41 results on '"Michal Natan"'
Search Results
2. Photoactive Antimicrobial CuZnO Nanocrystals
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Shira Gigi, Tom Naor, Nir Waiskopf, David Stone, Michal Natan, Gila Jacobi, Adar Levi, Sergei Remennik, Yael Levi-Kalisman, Ehud Banin, and Uri Banin
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General Energy ,Physical and Theoretical Chemistry ,Surfaces, Coatings and Films ,Electronic, Optical and Magnetic Materials - Published
- 2022
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3. Fluorine-Free Superhydrophobic Coating with Antibiofilm Properties Based on Pickering Emulsion Templating
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Gila Jacobi, Ayelet Atkins, Einat Zelinger, Ehud Banin, Noga Yaakov, Elazar Fallik, Michal Natan, Karthik Ananth Mani, Guy Mechrez, and Mor Maayan
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Polypropylene ,Materials science ,Polydimethylsiloxane ,Xylenes ,engineering.material ,Silicon Dioxide ,Superhydrophobic coating ,Pickering emulsion ,Anti-Bacterial Agents ,chemistry.chemical_compound ,chemistry ,Coating ,Chemical engineering ,Biofilms ,Emulsion ,Escherichia coli ,engineering ,Emulsions ,General Materials Science ,Dimethylpolysiloxanes ,Hydrophobic and Hydrophilic Interactions ,Nanoscopic scale ,Toluene ,Hydrophobic silica - Abstract
This study presents antibiofilm coating formulations based on Pickering emulsion templating. The coating contains no bioactive material because its antibiofilm properties stem from passive mechanisms that derive solely from the superhydrophobic nature of the coating. Moreover, unlike most of the superhydrophobic formulations, our system is fluorine-free, thus making the method eminently suitable for food and medical applications. The coating formulation is based on water in toluene or xylene emulsions that are stabilized using commercial hydrophobic silica, with polydimethylsiloxane (PDMS) dissolved in toluene or xylene. The structure of the emulsions and their stability was characterized by confocal microscopy and cryogenic-scanning electron microscopy (cryo-SEM). The most stable emulsions are applied on polypropylene (PP) surfaces and dried in an oven to form PDMS/silica coatings in a process called emulsion templating. The structure of the resulting coatings was investigated by atomic force microscopy (AFM) and SEM. The surface of the coatings shows a honeycomb-like structure that exhibits a combination of micron-scale and nanoscale roughness, which endows it with its superhydrophobic properties. After tuning, the superhydrophobic properties of the coatings demonstrated highly efficient passive antibiofilm activity. In vitro antibiofilm trials with E. coli indicate that the coatings reduced the biofilm accumulation by 83% in the xylene-water-based surfaces and by 59% in the case of toluene-water-based surfaces.
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- 2021
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4. Cuprous Oxide Nanoparticles Decorated Fabric Materials with Anti-biofilm Properties
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Akanksha Gupta, Moorthy Maruthapandi, Poushali Das, Arumugam Saravanan, Gila Jacobi, Michal Natan, Ehud Banin, John H. T. Luong, and Aharon Gedanken
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Biomaterials ,Biochemistry (medical) ,Biomedical Engineering ,General Chemistry - Abstract
Considering the global spread of bacterial infections, the development of anti-biofilm surfaces with high antimicrobial activities is highly desired. This work unraveled a simple, sonochemical method for coating Cu
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- 2022
5. Biofilm-Protected Catheters Nanolaminated by Multiple Atomic-Layer-Deposited Oxide Films
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Shira Frank, Gila Jacobi, Ehud Banin, Malachi Noked, Michal Natan, Reut Yemini, Hagit Aviv, and Melina Zysler
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chemistry.chemical_compound ,Materials science ,chemistry ,Chemical engineering ,Oxide ,Biofilm ,General Materials Science ,Layer (electronics) - Published
- 2021
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6. Antibacterial, Antibiofilm, and Antiviral Farnesol-Containing Nanoparticles Prevent
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Aleksandra, Ivanova, Kristina, Ivanova, Luisa, Fiandra, Paride, Mantecca, Tiziano, Catelani, Michal, Natan, Ehud, Banin, Gila, Jacobi, and Tzanko, Tzanov
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Methicillin-Resistant Staphylococcus aureus ,Staphylococcus aureus ,SARS-CoV-2 ,Biofilms ,COVID-19 ,Humans ,Nanoparticles ,Microbial Sensitivity Tests ,Staphylococcal Infections ,Antiviral Agents ,Farnesol ,Drug Resistance, Multiple ,Anti-Bacterial Agents - Abstract
Multidrug antimicrobial resistance is a constantly growing health care issue associated with increased mortality and morbidity, and huge financial burden. Bacteria frequently form biofilm communities responsible for numerous persistent infections resistant to conventional antibiotics. Herein, novel nanoparticles (NPs) loaded with the natural bactericide farnesol (FSL NPs) are generated using high-intensity ultrasound. The nanoformulation of farnesol improved its antibacterial properties and demonstrated complete eradication of
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- 2022
7. Carbon Dots for Heavy-Metal Sensing, pH-Sensitive Cargo Delivery, and Antibacterial Applications
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Michal Natan, Moorthy Maruthapandi, Arumugam Saravanan, Ehud Banin, Poushali Das, Aharon Gedanken, and Gila Jacobi
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Metal ,Materials science ,Fabrication ,chemistry ,visual_art ,Drug delivery ,visual_art.visual_art_medium ,chemistry.chemical_element ,General Materials Science ,Nanotechnology ,Antibacterial activity ,Carbon - Abstract
Currently, the technologies accompanying the usage of waste materials for the fabrication of innovative useful materials have been significantly advanced. For the same purpose, a possible sustainab...
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- 2020
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8. Antimicrobial Activities of Zn-Doped CuO Microparticles Decorated on Polydopamine against Sensitive and Antibiotic-Resistant Bacteria
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Aharon Gedanken, Ehud Banin, Gila Jacobi, Poushali Das, Arumugam Saravanan, John H. T. Luong, Moorthy Maruthapandi, and Michal Natan
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Antibiotic resistance ,Polymers and Plastics ,X-ray photoelectron spectroscopy ,Chemistry ,Process Chemistry and Technology ,Sonication ,Organic Chemistry ,Composite number ,Zn doped ,Fourier transform infrared spectroscopy ,Antimicrobial ,Nuclear chemistry - Abstract
A polydopamine (PDA) composite was synthesized by depositing Zn-doped CuO (Zn@CuO) particles on polydopamine by one-step ultrasonication. XPS, XRD, and FTIR confirmed the formation of spherical Zn@...
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- 2020
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9. Antibacterial, antibiofilm, and antiviral farnesol-containing nanoparticles prevent Staphylococcus aureus from drug resistance development
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Aleksandra Ivanova, Kristina Ivanova, Luisa Fiandra, Paride Mantecca, Tiziano Catelani, Michal Natan, Ehud Banin, Gila Jacobi, Tzanko Tzanov, Ivanova, A, Ivanova, K, Fiandra, L, Mantecca, P, Catelani, T, Natan, M, Banin, E, Jacobi, G, Tzanov, T, Universitat Politècnica de Catalunya. Departament d'Enginyeria Química, and Universitat Politècnica de Catalunya. GBMI - Grup de Biotecnologia Molecular i Industrial
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farnesol nanoparticle ,SARS-CoV-2 ,Organic Chemistry ,bacterial eradication ,Biocompatibilitat ,General Medicine ,COVID-19 (Malaltia) ,Catalysis ,Computer Science Applications ,Inorganic Chemistry ,Farnesol nanoparticles ,biocompatibility ,farnesol nanoparticles ,biofilm prevention and elimination ,COVID-19 (Disease) ,Enginyeria química [Àrees temàtiques de la UPC] ,Biofilm prevention and elimination ,Biocompatibility ,Bacterial eradication ,Physical and Theoretical Chemistry ,Molecular Biology ,Spectroscopy - Abstract
Multidrug antimicrobial resistance is a constantly growing health care issue associated with increased mortality and morbidity, and huge financial burden. Bacteria frequently form biofilm communities responsible for numerous persistent infections resistant to conventional antibiotics. Herein, novel nanoparticles (NPs) loaded with the natural bactericide farnesol (FSL NPs) are generated using high-intensity ultrasound. The nanoformulation of farnesol improved its antibacterial properties and demonstrated complete eradication of Staphylococcus aureus within less than 3 h, without inducing resistance development, and was able to 100% inhibit the establishment of a drug-resistant S. aureus biofilm. These antibiotic-free nano-antimicrobials also reduced the mature biofilm at a very low concentration of the active agent. In addition to the outstanding antibacterial properties, the engineered nano-entities demonstrated strong antiviral properties and inhibited the spike proteins of SARS-CoV-2 by up to 83%. The novel FSL NPs did not cause skin tissue irritation and did not induce the secretion of anti-inflammatory cytokines in a 3D skin tissue model. These results support the potential of these bio-based nano-actives to replace the existing antibiotics and they may be used for the development of topical pharmaceutic products for controlling microbial skin infections, without inducing resistance development.
