Biofilm eradication by in situ generation of reactive chlorine species on nano-CuO surfaces

[1]  Xu Zhang,et al.  CuO nanoparticles as haloperoxidase-mimics: Chloride-accelerated heterogeneous Cu-Fenton chemistry for H2O2 and glucose sensing , 2019, Sensors and Actuators B: Chemical.

[2]  R. Briandet,et al.  Biofilms in Food Processing Environments: Challenges and Opportunities. , 2019, Annual review of food science and technology.

[3]  C. Ripolles-Avila,et al.  Biofilms in the Spotlight: Detection, Quantification, and Removal Methods. , 2018, Comprehensive reviews in food science and food safety.

[4]  M. Shukla,et al.  Nano-magnesium oxide reinforced polylactic acid biofilms for food packaging applications. , 2018, International journal of biological macromolecules.

[5]  Changha Lee,et al.  Chloride-enhanced oxidation of organic contaminants by Cu(II)-catalyzed Fenton-like reaction at neutral pH. , 2018, Journal of hazardous materials.

[6]  T. Coenye,et al.  The Role of Reactive Oxygen Species in Antibiotic-Mediated Killing of Bacteria. , 2017, Trends in microbiology.

[7]  K. Oakes,et al.  Chloride-accelerated Cu-Fenton chemistry for biofilm removal. , 2017, Chemical communications.

[8]  R. Amal,et al.  Iron Complex Facilitated Copper Redox Cycling for Nitric Oxide Generation as Nontoxic Nitrifying Biofilm Inhibitor. , 2016, ACS applied materials & interfaces.

[9]  Rafiq Ahmad,et al.  Outstanding Antibiofilm Features of Quanta-CuO Film on Glass Surface. , 2016, ACS applied materials & interfaces.

[10]  M. Hoffmann,et al.  Mixed-Metal Semiconductor Anodes for Electrochemical Water Splitting and Reactive Chlorine Species Generation: Implications for Electrochemical Wastewater Treatment , 2016 .

[11]  F. Cappitelli,et al.  Mini-review: Biofilm responses to oxidative stress , 2016, Biofouling.

[12]  Li Wang,et al.  Chloride accelerated Fenton chemistry for the ultrasensitive and selective colorimetric detection of copper. , 2016, Chemical communications.

[13]  D. Dionysiou,et al.  Degradation kinetics and mechanism of oxytetracycline by hydroxyl radical-based advanced oxidation processes , 2016 .

[14]  H. Beyenal,et al.  Electrochemical biofilm control: a review , 2015, Biofouling.

[15]  R. Amal,et al.  Copper Complex in Poly(vinyl chloride) as a Nitric Oxide-Generating Catalyst for the Control of Nitrifying Bacterial Biofilms. , 2015, ACS applied materials & interfaces.

[16]  Rong Wang,et al.  Simple method of deposition of CuO nanoparticles on a cellulose paper and its antibacterial activity , 2015 .

[17]  S. Rice,et al.  Nitric oxide: a key mediator of biofilm dispersal with applications in infectious diseases. , 2014, Current pharmaceutical design.

[18]  S. Dwivedi,et al.  Reactive Oxygen Species Mediated Bacterial Biofilm Inhibition via Zinc Oxide Nanoparticles and Their Statistical Determination , 2014, PloS one.

[19]  F. Villa,et al.  Biofilm Formation in Food Processing Environments is Still Poorly Understood and Controlled , 2014, Food Engineering Reviews.

[20]  M. Cormican,et al.  Commonly Used Disinfectants Fail To Eradicate Salmonella enterica Biofilms from Food Contact Surface Materials , 2013, Applied and Environmental Microbiology.

[21]  Ursula Jakob,et al.  Bacterial responses to reactive chlorine species. , 2013, Annual review of microbiology.

[22]  T. Thongtem,et al.  Antimicrobial activities of CuO films deposited on Cu foils by solution chemistry , 2013 .

[23]  A. Kettle,et al.  Myeloperoxidase: a front‐line defender against phagocytosed microorganisms , 2013, Journal of leukocyte biology.

[24]  W. Tremel,et al.  Vanadium pentoxide nanoparticles mimic vanadium haloperoxidases and thwart biofilm formation. , 2012, Nature nanotechnology.

[25]  Diane McDougald,et al.  Should we stay or should we go: mechanisms and ecological consequences for biofilm dispersal , 2011, Nature Reviews Microbiology.

[26]  O. Akhavan,et al.  CuO/Cu(OH) 2 hierarchical nanostructures as bactericidal photocatalysts , 2011 .

[27]  Efstathios Z Panagou,et al.  Use of titanium dioxide (TiO2) photocatalysts as alternative means for Listeria monocytogenes biofilm disinfection in food processing. , 2011, Food microbiology.

[28]  R. Allaker,et al.  The Use of Nanoparticles to Control Oral Biofilm Formation , 2010, Journal of dental research.

[29]  N. S. Das,et al.  CuO nanostructures on copper foil by a simple wet chemical route at room temperature , 2010 .

[30]  M. Elimelech,et al.  Toxic effects of single-walled carbon nanotubes in the development of E. coli biofilm. , 2010, Environmental science & technology.

[31]  M. Vieira,et al.  A review of current and emergent biofilm control strategies , 2010 .

[32]  Yinglei Xu,et al.  Antibacterial activity of chitosan tripolyphosphate nanoparticles loaded with various metal ions , 2009 .

[33]  Yi-Cheng Su,et al.  Effects of electrolyzed oxidizing water on reducing Listeria monocytogenes contamination on seafood processing surfaces. , 2006, International journal of food microbiology.

[34]  S. Klebanoff Myeloperoxidase: friend and foe , 2005, Journal of leukocyte biology.

[35]  J. Albrich,et al.  Oxidative inactivation of Escherichia coli by hypochlorous acid , 1982, FEBS letters.

[36]  W. Tremel,et al.  Haloperoxidase Mimicry by CeO2−x Nanorods Combats Biofouling , 2017, Advanced materials.

[37]  B. Cammue,et al.  Reactive oxygen species-inducing antifungal agents and their activity against fungal biofilms. , 2014, Future medicinal chemistry.