Your search keyword '"Metal Nanoparticles microbiology"' showing total 6 results

1. Biosynthesis of bismuth selenide nanoparticles using chalcogen-metabolizing bacteria.

Author

Kuroda M, Suda S, Sato M, Ayano H, Ohishi Y, Nishikawa H, Soda S, and Ike M

Subjects

Bismuth, Metal Nanoparticles microbiology, Selenium Compounds, Semiconductors microbiology, Chalcogens metabolism, Ochrobactrum anthropi metabolism, Organoselenium Compounds metabolism, Pseudomonas metabolism, Stenotrophomonas maltophilia metabolism

Abstract

Cost and energy reductions in the production process of bismuth chalcogenide (BC) semiconductor materials are essential to make thermoelectric generators comprised of BCs profitable and CO 2 neutral over their life cycle. In this study, as an eco-friendly production method, bismuth selenide (Bi 2 Se 3 ) nanoparticles were synthesized using the following five strains of chalcogen-metabolizing bacteria: Pseudomonas stutzeri NT-I, Pseudomonas sp. RB, Stenotrophomonas maltophilia TI-1, Ochrobactrum anthropi TI-2, and O. anthropi TI-3 under aerobic conditions. All strains actively volatilized selenium (Se) by reducing selenite, possibly to organoselenides. In the growth media containing bismuth (Bi) and Se, all strains removed Bi and Se concomitantly and synthesized nanoparticles containing Bi and Se as their main components. Particles synthesized by strain NT-I had a theoretical elemental composition of Bi 2 Se 3 , whereas those synthesized by other strains contained a small amount of sulfur in addition to Bi and Se, making strain NT-I the best Bi 2 Se 3 synthesizer among the strains used in this study. The particle sizes were 50-100 nm in diameter, which is sufficiently small for nanostructured semiconductor materials that exhibit quantum size effect. Successful synthesis of Bi 2 Se 3 nanoparticles could be attributed to the high Se-volatilizing activities of the bacterial strains. Selenol-containing compounds as intermediates of Se-volatilizing metabolic pathways, such as methane selenol and selenocysteine, may play an important role in biosynthesis of Bi 2 Se 3 .

Published

2019

2. Biomining of iron-containing nanoparticles from coal tailings.

Author

Maass D, de Medeiros Machado M, Rovaris BC, Bernardin AM, de Oliveira D, and Hotza D

Subjects

Biomass, Biotransformation, Environmental Pollutants metabolism, Metal Nanoparticles chemistry, Particle Size, Rhodococcus metabolism, Sulfur metabolism, Coal, Iron metabolism, Metal Nanoparticles microbiology, Mining

Abstract

Sulfur minerals originating from coal mining represent an important environmental problem. Turning these wastes into value-added by-products can be an interesting alternative. Biotransformation of coal tailings into iron-containing nanoparticles using Rhodococcus erythropolis ATCC 4277 free cells was studied. The influence of culture conditions (stirring rate, biomass concentration, and coal tailings ratio) in the particle size was investigated using a 2 3 full factorial design. Statistical analysis revealed that higher concentrations of biomass produced larger sized particles. Conversely, a more intense stirring rate of the culture medium and a higher coal tailings ratio (% w/w) led to the synthesis of smaller particles. Thus, the culture conditions that produced smaller particles (< 50 nm) were 0.5 abs of normalized biomass concentration, 150 rpm of stirring rate, and 2.5% w/w of coal tailings ratio. Composition analyses showed that the biosynthesized nanoparticles are formed by iron sulfate. Conversion ratio of the coal tailings into iron-containing nanoparticles reached 19%. The proposed biosynthesis process, using R. erythropolis ATCC 4277 free cells, seems to be a new and environmentally friendly alternative for sulfur minerals reuse.

Published

2019

3. Role of plant phytochemicals and microbial enzymes in biosynthesis of metallic nanoparticles.

Author

Ovais M, Khalil AT, Islam NU, Ahmad I, Ayaz M, Saravanan M, Shinwari ZK, and Mukherjee S

Subjects

Bacteria enzymology, Flavonoids metabolism, Flavonoids physiology, Fungi enzymology, Hydroxybenzoates metabolism, Terpenes metabolism, Bacteria metabolism, Fungi metabolism, Green Chemistry Technology, Metal Nanoparticles chemistry, Metal Nanoparticles microbiology, Nanotechnology, Phytochemicals biosynthesis, Phytochemicals metabolism, Plants, Medicinal metabolism

Abstract

Metal-based nanoparticles have gained tremendous popularity because of their interesting physical, biological, optical, and magnetic properties. These nanoparticles can be synthesized using a variety of different physical, chemical, and biological techniques. The biological means are largely preferred as it provides an environmentally benign, green, and cost-effective route for the biosynthesis of nanoparticles. These bioresources can act as a scaffold, thereby playing the role of reducing as well as capping agents in the biosynthesis of nanoparticles. Medicinal plants tend to have a complex phytochemical constituent such as alcohols, phenols, terpenes, alkaloids, saponins, and proteins, while microbes have key enzymes which can act as reducing as well as stabilizing agent for NP synthesis. However, the mechanism of biosynthesis is still highly debatable. Herein, the present review is directed to give an updated comprehensive overview towards the mechanistic aspects in the biosynthesis of nanoparticles via plants and microbes. Various biosynthetic pathways of secondary metabolites in plants and key enzyme production in microbes have been discussed in detail, along with the underlying mechanisms for biogenic NP synthesis.