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- 2022
10. An Engineered Nanocomplex with Photodynamic and Photothermal Synergistic Properties for Cancer Treatment
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Eli Varon, Gaddi Blumrosen, Moshe Sinvani, Elina Haimov, Shlomi Polani, Michal Natan, Irit Shoval, Avi Jacob, Ayelet Atkins, David Zitoun, and Orit Shefi
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Membrane Potential, Mitochondrial ,Photosensitizing Agents ,Cell Survival ,Lasers ,Organic Chemistry ,Metal Nanoparticles ,General Medicine ,Phototherapy ,Combined Modality Therapy ,Catalysis ,Computer Science Applications ,Inorganic Chemistry ,Photochemotherapy ,engineering ,biomaterials ,phototherapy ,cancer ,nanoparticles ,Cell Line, Tumor ,Neoplasms ,Humans ,Gold ,Physical and Theoretical Chemistry ,Molecular Biology ,Spectroscopy - Abstract
Photodynamic therapy (PDT) and photothermal therapy (PTT) are promising therapeutic methods for cancer treatment; however, as single modality therapies, either PDT or PTT are still limited in their success rate. A dual application of both PDT and PTT, in a combined protocol, has gained immense interest. In this study, gold nanoparticles (AuNPs) are conjugated with a PDT agent, meso-tetrahydroxyphenylchlorin (mTHPC) photosensitizer, designed as nanotherapeutic agents that can activate a dual photodynamic/photothermal therapy.The AuNP-mTHPC complex is biocompatible, soluable, and photostable. PDT efficiency is high because of immediate reactive oxygen species (ROS) production upon mTHPC activation by the 650 nm laser which decreased mitochondrial membrane potential (ΔΨm). Likewise, the AuNP-mTHPC complex is used as a photoabsorbing (PTA) agent for PTT, due to efficient plasmon absorption and excellent photothermal conversion characteristics of AuNPs under laser irradiation at 532 nm. Under the laser irradiation of a PDT/PTT combination, a twofold phototoxicity outcome follows, compared to PDT-only or PTT-only treatment. This indicates that PDT and PTT have synergistic effects together as a combined therapeutic method. Hence, applying our AuNP-mTHPC may be a potential treatment of cancer in the biomedical field.Abstract Figure
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- 2021
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11. Non-radical synthesis of chitosan-quercetin polysaccharide: Properties, bioactivity and applications
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Yevgenia Shebis, Alexander Laskavy, Anat Molad-Filossof, Hadar Arnon-Rips, Michal Natan-Warhaftig, Gila Jacobi, Elazar Fallik, Ehud Banin, and Elena Poverenov
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Chitosan ,Cucurbitaceae ,Polymers and Plastics ,Polysaccharides ,Organic Chemistry ,Materials Chemistry ,Quercetin ,Antioxidants - Abstract
Quercetin-chitosan (QCS) polysaccharide was synthesized via non-radical reaction using L-valine-quercetin as the precursor. QCS was systematically characterized and demonstrated amphiphilic properties with self-assembling ability. In-vitro activity studies confirmed that quercetin grafting does not diminish but rather increases antimicrobial activity of the original chitosan (CS) and provided the modified polysaccharide with antioxidative properties. QCS applied as a coating on fresh-cut fruit reduced microbial spoilage and oxidative browning of coated melon and apple, respectively. Notably, QCS-based coatings prevented moisture loss, a major problem with fresh produce (2%, 12% and 18% moisture loss for the QCS-coated, CS-coated and uncoated fruit, respectively). The prepared QCS polysaccharide provides advanced bioactivity and does not involve radical reactions during its synthesis, therefore, it has good potential for use as a nature-sourced biocompatible active material for foods and other safety-sensitive applications.
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- 2021
12. In Situ Grafting of Silica Nanoparticle Precursors with Covalently Attached Bioactive Agents to Form PVA-Based Materials for Sustainable Active Packaging
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Elena Poverenov, Victor Rodov, Anat Molad Filossof, Ehud Banin, Sefi Vernick, Miri Klein, Idan Ashur, and Michal Natan-Warhaftig
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In situ ,Antioxidant ,active package ,antioxidant ,Polymers and Plastics ,integumentary system ,medicine.medical_treatment ,Active packaging ,Organic chemistry ,General Chemistry ,Grafting ,Polyvinyl alcohol ,Article ,chemistry.chemical_compound ,QD241-441 ,polyvinyl alcohol ,Chemical engineering ,chemistry ,Covalent bond ,silica nanoparticle ,Curcumin ,medicine ,antimicrobial ,Benzoic acid - Abstract
Sustainable antibacterial–antioxidant films were prepared using in situ graftings of silica nanoparticle (SNP) precursors with covalently attached bioactive agents benzoic acid (ba) or curcumin (cur) on polyvinyl alcohol (PVA). The modified PVA-SNP, PVA-SNP-ba and PVA-SNP-cur films were characterized using spectroscopic, physicochemical and microscopic methods. The prepared films showed excellent antibacterial and antioxidant activity, and increased hydrophobicity providing protection from undesired moisture. The PVA-SNP-ba films completely prevented the growth of the foodborne human pathogen Listeria innocua, whereas PVA-SNP-cur resulted in a 2.5 log reduction of this bacteria. The PVA-SNP-cur and PVA-SNP-ba films showed high antioxidant activity of 15.9 and 14.7 Mm/g TEAC, respectively. The described approach can serve as a generic platform for the formation of PVA-based packaging materials with tailor-made activity tuned by active substituents on silica precursors. Application of such biodegradable films bearing safe bioactive agents can be particularly valuable for advanced sustainable packaging materials in food and medicine.
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- 2021
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13. Poly(styryl bisphosphonate) nanoparticles with a narrow size distribution: Synthesis, characterization and antibacterial applications
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Michal Natan, Safra Rudnick-Glick, Hanna P. Steinmetz, Shlomo Margel, and Ehud Banin
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Polymers and Plastics ,Chemistry ,Organic Chemistry ,technology, industry, and agriculture ,General Physics and Astronomy ,chemistry.chemical_element ,Nanoparticle ,02 engineering and technology ,Calcium ,010402 general chemistry ,021001 nanoscience & nanotechnology ,medicine.disease_cause ,01 natural sciences ,Combinatorial chemistry ,Bacterial cell structure ,0104 chemical sciences ,chemistry.chemical_compound ,Monomer ,Polymerization ,Materials Chemistry ,medicine ,Methacrylamide ,0210 nano-technology ,Antibacterial activity ,Escherichia coli - Abstract
Bacterial resistance to antibiotics is a major challenge in health research. A recent approach to combat this resistance is by interfering with vital bacterial functional systems. Calcium ions play an important role in bacterial functions such as bacterial cell stability, regulation of virulence genes, and in the function of various intracellular proteins. Bisphosphonate compounds have a high affinity for calcium ions and the antibacterial activity of bisphosphonates in combination with antibiotics has been recently studied. However, the antibacterial behavior of the bisphosphonate group itself has hardly been investigated. New cross-linked poly(styryl bisphosphonate) nanoparticles (poly(StBP) NPs) with a narrow size distribution and high yield were engineered using a dispersion copolymerization of styryl bisphosphonate monomer with the cross-linking monomer triethylene glycol diacrylate and the primary amino monomer N-(3-aminopropyl) methacrylamide hydrochloride. The diameter and size distribution were controlled by changing various polymerization parameters. Fluorescent poly(StBP) NPs were prepared by covalent binding of the primary amino groups on the poly(StBP) NPs surface to the dye BODIPY-FL-NHS ester; these NPs demonstrated a strong affinity for calcium ions. Antibacterial properties of optimal poly(StBP) NPs were studied compared to control NPs, which contain a methoxy group instead the bisphosphonate functional group. Unlike the control NPs, the poly(StBP) NPs demonstrated a significant antibacterial activity for both Gram negative (Escherichia coli and Pseudomonas aeruginosa) and Gram-positive (Staphylococcus aureus and Bacillius subtilis) bacteria.
