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Background and Objective: Iron oxide nanoparticles, including nanoparticles is important in industry and medicine. Nanoparticles affect on detoxification of environmental pollutants such as Pesticides and chlorinated organic solvents.This study was done to evaluate the short term effect of Fe2NiO4 composite nanoparticle on kidney function indeces in wistar rats.

Methods: In this experimental study, Twenty four Wistar rat were randomly allocated into three groups, including: control, treated groups 1 and 2. Animales in control, treated groups 1 and 2 were received 0.5cc of saline, 0.5cc of solution containing 100, 200 ppm Fe2NiO4 for 7 days, respectively. Uric acid, ceratinine and urea (BUN) were measured at day 2, 7 and 14.

Results: BUN level in treated groups 1 and 2 significantly reduced in comparison with control group at day 7, 14 after intervention (P<0.05). Uric acid level in treated groups 1 and 2 significantly increased at day 7 and 14. 2 week after intervention, the mean creatinine levels in treated group 2 group significantly reduced in compare  to the in treated group 1 and controls (P<0.05).

Conclusion: It seems that the application of Fe2NiO4 nanoparticles in biological system has no toxic effect on the kidney function indeces.

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Background and Objective: Organic aromatic compounds as common environmental pollutants can be existing in the effluent of different industries in concentrations ranging from trace quantities to hundreds of milligrams per liter. Phenol compounds extremely have been used in pharmaceutical, wood industry and paper and dyes industries which introduced to environment via effluents. This study was done to evaluate the efficacy of persulfate activated by Fe²⁺ in the present of UV for removal of phenol from aqueous solutions.
Methods: This photocatalytic degradation experiment was performed in batch mode using a 2.5 L cylindrical reactor equipped with low-pressure Hg vapor lamp of 55 W for wavelength production of 253.7 nm. The effects of operating parameters such as pH of the solution (pH: 3-10), different initial persulfate concentration (10-75 mmol/l), initial Fe²⁺ concentration (5-30 mmol/l) and initial phenol concentration (10-100 mg/l). Concentration changes of phenol were determined using UV–VIS spectroscopy at the wavelength of 500 nm.
Results: Degradation of phenol was significantly decreased with increasing of pH from 3 to 10, whereas the highest phenol removal rate was 82% at pH=3 in 45 min contact time. Also, the phenol removal rate is depending on initial persulfate and Fe²⁺ concentration. The degradation of phenol by this photocatalytic followed first order rate decay kinetics (R²>98%(. Under optimum operational conditions, the removal of TOC was obtained to be 61% in 45 min contact time.
Conclusion: This study indicated that activation of persulfate by Fe²⁺ in the present of UV process could serve as a novel treatment technique for removal of phenol in aqueous solution.
 

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Background and Objective: Binding of antibiotics to nanoparticles increases the antibacterial potential of nanoparticles and antibiotics. This study was performed to determine the antibacterial and hemolytic effect of zinc / ferrite / cellulose nanocomposite (ZnFe2O4 @ Cell) (single nanoparticle), zinc / ferrite / cellulose nanocomposite was aminated with 3-aminopropyltriethoxysilane (APTES) with the name of ZnFe2O4@Cell@APTES (Coated nanocomposite) and ZnFe2O4@Cell@APTES@Van nanocomposite (coated nanocomposite bound to vancomycin) against gram-negative bacteria Escherichia coli (E. coli) and Pseudomonas aeruginosa (P. aeruginosa) and gram-positive bacterium Staphylococcus aureus (S. aureus).
Methods: In this descriptive study, antibacterial-activity was evaluated by broth macro dilution method. Minimum inhibitory concentration (MIC) and minimum lethal concentration (MBC) were determined for E. coli, S. aurous and P. aeruginosa. The hemolytic activity of nanoparticles was investigated by colorimetric method.
Results: Nanoparticles did not have hemolytic activity. ZnFe2O4@Cell and ZnFe2O4@Cell@APTES@Van did not have a significant antibacterial effect against gram-positive and gram-negative bacteria, and vancomycin binding resulted in antibacterial-activity. ZnFe2O4@Cell@APTES@Van inhibited the growth of Gram-negative bacteria Escherichia coli and Pseudomonas aeruginosa. The growth of E. coli was reduced to 85% at a concentration of 0.4 mg/ml and a concentration of 0.1 mg nanoparticles completely prevented the growth of P. aeruginosa. The growth of gram-positive S. aureus bacteria at a concentration of 0.3 mg/ml nanoparticles was completely stopped.
Conclusion: Vancomycin-modified nanocomposite has antibacterial-activity against both gram-positive and gram-negative bacteria and has the potential to overcome the antibiotic resistance of bacteria.