiesterase NbdA in Pseudomonas aeruginosa.
iScience
; 25(12): 105531, 2022 Dec 22.
Artículo
en Inglés
| MEDLINE | ID: mdl-36437878
4.
Construction and comparison of synthetic microbial consortium system (SMCs) by non-living or living materials immobilization and application in acetochlor degradation.
J Hazard Mater
; 438: 129460, 2022 09 15.
Artículo
en Inglés
| MEDLINE | ID: mdl-35803189
5.
Enhanced rhamnolipids production using a novel bioreactor system based on integrated foam-control and repeated fed-batch fermentation strategy.
Biotechnol Biofuels
; 13: 80, 2020.
Artículo
en Inglés
| MEDLINE | ID: mdl-32346396
6.
High Di-rhamnolipid Production Using Pseudomonas aeruginosa KT1115, Separation of Mono/Di-rhamnolipids, and Evaluation of Their Properties.
Front Bioeng Biotechnol
; 7: 245, 2019.
Artículo
en Inglés
| MEDLINE | ID: mdl-31696112
7.
Biomethane Production From Lignocellulose: Biomass Recalcitrance and Its Impacts on Anaerobic Digestion.
Front Bioeng Biotechnol
; 7: 191, 2019.
Artículo
en Inglés
| MEDLINE | ID: mdl-31440504
8.
Performance evaluation of a lab-scale moving bed biofilm reactor (MBBR) using polyethylene as support material in the treatment of wastewater contaminated with terephthalic acid.
Chemosphere
; 227: 117-123, 2019 Jul.
Artículo
en Inglés
| MEDLINE | ID: mdl-30986593
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