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- 2019
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14. Prevention and Treatment of Pseudomonas Aeruginosa-Based Biofilm with Ethanol
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Michal, Natan, Gila, Jacobi, Ehud, Banin, and Shai, Ashkenazi
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Ethanol ,Biofilms ,Catheter-Related Infections ,Pseudomonas aeruginosa ,Anti-Infective Agents, Local ,Humans ,Pseudomonas Infections ,Microbial Sensitivity Tests - Abstract
Although indwelling catheters are increasingly used in modern medicine, they can be a source of microbial contamination and hard-to-treat biofilms, which jeopardize patient lives. At times 70% ethanol is used as a catheter-lock solution due to its bactericidal properties. However, high concentrations of ethanol can result in adverse effects and in malfunction of the catheters.To determine whether low concentrations of ethanol can prevent and treat biofilms of Pseudomonas aeruginosa.Ethanol was tested at a concentration range of 0.625-80% against laboratory and clinical isolates of P. aeruginosa for various time periods (2-48 hours). The following parameters were evaluated following ethanol exposure: prevention of biofilm formation, reduction of biofilm metabolic activity, and inhibition of biofilm regrowth.Exposing P. aeruginosa to twofold ethanol gradients demonstrated a significant biofilm inhibition at concentrations as low as 2.5%. Treating pre-formed biofilms of P. aeruginosa with 20% ethanol for 4 hours caused a sharp decay in the metabolic activity of both the laboratory and clinical P. aeruginosa isolates. In addition, treating mature biofilms with 20% ethanol prevented the regrowth of bacteria encased within it.Low ethanol concentrations (2.5%) can prevent in vitro biofilm formation of P. aeruginosa. Treatment of previously formed biofilms can be achieved using 20% ethanol, thereby keeping the catheters intact and avoiding complications that can result from high ethanol concentrations.
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- 2020
15. Small molecule-decorated gold nanoparticles for preparing antibiofilm fabrics
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Ilana Perelshtein, Le Wang, Gila Jacobi, Ehud Banin, Shaoqin Liu, Xingyu Jiang, Wenfu Zheng, Wenshu Zheng, Aharon Gedanken, and Michal Natan
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biology ,Chemistry ,education ,technology, industry, and agriculture ,General Engineering ,Biofilm ,Bioengineering ,02 engineering and technology ,General Chemistry ,Bacterial growth ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Antimicrobial ,biology.organism_classification ,01 natural sciences ,Combinatorial chemistry ,Small molecule ,Atomic and Molecular Physics, and Optics ,Bacterial cell structure ,0104 chemical sciences ,Sonochemistry ,Colloidal gold ,General Materials Science ,0210 nano-technology ,Bacteria - Abstract
The increase in antibiotic resistance reported worldwide poses an immediate threat to human health and highlights the need to find novel approaches to inhibit bacterial growth. In this study, we present a series of gold nanoparticles (Au NPs) capped by different N-heterocyclic molecules (N_Au NPs) which can serve as broad-spectrum antibacterial agents. Neither the Au NPs nor N-heterocyclic molecules were toxic to mammalian cells. These N_Au NPs can attach to the surface of bacteria and destroy the bacterial cell wall to induce cell death. Sonochemistry was used to coat Au NPs on the surface of fabrics, which showed superb antimicrobial activity against multi-drug resistant (MDR) bacteria as well as excellent efficacy in inhibiting bacterial biofilms produced by MDR bacteria. Our study provides a novel strategy for preventing the formation of MDR bacterial biofilms in a straightforward, low-cost, and efficient way, which holds promise for broad clinical applications.
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- 2020
16. Engineering of a New Bisphosphonate Monomer and Nanoparticles of Narrow Size Distribution for Antibacterial Applications
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Shlomo Margel, Michal Natan, Ehud Banin, Nimrod Tal, Igor Grinberg, and Safra Rudnick-Glick
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0301 basic medicine ,General Chemical Engineering ,technology, industry, and agriculture ,chemistry.chemical_element ,Nanoparticle ,02 engineering and technology ,General Chemistry ,Calcium ,021001 nanoscience & nanotechnology ,Methacrylate ,Combinatorial chemistry ,Article ,lcsh:Chemistry ,03 medical and health sciences ,chemistry.chemical_compound ,030104 developmental biology ,Monomer ,lcsh:QD1-999 ,chemistry ,Polymerization ,Copolymer ,Methacrylamide ,0210 nano-technology ,Ethylene glycol - Abstract
In recent years, many bacteria have developed resistance to commonly used antibiotics. It is well-known that calcium is essential for bacterial function and cell wall stability. Bisphosphonates (BPs) have high affinity to calcium ions and are effective calcium chelators. Therefore, BPs could potentially be used as antibacterial agents. This article provides a detailed description regarding the synthesis of a unique BP vinylic monomer MA-Glu-BP (methacrylate glutamate bisphosphonate) and polyMA-Glu-BP nanoparticles (NPs) for antibacterial applications. polyMA-Glu-BP NPs were synthesized by dispersion copolymerization of the MA-Glu-BP monomer with the primary amino monomer N-(3-aminopropyl)methacrylamide hydrochloride (APMA) and the cross-linker monomer tetra ethylene glycol diacrylate, to form cross-linked NPs with a narrow size distribution. The size and size distribution of polyMA-Glu-BP NPs were controlled by changing various polymerization parameters. Near-infrared fluorescent polyMA-Glu-BP NPs were prepared by covalent binding of the dye cyanine7 N-hydroxysuccinimide to the primary amino groups belonging to the APMA monomeric units on the polyMA-Glu-BP NPs. The affinity of the near-infrared fluorescent polyMA-Glu-BP NPs toward calcium was demonstrated in vitro by a coral model. Cytotoxicity, cell uptake, and antibacterial properties of the polyMA-Glu-BP NPs against two common bacterial pathogens representing Gram-negative bacteria, Escherichia coli and Pseudomonas aeruginosa, and two representing Gram-positive bacteria, Listeria innocua and Staphylococcus aureus, were then demonstrated.
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- 2018
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17. Engineering of crosslinked polyisothiouronium methylstyrene microparticles of narrow size distribution for antibacterial applications
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Tammy Lublin Tennebaum, Sarit Cohen, Michal Natan, Inna Laitman, Ehud Banin, and Shlomo Margel
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Materials science ,Polymers and Plastics ,Chemical engineering ,Distribution (pharmacology) ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,0210 nano-technology ,01 natural sciences ,0104 chemical sciences - Published
- 2017
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18. Ga@C-dots as an antibacterial agent for the eradication of Pseudomonas aeruginosa
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Aharon Gedanken, Gila Jacobi, Ehud Banin, Ze'ev Porat, Vijay Bhooshan Kumar, and Michal Natan
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Biophysics ,Pharmaceutical Science ,Nanoparticle ,chemistry.chemical_element ,Bioengineering ,02 engineering and technology ,Bacterial growth ,010402 general chemistry ,medicine.disease_cause ,01 natural sciences ,Biomaterials ,Drug Discovery ,medicine ,Gallium ,Antibacterial agent ,biology ,Pseudomonas aeruginosa ,Chemistry ,Organic Chemistry ,General Medicine ,021001 nanoscience & nanotechnology ,biology.organism_classification ,Antimicrobial ,0104 chemical sciences ,0210 nano-technology ,Antibacterial activity ,Bacteria ,Nuclear chemistry - Abstract
The opportunistic pathogen Pseudomonas aeruginosa causes infections that are difficult to treat by antibiotic therapy. This research article reports on the synthesis of gallium (Ga) doped in carbon (C)-dots (Ga@C-dots) and their antimicrobial activity against free-living P. aeruginosa bacteria. The synthesis of Ga@C-dots was carried out by sonicating molten Ga (for 2.5 h) in polyethylene glycol-400, which acts as both a medium and carbon source. The resultant Ga@C-dots, having an average diameter of 9±2 nm, showed remarkably enhanced antibacterial activity compared with undoped C-dots. This was reflected by the much lower concentration of Ga doped within Ga@C-dots which was required for full inhibition of the bacterial growth. These results highlight the possibility of using Ga@C-dots as potential antimicrobial agents.