Published

2018

4. Palladium nanoparticles produced by fermentatively cultivated bacteria as catalyst for diatrizoate removal with biogenic hydrogen.

Author

Hennebel T, Van Nevel S, Verschuere S, De Corte S, De Gusseme B, Cuvelier C, Fitts JP, van der Lelie D, Boon N, and Verstraete W

Subjects

Bacteria chemistry, Biodegradation, Environmental, Bioreactors microbiology, Catalysis, Environmental Restoration and Remediation instrumentation, Fermentation, Kinetics, Metal Nanoparticles microbiology, Oxidation-Reduction, Palladium metabolism, Bacteria metabolism, Diatrizoate metabolism, Environmental Restoration and Remediation methods, Hydrogen metabolism, Metal Nanoparticles chemistry, Palladium chemistry, Water Pollutants, Chemical metabolism

Abstract

A new biological inspired method to produce nanopalladium is the precipitation of Pd on a bacterium, i.e., bio-Pd. This bio-Pd can be applied as catalyst in dehalogenation reactions. However, large amounts of hydrogen are required as electron donor in these reactions resulting in considerable costs. This study demonstrates how bacteria, cultivated under fermentative conditions, can be used to reductively precipitate bio-Pd catalysts and generate the electron donor hydrogen. In this way, one could avoid the costs coupled to hydrogen supply. The catalytic activities of Pd(0) nanoparticles produced by different strains of bacteria (bio-Pd) cultivated under fermentative conditions were compared in terms of their ability to dehalogenate the recalcitrant aqueous pollutants diatrizoate and trichloroethylene. While all of the fermentative bio-Pd preparations followed first order kinetics in the dehalogenation of diatrizoate, the catalytic activity differed systematically according to hydrogen production and starting Pd(II) concentration in solution. Batch reactors with nanoparticles formed by Citrobacter braakii showed the highest diatrizoate dehalogenation activity with first order constants of 0.45 ± 0.02 h⁻¹ and 5.58 ± 0.6 h⁻¹ in batches with initial concentrations of 10 and 50 mg L⁻¹ Pd, respectively. Nanoparticles on C. braakii, used in a membrane bioreactor treating influent containing 20 mg L⁻¹ diatrizoate, were capable of dehalogenating 22 mg diatrizoate mg⁻¹ Pd over a period of 19 days before bio-Pd catalytic activity was exhausted. This study demonstrates the possibility to use the combination of Pd(II), a carbon source and bacteria under fermentative conditions for the abatement of environmental halogenated contaminants.

Published

2011

5. Mechanistic aspects in the biogenic synthesis of extracellular metal nanoparticles by peptides, bacteria, fungi, and plants.

Author

Durán N, Marcato PD, Durán M, Yadav A, Gade A, and Rai M

Subjects

Metal Nanoparticles microbiology, Bacteria metabolism, Fungi metabolism, Metal Nanoparticles chemistry, Nanotechnology methods, Peptides chemistry, Plants metabolism

Abstract

Metal nanoparticles have been studied and applied in many areas including the biomedical, agricultural, electronic fields, etc. Several products of colloidal silver are already on the market. Research on new, eco-friendly and cheaper methods has been initiated. Biological production of metal nanoparticles has been studied by many researchers due to the convenience of the method that produces small particles stabilized by protein. However, the mechanism involved in this production has not yet been elucidated although hypothetical mechanisms have been proposed in the literature. Thus, this review discusses the various mechanisms provided for the biological synthesis of metal nanoparticles by peptides, bacteria, fungi, and plants. One thing that is clear is that the mechanistic aspects in some of the biological systems need more detailed studies.

Published

2011

6. Magnetically recyclable, antimicrobial, and catalytically enhanced polymer-assisted "green" nanosystem-immobilized Aspergillus niger amyloglucosidase.

Author

Konwarh R, Kalita D, Mahanta C, Mandal M, and Karak N

Subjects

Aspergillus niger chemistry, Bacteria drug effects, Biocatalysis, Green Chemistry Technology instrumentation, Kinetics, Magnetics, Metal Nanoparticles microbiology, Polymers chemistry, Aspergillus niger enzymology, Enzymes, Immobilized chemistry, Fungal Proteins chemistry, Glucan 1,4-alpha-Glucosidase chemistry, Green Chemistry Technology methods, Metal Nanoparticles chemistry, Polymers pharmacology

Abstract

The present work reports the integration of polymer matrix-supported nanomaterial and enzyme biotechnology for development of industrially feasible biocatalysts. Aqueous leaf extract of Mesua ferrea L. was used to prepare silver nanoparticles distributed within a narrow size range (1-12 nm). In situ oxidative technique was used to obtain poly(ethylene glycol)-supported iron oxide nanoparticles (3-5 nm). Sonication-mediated mixing of above nanoparticles generated the immobilization system comprising of polymer-supported silver-iron oxide nanoparticles (20-30 nm). A commercially important enzyme, Aspergillus niger amyloglucosidase was coupled onto the immobilization system through sonication. The immobilization enzyme registered a multi-fold increment in the specific activity (807 U/mg) over the free counterpart (69 U/mg). Considerable initial activity of the immobilized enzyme was retained even after storing the system at room temperature as well as post-repeated magnetic recycling. Evaluation of the commendable starch saccharification rate, washing performance synergy with a panel of commercial detergents, and antibacterial potency strongly forwards the immobilized enzyme as a multi-functional industrially feasible system.

Published

2010