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- 2017
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19. Antibacterial Activity Against Methicillin-Resistant Staphylococcus aureus of Colloidal Polydopamine Prepared by Carbon Dot Stimulated Polymerization of Dopamine
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Aharon Gedanken, Gila Jacobi, Moorthy Maruthapandi, Michal Natan, John H. T. Luong, and Ehud Banin
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chemistry.chemical_classification ,Staphylococcus aureus ,Catechol ,Reactive oxygen species ,Autoxidation ,Superoxide ,General Chemical Engineering ,technology, industry, and agriculture ,colloidal dispersion ,Article ,Quinone ,chemistry.chemical_compound ,chemistry ,Polymerization ,eradication of MRSA ,carbon dots ,General Materials Science ,Antibacterial activity ,Hydrogen peroxide ,human activities ,polydopamine ,Nuclear chemistry - Abstract
A simple one-step process for the polymerization of dopamine has been developed using nitrogen-doped carbon dots (N@C&ndash, dots) as the sole initiator. The synthesized amorphous polydopamine (PDA)-doped N@C&ndash, dots (PDA&ndash, N@C&ndash, dots composite) exhibited a negative charge of &ndash, 39 mV with particle sizes ranging from 200 to 1700 nm. The stable colloidal solution was active against methicillin-resistant Staphylococcus aureus (MRSA), a Gram-negative bacterium. The strong adhesion of the polymer to the bacterial membrane resulted in a limited diffusion of nutrients and wastes in and out of the cell cytosol, which is a generic mechanism to trigger cell death. Another possible route is the autoxidation of the catechol moiety of PDA to form quinone and release reactive oxygen species (ROS) such as superoxide radicle and hydrogen peroxide, two well-known ROS with antimicrobial properties against both Gram-negative and Gram-positive bacteria.
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- 2019
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20. Engineering Irrigation Drippers with Rechargeable N-Halamine Nanoparticles for Antifouling Applications
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Shlomo Margel, Ehud Banin, Dekel Segev, Ori Gutman, and Michal Natan
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Crops, Agricultural ,Irrigation ,Acrylamides ,Materials science ,Agricultural Irrigation ,business.industry ,Environmental engineering ,Fresh Water ,02 engineering and technology ,Wastewater ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,Waste Disposal, Fluid ,Reclaimed water ,0104 chemical sciences ,Biofouling ,Cross-Linking Reagents ,Agriculture ,Humans ,Nanoparticles ,General Materials Science ,Amines ,0210 nano-technology ,business - Abstract
The increased demand for water highlights the need to utilize reclaimed water of various types. In agriculture, for example, which is considered the largest consumer of freshwater, irrigation with treated wastewater can replace much of the need for freshwater. Wastewater is generally used for irrigation through drippers, releasing small amounts of water to the crops. The contaminants found in treated wastewater increase the accumulation of fouling on the drippers, ultimately culminating in blocking of water exit. Thus, there is a crucial need to develop novel approaches to limit biofilm formation on the dripper. Here, we describe the synthesis of N-halamine-derivatized cross-linked polymethacrylamide nanoparticles (NPs) by copolymerization of the monomer methacrylamide and the cross-linker monomer N, N-methylenebisacrylamide and their subsequent embedding in the polyethylene that is used to fabricate the drippers. The newly designed drip system was activated by chlorinating the incorporated NPs and then was fully characterized. The nanofunctionalized drippers were tested in the field, showing excellent antifouling activity for at least 5 months compared to the control. In addition, the inherent recharging capacity of the antifouling NPs constitutes yet another valuable advantage of the currently reported technology.
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- 2019
21. Engineering of new methylstyrene farmin vinylic monomer and crosslinked poly(methylstyrene farmin) nanoparticles of narrow size distribution for antibacterial and antibiofilm applications
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Shlomo Margel, Sarit Cohen, Chen Gelber, Michal Kolitz-Domb, Ehud Banin, and Michal Natan
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chemistry.chemical_classification ,Aqueous solution ,Materials science ,Polymers and Plastics ,Organic Chemistry ,Nanoparticle ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Styrene ,chemistry.chemical_compound ,Monomer ,chemistry ,Polymerization ,Polymer chemistry ,Materials Chemistry ,0210 nano-technology ,Dispersion (chemistry) ,Ethylene glycol ,Alkyl - Abstract
The vinylic monomer methylstyrene farmin (MSF) was synthesized by interacting p -chloromethyl styrene with farmin in basic distilled water. Crosslinked poly(methyl styrene farmin) nanoparticles (PMSF NPs) were then synthesized by dispersion co-polymerization of the MSF monomer with the crosslinking monomer tetra(ethylene glycol) diacrylate (TTEGDA) in an aqueous continuous phase. The effect of various polymerization parameters on the size and size distribution of the formed NPs has been elucidated. These PMSF NPs contain quaternary ammonium groups and long alkyl chain groups, and therefore are expected to possess efficient antibacterial and antibiofilm properties. The antibacterial and antibiofilm properties of PMSF NPs of 40 ± 9 nm and NPs-coated films were demonstrated. Due to their promising antibacterial and antibiofilm properties, these newly NPs could be utilized in a variety of industrial applications as a new type of biocide and antibiofilm additive.
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- 2016
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22. Engineering of crosslinked poly(isothiouronium methylstyrene) microparticles of narrow size distribution for antibacterial applications
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Sarit Cohen, Ehud Banin, Shlomo Margel, Michal Natan, Tammy Lublin Tennenbaum, and Inna Laitman
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Dispersion polymerization ,Isothiouronium ,Materials science ,Polymers and Plastics ,Distribution (number theory) ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,chemistry.chemical_compound ,chemistry ,Composite material ,0210 nano-technology - Published
- 2016
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23. Engineering of Superparamagnetic Core–Shell Iron Oxide/N-Chloramine Nanoparticles for Water Purification
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Shlomo Margel, Michal Natan, Michal Kolitz-Domb, Ehud Banin, Hai Haham, and Ori Gutman
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inorganic chemicals ,Materials science ,Aqueous solution ,education ,Inorganic chemistry ,technology, industry, and agriculture ,Iron oxide ,Nanoparticle ,02 engineering and technology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,chemistry.chemical_compound ,Crystallinity ,chemistry ,Chemical engineering ,Polymerization ,mental disorders ,Methacrylamide ,Magnetic nanoparticles ,General Materials Science ,0210 nano-technology ,health care economics and organizations ,Superparamagnetism - Abstract
In this study, we describe the synthesis and characterization of superparamagnetic core-shell iron oxide (IO)/N-halamine antibacterial nanoparticles (NPs). For this purpose, superparamagnetic IO core NPs were coated with cross-linked polymethacrylamide (PMAA) by surfactant-free dispersion copolymerization of methacrylamide and N,N-methylenebis(acrylamide) in an aqueous continuous phase. The effect of the polymerization process on the chemical composition, size, shape, crystallinity, and magnetic properties of the IO/PMAA NPs was elucidated. Conversion of the core-shell IO/PMAA NPs into their N-halamine form, IO/PMAA-Cl, was accomplished using a chlorination reaction with sodium hypochlorite. The influence of chlorination on the shape, crystallinity, and magnetic properties of the IO/PMAA NPs was studied. The IO/PMAA-Cl NPs demonstrated excellent antibacterial activity against Gram-negative and Gram-positive bacteria. Finally, the chlorination recharging capabilities of the NPs and their potential for use in the purification of water containing bacteria were demonstrated with magnetic columns packed with the IO/PMAA-Cl NPs.
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- 2016
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24. Multiphase thermoplastic hybrid for controlled release of antimicrobial essential oils in active packaging film
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Michal Natan, Itan Moshe, Orli Weizman, Gila Jacobi, Ehud Banin, A. Dotan, and Amos Ophir
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Materials science ,Polymers and Plastics ,Food preservation ,Active packaging ,04 agricultural and veterinary sciences ,02 engineering and technology ,Bacterial growth ,021001 nanoscience & nanotechnology ,Shelf life ,040401 food science ,Controlled release ,Food packaging ,chemistry.chemical_compound ,0404 agricultural biotechnology ,Chemical engineering ,chemistry ,Polyamide ,Organic chemistry ,0210 nano-technology ,Thymol - Abstract
Active packaging, a new technology concept in the field of food packaging, has been introduced in recent years in order to provide quality and safety, as well as extend the shelf life of food products. Antimicrobial (AM) agents can be incorporated directly into the active packaging and migrate in a controlled manner to the headspace between the food and the package, inhibiting bacteria growth on the food surface. Naturally derived AM agent, such as essential oils (EOs), has received considerable attention for food preservation purposes, because of their effective AM activity against various bacteria and fungi. In the present study, AM active film systems based on polypropylene/polyamide blends, montmorillonite nanoclays, and thymol EO were produced to investigate the feasibility of controlling the release rate of thymol from food packaging systems. Selective localization of thymol in a specific phase in the system that derives from thermodynamic affinity was assumed to be useful in controlling its migration rate from the film to the headspace. EO retention in the film under two different time conditions was measured by spectroscopic analysis. The release rate of EO was determined using Gas chromatography technique and analyzed by diffusion model approach. Inhibition of bacterial growth was periodically tested for Listeria and Escherichia coli bacteria. This study confirms the thermodynamic affinity of polyamide phase with thymol that has a positive effect in retaining the EO. Results show controlled AM behavior of the active packaging films, based on various blend compositions. Copyright © 2016 John Wiley & Sons, Ltd.
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- 2016
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25. Two are Better than One: Combining ZnO and MgF2Nanoparticles ReducesStreptococcus pneumoniaeandStaphylococcus aureusBiofilm Formation on Cochlear Implants
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Ilana Perelshtein, Helge Rask-Andersen, Fredrik Edin, Herbert Keppner, Michal Natan, Edith Laux, Nina Perkas, Elad Segal, Ehud Banin, Aharon Gedanken, Alexandra Homsy, and Gila Yacobi
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Materials science ,Biocompatibility ,Nanoparticle ,02 engineering and technology ,engineering.material ,010402 general chemistry ,medicine.disease_cause ,01 natural sciences ,Microbiology ,Biomaterials ,Coating ,Streptococcus pneumoniae ,Electrochemistry ,medicine ,biology ,Biofilm ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,biology.organism_classification ,0104 chemical sciences ,Electronic, Optical and Magnetic Materials ,Staphylococcus aureus ,Toxicity ,engineering ,0210 nano-technology ,Bacteria - Abstract
Streptococcus pneumoniae (S. pneumoniae) and Staphylococcus aureus (S.aureus) are considered the most common colonizers of cochlear implants (CI), which have prompted the search for new ways to inhibit their growth and biofilm development. In the current study, CI-based platforms are prepared and sonochemically coated with ZnO or MgF2 nanoparticles (NPs), two agents previously shown to possess antibacterial properties. Additionally, a method is developed for coating both ZnO and MgF2 on the same platform to achieve synergistic activity against both pathogens. Each surface is characterized, and the optimal conditions for the NP homogenous distribution on the surface are determined. The ZnO-MgF2 surface significantly reduces the S. pneumoniae and S. aureus biofilm compared with the surfaces coated with either ZnO or MgF2, even though it contains smaller amounts of each NP type. Importantly, leaching assays show that the NPs remain anchored to the surface for at least 7 d. Finally, biocompatibility studies demonstrate that coating with low concentrations of ZnO-MgF2 results in no toxicity toward primary human fibroblasts from the auditory canal. Taken together, these findings underscore the potential of using NP combinations such as the one presented here to efficiently inhibit bacterial colonization and growth on medical devices such as CIs.
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- 2016
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26. Antibacterial properties of polypyrrole-treated fabrics by ultrasound deposition
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Nina Perkas, Ehud Banin, Alessio Varesano, Aharon Gedanken, Riccardo Andrea Carletto, Diego Omar Sanchez Ramirez, Ilana Perelshtein, Claudia Vineis, and Michal Natan
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Staphylococcus aureus ,Materials science ,Polymers ,Nanoparticle ,Bioengineering ,02 engineering and technology ,Microbial Sensitivity Tests ,engineering.material ,010402 general chemistry ,Polypyrrole ,01 natural sciences ,Biomaterials ,chemistry.chemical_compound ,Coating ,Ultrasound ,Spectroscopy, Fourier Transform Infrared ,Escherichia coli ,Pyrroles ,Ultrasonics ,Sonochemical coating ,chemistry.chemical_classification ,Viscosity ,Conjugated polymer ,Textiles ,Backbone chain ,Polymer ,021001 nanoscience & nanotechnology ,Antimicrobial ,0104 chemical sciences ,Anti-Bacterial Agents ,Polyester ,chemistry ,Chemical engineering ,Polymerization ,Mechanics of Materials ,Thermogravimetry ,engineering ,Nanoparticles ,Antibacterial fabric ,0210 nano-technology - Abstract
Antimicrobial textiles can contribute to the fighting against antibiotic resistance pathogenic microorganisms. Polypyrrole is a conjugated polymer that exerts a biocidal action thanks to positive charges on its backbone chain produced during it synthesis. In this work, dispersions of stable polypyrrole nanoparticles were produced by chemical oxidative polymerization at room temperature in water. An ultrasound-assisted coating process was then used to effectively treat a polyester fabric with the nanoparticles to obtain an optimal antibacterial coating which efficiently eradicates the bacteria. The results showed that the treated fabric with about 4 g/m2 of polypyrrole had log bacteria reductions of 6.0 against Staphylococcus aureus and 7.5 against Escherichia coli. The combination of a polypyrrole synthesis in the form of water nanoparticles dispersions and a continuous coating of fabrics supported by ultrasound overcomes some issues of upscaling of the traditional in-situ chemical deposition used until now for the production of polypyrrole-coated textiles.
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- 2018
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27. New Life for an Old Antibiotic
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Aharon Gedanken, Ehud Banin, Michal Natan, Rahul Kumar Mishra, Anat Lipovsky, and Elad Segal
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Staphylococcus aureus ,Materials science ,Cell Survival ,Tetracycline ,Sonication ,Kinetics ,Oxide ,Nanoparticle ,Nanotechnology ,Sonochemistry ,law.invention ,Diffusion ,chemistry.chemical_compound ,Drug Stability ,Nanocapsules ,law ,Materials Testing ,medicine ,General Materials Science ,Fourier transform infrared spectroscopy ,Graphene ,Drug Synergism ,Oxides ,Anti-Bacterial Agents ,chemistry ,Graphite ,Nuclear chemistry ,medicine.drug - Abstract
Restoring the antibacterial properties of existing antibiotics is of great concern. Herein, we present, for the first time, the formation and deposition of stable antibiotic nanoparticles (NPs) on graphene oxide (GO) sheets by a facile one-step sonochemical technique. Sonochemically synthesized graphene oxide/tetracycline (GO/TET) composite shows enhanced activity against both sensitive and resistant Staphylococcus aureus (S. aureus). The size and deposition of tetracycline (TET) nanoparticles on GO can be controlled by varying the sonication time. The synthesized NPs ranged from 21 to 180 nm. Moreover, ultrasonic irradiation does not cause any structural and chemical changes to the TET molecule as confirmed by Fourier transform infrared spectroscopy (FTIR). The virtue of π-π stacking between GO and TET additionally facilitate the coating of TET NPs upon GO. A time dependent release kinetics of TET NPs from the GO surface is also monitored providing important insights regarding the mechanism of antibacterial activity of GO/TET composites. Our results show that the GO/TET composite is bactericidal in nature, resulting in similar values of minimal inhibitory concentration (MIC) and minimal bactericidal concentration (MBC). This composite is found to be active against TET resistant S. aureus at a concentration four times lower than the pristine TET. The sensitive S. aureus follows the same trend showing six times lower MIC values compared to pristine TET. GO shows no activity against both sensitive and resistant S. aureus even at a concentration as high as 1 mg/mL but influences the biocidal activity of the GO/TET composite. We propose that the unique structure and composition manifested by GO/TET composites may be further utilized for different formulations of antibiotics with GO. The sonochemical method used in this work can be precisely tailored for the stable deposition of a variety of antibiotics on the GO surface to reduce health risks and increase the spectrum of applications.
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- 2015
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28. Novel LDPE/halloysite nanotube films with sustained carvacrol release for broad-spectrum antimicrobial activity
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Anita Vaxman, Yechezkel Kashi, Michal Natan, Max Krepker, Rotem Shemesh, Yael Danin-Poleg, Ehud Banin, Ester Segal, and Nadav Nitzan
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chemistry.chemical_classification ,Nanocomposite ,Polymer nanocomposite ,Chemistry ,General Chemical Engineering ,Nanotechnology ,General Chemistry ,Polymer ,engineering.material ,Antimicrobial ,Halloysite ,Low-density polyethylene ,chemistry.chemical_compound ,Chemical engineering ,engineering ,Carvacrol ,Thermal stability - Abstract
The emergence of antibiotic resistance of pathogenic bacteria has led to renewed interest in exploring the potential of plant-derived antimicrobials e.g., essential oils (EOs), as an alternative strategy to reduce microbial contamination. However, the volatile nature of EOs presents a major challenge in their incorporation into polymers by conventional high-temperature processing techniques. Herein, we employ halloysite nanotubes (HNTs) as efficient nano-carriers for carvacrol (a model EO). This pre-compounding encapsulation step imparts enhanced thermal stability to the carvacrol, allowing for its subsequent melt compounding with low-density polyethylene (LDPE). The resulting polymer nanocomposites exhibit outstanding antimicrobial properties with a broad spectrum of inhibitory activity against Escherichia coli, Listeria innocua in biofilms, and Alternaria alternata. Their antimicrobial effectiveness is also successfully demonstrated in complex model food systems (soft cheese and bread). This superior activity, compared to other studied carvacrol containing films, is induced by the significantly higher carvacrol content in the film as well as its slower out-diffusion from the hybrid system. Thus, these new active polymer nanocomposites presents an immense potential in controlling microbial contamination and biofilm related adverse effects, rendering them as excellent candidate materials for a wide range of applications.
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- 2015
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29. Imparting superhydrophobic and biocidal functionalities to a polymeric substrate by the sonochemical method
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Aharon Gedanken, Ehud Banin, Asya Svirinovsky, Michal Natan, and Ilana Perelshtein
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chemistry.chemical_classification ,Materials science ,Nanocomposite ,Acoustics and Ultrasonics ,Organic Chemistry ,Nanoparticle ,02 engineering and technology ,Polymer ,Polyethylene ,010402 general chemistry ,021001 nanoscience & nanotechnology ,01 natural sciences ,0104 chemical sciences ,Sonochemistry ,Inorganic Chemistry ,chemistry.chemical_compound ,chemistry ,Chemical engineering ,Surface roughness ,Chemical Engineering (miscellaneous) ,Environmental Chemistry ,Radiology, Nuclear Medicine and imaging ,Tetrafluoroethylene ,Hexafluoropropylene ,0210 nano-technology - Abstract
Multifunctional substrates with superhydrophobic and biocidal properties are gaining interest for a wide range of applications; however, the production of such surfaces remains challenging. Here, the sonochemical method is utilized to impart superhydrophobicity and antimicrobial properties to a polyethylene (PE) sheet. This is achieved by sonochemically depositing nanoparticles (NPs) of a hydrophobic fluoro-polymer (FP) on the PE sheets. The polymer is a flexible, transparent fluoroplastic composed of tetrafluoroethylene, hexafluoropropylene and vinylidene fluoride in the form of a powder. The NPs of polymers are generated and deposited on the surface of the PE using ultrasound irradiation. Optimizing the process results in a homogeneous distribution of 110–200 nm of NPs on the PE surface. The coated surface displays a water-contact angle of 160°, indicating excellent superhydrophobicity. This superhydrophobic surface shows high stability under outdoor conditions for two months, which is essential for various applications. In addition, metal-oxide nanoparticles (CuO or ZnO NPs) were integrated into the polymer coating to achieve antibacterial properties and increase the surface roughness. The metal oxides were also deposited sonochemically. The antibacterial activity of the FP@ZnO and FP@CuO PE composites was tested against the bacterium Staphylococcus aureus, and the results show that the FP@CuO PE can effectively eradicate the bacteria. This study highlights the feasibility of using the sonochemical method to deposit two separate functions, opening up new possibilities for producing “smart” novel surfaces.
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- 2017
30. Ga@C-dots as an antibacterial agent for the eradication of
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Vijay Bhooshan, Kumar, Michal, Natan, Gila, Jacobi, Ze'ev, Porat, Ehud, Banin, and Aharon, Gedanken
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gallium ,Static Electricity ,C-dots ,Microbial Sensitivity Tests ,Spectrum Analysis, Raman ,Carbon ,Anti-Bacterial Agents ,antibacterial ,Pseudomonas aeruginosa ,Nanoparticles ,Carbon-13 Magnetic Resonance Spectroscopy ,Ga@C-dots ,sonochemistry ,Original Research - Abstract
The opportunistic pathogen Pseudomonas aeruginosa causes infections that are difficult to treat by antibiotic therapy. This research article reports on the synthesis of gallium (Ga) doped in carbon (C)-dots (Ga@C-dots) and their antimicrobial activity against free-living P. aeruginosa bacteria. The synthesis of Ga@C-dots was carried out by sonicating molten Ga (for 2.5 h) in polyethylene glycol-400, which acts as both a medium and carbon source. The resultant Ga@C-dots, having an average diameter of 9±2 nm, showed remarkably enhanced antibacterial activity compared with undoped C-dots. This was reflected by the much lower concentration of Ga doped within Ga@C-dots which was required for full inhibition of the bacterial growth. These results highlight the possibility of using Ga@C-dots as potential antimicrobial agents.
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- 2017
31. Characterization and antibacterial properties of N-halamine-derivatized cross-linked polymethacrylamide nanoparticles
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Ehud Banin, Michal Natan, Ori Gutman, and Shlomo Margel
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Staphylococcus aureus ,Materials science ,Aqueous solution ,Biophysics ,Nanoparticle ,Hypochlorite ,Bioengineering ,Microbial Sensitivity Tests ,Antimicrobial ,Anti-Bacterial Agents ,Biomaterials ,Nylons ,chemistry.chemical_compound ,Monomer ,chemistry ,Polymerization ,Mechanics of Materials ,Sodium hypochlorite ,Polymer chemistry ,Ceramics and Composites ,Nanoparticles ,Methacrylamide - Abstract
N-halamine-derivatized cross-linked polymethacrylamide nanoparticles with sizes ranging between 18 ± 2.0 and 460 ± 60 nm were prepared via surfactant-free dispersion co-polymerization of methacrylamide (MAA) and the cross-linking monomer N,N-methylenebisacrylamide (MBAA) in an aqueous continuous phase, followed by a chlorination process using sodium hypochlorite. The effect of various polymerization parameters (monomer concentration, initiator type and concentration, polymerization duration, polymerization temperature, and the weight ratio [MBAA]/[MAA]) on the size and size distribution of the produced cross-linked P(MAA–MBAA) nanoparticles was elucidated. The effect of various chlorination parameters (hypochlorite concentration, chlorination period and temperature) on the bound oxidative chlorine atom (Cl) content of the P(MAA–MBAA) nanoparticles was also investigated. The bactericidal activity of these chloramine-derivatized nanoparticles was tested against two common bacterial pathogens ( Escherichia coli and Staphylococcus aureus ), and they were found to be highly potent. Furthermore, these nanoparticles also exerted their antimicrobial activity against multi-drug resistant (MDR) bacteria, further demonstrating their efficacy.
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- 2014
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32. Synthesis and characterization of fluoro-modified polypropylene films for inhibition of biofilm formation
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Michal Natan, Inna Laitman, Shlomo Margel, and Ehud Banin
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Listeria ,Fluorine Compounds ,Microscopy, Atomic Force ,Polypropylenes ,Methacrylate ,Polymerization ,Contact angle ,chemistry.chemical_compound ,Colloid and Surface Chemistry ,X-ray photoelectron spectroscopy ,Spectroscopy, Fourier Transform Infrared ,Polymer chemistry ,Escherichia coli ,Physical and Theoretical Chemistry ,Polypropylene ,Ozonolysis ,Calorimetry, Differential Scanning ,Water ,Hydrogen Peroxide ,Surfaces and Interfaces ,General Medicine ,Monomer ,chemistry ,Chemical engineering ,Biofilms ,Thermogravimetry ,Surface modification ,Oxidation-Reduction ,Biotechnology - Abstract
Surface hydroperoxide-conjugated polypropylene (PP) films were prepared by optimal ozonolysis processing of the films. These hydroperoxide-conjugated groups were then used as initiators at room temperature for redox graft polymerization of the fluoro vinylic monomer 1H,1H-heptaflourobutyl methacrylate (HFBM). The ozonolysis process allows, on one hand, for the formation of the desired hydroperoxide-conjugated groups while, on the other hand, leads to an undesired degradation of the PP. The ozone treatment time was therefore optimized to obtain sufficient hydroperoxide groups for graft polymerization, while maintaining the mechanical strength of the films, which was barely affected. The resulting PP-PolyHFBM (PP-PHFBM) films were characterized by methods such as AFM, ATR, TGA, contact angle goniometry and XPS. The antibiofilm properties of the PP-PHFBM films were evaluated, using two bacterial strains. An 86% inhibition was observed for the Gram-negative Escherichia coli, and a 37% inhibition was observed for the Gram-positive Listeria.
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- 2014
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33. From Nano to Micro: using nanotechnology to combat microorganisms and their multidrug resistance
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Michal Natan and Ehud Banin
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Drug Carriers ,Medical device ,Bacteria ,Metal Nanoparticles ,Nanotechnology ,02 engineering and technology ,Bacterial Infections ,Biology ,010402 general chemistry ,021001 nanoscience & nanotechnology ,Antimicrobial ,01 natural sciences ,Microbiology ,0104 chemical sciences ,Anti-Bacterial Agents ,Multiple drug resistance ,Infectious Diseases ,Antibiotic resistance ,Biofilms ,Drug Resistance, Multiple, Bacterial ,Nanocarriers ,0210 nano-technology - Abstract
The spread of antibiotic resistance and increasing prevalence of biofilm-associated infections is driving demand for new means to treat bacterial infection. Nanotechnology provides an innovative platform for addressing this challenge, with potential to manage even infections involving multidrug-resistant (MDR) bacteria. The current review summarizes recent progress over the last 2 years in the field of antibacterial nanodrugs, and describes their unique properties, mode of action and activity against MDR bacteria and biofilms. Biocompatibility and commercialization are also discussed. As opposed to the more common division of nanoparticles (NPs) into organic- and inorganic-based materials, this review classifies NPs into two functional categories. The first includes NPs exhibiting intrinsic antibacterial properties and the second is devoted to NPs serving as a cargo for delivering antibacterial agents. Antibacterial nanomaterials used to decorate medical devices and implants are reviewed here as well.
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- 2016
34. Graft polymerization of styryl bisphosphonate monomer onto polypropylene films for inhibition of biofilm formation
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Safra Rudnick-Glick, Hanna P. Steinmetz, Shlomo Margel, Ehud Banin, and Michal Natan
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0301 basic medicine ,Polymers ,030106 microbiology ,02 engineering and technology ,engineering.material ,Microscopy, Atomic Force ,Polymerization ,Contact angle ,03 medical and health sciences ,chemistry.chemical_compound ,Colloid and Surface Chemistry ,Coating ,Polymer chemistry ,Physical and Theoretical Chemistry ,Styrene ,Polypropylene ,Bacteria ,Bone Density Conservation Agents ,Diphosphonates ,Viscosity ,Photoelectron Spectroscopy ,Biofilm ,Surfaces and Interfaces ,General Medicine ,021001 nanoscience & nanotechnology ,Grafting ,Monomer ,chemistry ,Chemical engineering ,Propylene Glycols ,Biofilms ,engineering ,Surface modification ,0210 nano-technology ,Biotechnology - Abstract
There has been increased concern during the past few decades over the role bacterial biofilms play in causing a variety of health problems, especially since they exhibit a high degree of resistance to antibiotics and are able to survive in hostile environments. Biofilms consist of bacterial aggregates enveloped by a self-produced matrix attached to the surface. Ca2+ ions promote the formation of biofilms, and enhance their stability, viscosity, and strength. Bisphosphonates exhibit a high affinity for Ca2+ ions, and may inhibit the formation of biofilms by acting as sequestering agents for Ca2+ ions. Although the antibacterial activity of bisphosphonates is well known, research into their anti-biofilm behavior is still in its early stages. In this study, we describe the synthesis of a new thin coating composed of poly(styryl bisphosphonate) grafted onto oxidized polypropylene films for anti-biofilm applications. This grafting process was performed by graft polymerization of styryl bisphosphonate vinylic monomer onto O2 plasma-treated polypropylene films. The surface modification of the polypropylene films was confirmed using surface measurements, including X-ray photoelectron spectroscopy, atomic force microscopy, and water contact angle goniometry. Significant inhibition of biofilm formation was achieved for both Gram-negative and Gram-positive bacteria.
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- 2016
35. Killing mechanism of stable N-halamine cross-linked polymethacrylamide nanoparticles that selectively target bacteria
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Shlomo Margel, Michal Natan, Ori Gutman, Ronit Lavi, and Ehud Banin
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Staphylococcus aureus ,Bleach ,Polymers ,Sodium Hypochlorite ,Disinfectant ,General Physics and Astronomy ,chemistry.chemical_element ,Bacterial growth ,chemistry.chemical_compound ,Drug Stability ,Cell Line, Tumor ,Chlorine ,Escherichia coli ,Methacrylamide ,Organic chemistry ,Humans ,General Materials Science ,Acrylamides ,Chemistry ,General Engineering ,Antimicrobial ,Combinatorial chemistry ,Anti-Bacterial Agents ,Oxidative Stress ,Monomer ,Sodium hypochlorite ,Nanoparticles - Abstract
Increased resistance of bacteria to disinfection and antimicrobial treatment poses a serious public health threat worldwide. This has prompted the search for agents that can inhibit both bacterial growth and withstand harsh conditions (e.g., high organic loads). In the current study, N-halamine-derivatized cross-linked polymethacrylamide nanoparticles (NPs) were synthesized by copolymerization of the monomer methacrylamide (MAA) and the cross-linker monomer N,N-methylenebis(acrylamide) (MBAA) and were subsequently loaded with oxidative chlorine using sodium hypochlorite (NaOCl). The chlorinated NPs demonstrated remarkable stability and durability to organic reagents and to repetitive bacterial loading cycles as compared with the common disinfectant NaOCl (bleach), which was extremely labile under these conditions. The antibacterial mechanism of the cross-linked P(MAA-MBAA)-Cl NPs was found to involve generation of reactive oxygen species (ROS) only upon exposure to organic media. Importantly, ROS were not generated upon suspension in water, revealing that the mode of action is target-specific. Further, a unique and specific interaction of the chlorinated NPs with Staphylococcus aureus was discovered, whereby these microorganisms were all specifically targeted and marked for destruction. This bacterial encircling was achieved without using a targeting module (e.g., an antibody or a ligand) and represents a highly beneficial, natural property of the P(MAA-MBAA)-Cl nanostructures. Our findings provide insights into the mechanism of action of P(MAA-MBAA)-Cl NPs and demonstrate the superior efficacy of the NPs over bleach (i.e., stability, specificity, and targeting). This work underscores the potential of developing sustainable P(MAA-MBAA)-Cl NP-based devices for inhibiting bacterial colonization and growth.
- Published
- 2015
36. Note: Engineering of crosslinked poly(isothiouronium methylstyrene) microparticles of narrow size distribution for antibacterial applications
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Michal Natan, Sarit Cohen, Inna Laitman, Ehud Banin, Tammy Lublin Tennenbaum, and Shlomo Margel
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Isothiouronium ,chemistry.chemical_compound ,Materials science ,Polymers and Plastics ,Chemical engineering ,chemistry ,Polymer chemistry ,Distribution (pharmacology) ,chemistry.chemical_element ,Lithium ,Ion - Published
- 2017
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37. Note: Multiphase thermoplastic hybrid for controlled release of antimicrobial essential oils in active packaging film
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Itan Moshe, Ehud Banin, Gila Jacobi, Orli Weizman, A. Dotan, Amos Ophir, and Michal Natan
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chemistry.chemical_classification ,Thermoplastic ,Materials science ,Polymers and Plastics ,chemistry ,Chemical engineering ,Active packaging ,chemistry.chemical_element ,Lithium ,Composite material ,Antimicrobial ,Controlled release ,Ion - Published
- 2017
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38. Biofilm prevention on cochlear implants
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Yael Goldfinger, Chaim N. Sukenik, Michal Natan, Jona Kronenberg, and Ehud Banin
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Materials science ,Prosthesis-Related Infections ,chemistry.chemical_element ,macromolecular substances ,engineering.material ,Deafness ,Speech and Hearing ,Atomic layer deposition ,chemistry.chemical_compound ,Coating ,Coated Materials, Biocompatible ,Deposition (phase transition) ,Humans ,Dimethylpolysiloxanes ,Composite material ,Thin film ,chemistry.chemical_classification ,Titanium ,Microscopy, Confocal ,Polydimethylsiloxane ,technology, industry, and agriculture ,Polymer ,Cochlear Implants ,Otorhinolaryngology ,chemistry ,Biofilms ,engineering ,Casing - Abstract
Objectives To examine the efficiency of a bacteria-resistant coating for the polydimethylsiloxane (PDMS) casing of cochlear implants. Methods The coatings are based on thin titania films that are made by liquid phase deposition or atomic layer deposition. The antibacterial activity of the coating was tested by two different detection assays: BCA protein and confocal microscopy. Results Coating the PDMS with thin films (10–40 nm) of titania significantly reduces the accumulation of bacteria. Discussion Thin oxide films made under conditions that do not undermine the integrity of polymeric materials can be used as anti-microbial coatings for soft polymers such as the PDMS that is used as a casing for cochlear implants or other medical devices.
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- 2014
39. The combined effect of additives and processing on the thermal stability and controlled release of essential oils in antimicrobial films
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Ehud Banin, Roni Efrati, Anina Haberer, A. Dotan, Amos Ophir, Michal Natan, and Avishay Pelah
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Materials science ,Polymers and Plastics ,Materials Chemistry ,Thermal stability ,General Chemistry ,Composite material ,Antimicrobial ,Controlled release ,Surfaces, Coatings and Films - Published
- 2014
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40. The effect of polyethylene crystallinity and polarity on thermal stability and controlled release of essential oils in antimicrobial films
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Roni Efrati, Avishay Pelah, Michal Natan, A. Dotan, Ehud Banin, Anina Haberer, and Amos Ophir
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chemistry.chemical_classification ,Materials science ,Polymers and Plastics ,Crystallization of polymers ,General Chemistry ,Polymer ,Polyethylene ,Surfaces, Coatings and Films ,law.invention ,chemistry.chemical_compound ,Crystallinity ,Montmorillonite ,chemistry ,Chemical engineering ,law ,Desorption ,Materials Chemistry ,Thermal stability ,Crystallization ,Composite material - Abstract
Antimicrobial packaging can preserve and increase shelf life of free preservatives food products. Active materials present in the packaging material can migrate, in a controlled manner, to the food surface, avoiding bacterial and fungal proliferation and keeping the food product edible for longer periods of time. Essential oils (EO) are natural antimicrobial agents that can be released to the headspace with no direct contact between the package and the food. To minimize loses of EO during high heat melt processing, a three stages process was implemented and tested. Antimicrobial films were prepared by melt mixing a variety of polyethylene copolymers in the presence of organo-modified montmorillonite nano clay (NC) and thymol, an EO present in oregano and thyme. A controlled EO desorption from films can be achieved by changing the polymer crystallinity and polarity. As the crystallinity increased, the thermal stability of the EO during the extrusion process improved. The addition of NC affects the structure and homogeneity of the crystals. The combination of high polymer crystallinity and chemical affinity between EO and NC increased the thermal stability of the EO during film processing, enabling to control the desorption rate. The effect of multilayer structure based on varied densities and polarities was also studied. Increasing the polarity of the outer layers in multilayered film reduced the EO desorption rate as a result of chemical interactions between the polymer and the EO. The final antimicrobial activity of the films was also found to be dependent on the EO partitioning. © 2014 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2014, 131, 40309.
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- 2014
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41. Synthesis and characterization of crosslinked polyisothiouronium methylstyrene nanoparticles of narrow size distribution for antibacterial and antibiofilm applications
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Michal Natan, Enav Corem-Salkmon, Sarit Cohen, Chen Gelber, Ehud Banin, and Shlomo Margel
- Subjects
Keratinocytes ,Nanoparticle ,Medicine (miscellaneous) ,Pharmaceutical Science ,02 engineering and technology ,01 natural sciences ,Applied Microbiology and Biotechnology ,Dispersion polymerization ,Polymerization ,chemistry.chemical_compound ,Coated Materials, Biocompatible ,Organic chemistry ,Cell Line, Transformed ,chemistry.chemical_classification ,Polyethylene Terephthalates ,Biofilm ,Polymer ,021001 nanoscience & nanotechnology ,Anti-Bacterial Agents ,Cross-Linking Reagents ,Monomer ,Pseudomonas aeruginosa ,Isothioronium methylstyrene ,Methacrylates ,Molecular Medicine ,0210 nano-technology ,Antibacterial activity ,Staphylococcus aureus ,Isothiouronium ,Cell Survival ,Listeria ,Biomedical Engineering ,Bioengineering ,010402 general chemistry ,Styrenes ,Escherichia coli ,Humans ,Particle Size ,Research ,technology, industry, and agriculture ,Combinatorial chemistry ,0104 chemical sciences ,Antibacterial ,chemistry ,Biofilms ,Nanoparticles ,Ethylene glycol ,Isothiuronium - Abstract
Background Isothiouronium salts are well known in their variety of antimicrobials activities. The use of polymeric biocides, polymers with antimicrobial activities, is expected to enhance the efficacy of some existing antimicrobial agents, thus minimizing the environmental problems accompanying conventional antimicrobials. Methods The current manuscript describes the synthesis and characterization of crosslinked polyisothiouronium methylstyrene (PITMS) nanoparticles (NPs) of narrow size distribution by dispersion co-polymerization of the monomer isothiouronium methylstyrene with the crosslinking monomer ethylene glycol dimetacrylate. Results and discussion The effect of total monomer, crosslinker and initiator concentrations on the size and size distribution of the formed NPs was also elucidated. The bactericidal activity of PITMS NPs of 67 ± 8 nm diameter was illustrated for 4 bacterial pathogens: Listeria innocua, Escherichia coli, Pseudomonas aeruginosa and Staphylococcus aureus. In order to demonstrate the potential of these PITMS NPs as inhibitor of biofilm formation, polyethylene terephthalate (PET) films were thin-coated with the PITMS NPs. The formed PET/PITMS films reduced the viability of the biofilm of Listeria by 2 orders of magnitude, making the coatings excellent candidates for further development of non-fouling surfaces. In addition, PITMS NP coatings were found to be non-toxic in HaCaT cells. Conclusions The high antibacterial activity and effective inhibition of bacterial adsorption indicate the potential of these nanoparticles for development of new types of antibacterial and antibiofilm additives. Electronic supplementary material The online version of this article (doi:10.1186/s12951-016-0208-7) contains supplementary material, which is available to authorized users.
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