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Background and Objective: Nanosilver particles are one of functional nanotechnology filed. These nanoparticles have antibacterial and antifungal characteritic. Combination therapy is one of new and specific method for therapy of diseases in medicine and pharmacology. Some plants are useful in growth inhibition of Aspergilus Niger. This study was done to evaluate the synergic effect of alcoholic eucalyptus and nanosilver on colony count of Aspergilus Niger. Materials and Methods: In this laboratory study PAN were cultured in PDA medium. Five experimental and one control group were designed for the comparison of synergic effect of alcoholic eucalyptus and nanosilver, nanosilver 50ppm, nanosilver 12.5ppm, eucalyptus ethanolic extract 100%, eucalyptus ethanolic extract 100% mixed with nanosilver 12.5ppm, eucalyptus ethanolic extract mixed with 50ppm, and double distilled water were given to group 1, 2, 3, 4, 5 and control group respectively. Morphological, diameter, and colony numbers in various culture media were compared subsequently. The repeated number of Aspergilus Niger were 24, and they were chosen randomly. Data were analyzed using SPSS-15 and ANOVA test. Results: The Aspergilus niger colony were reduced 8 days following treatment from 200 colony in control group to 90, 75, 55 and 43 in nanosilver group in 12.5 ppm, nanosilver group in 50 ppm, nanosilver group in 50 ppm mixed with eucalyptus ethanolic extract and finally eucalyptus ethanolic extract group, respectivley (P<0.05). The colony count 24 day following treatment were reduced from 200 colony in control group to 42, 14 and 2 in eucalyptus ethanolic extract group, nanosilver group in 12.5 ppm mixed with eucalyptus ethanolic extract and finally nanosilver group in 50 ppm mixed with eucalyptus ethanolic extract, respectivley (P<0.05). Conclusion: This study showed that nanosilver with 50 ppm concentration mixed with eucalyptus ethanolic extract have synergic effect on reducing the Aspergilus niger growth rate.

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Background and Objective: Pollution due to the heavy metals is a problem that may have negative consequences on the hydrosphere. Identification of microorganisms resistant to heavy metals plays an important role in relation to environmental pollution bioremediation. This study was done to assess the antibiotic resistance in isolated bacteria from urban sewage and copper smeltery industrial wastewater. Materials and Methods: This laboratory study was done on the wastewater samples from urban sewage and copper smeltery in Isfahan-Iran, during 2011-12. Heavy metal resistant microorganisms were isolated and enumerated after serial dilution and culturing on PHG agar plates supplemented with 0.5 mM of each heavy metal. The pattern of resistance was assigned by Minimum Inhibitory Concentration (MIC). Antibiotic resistance toward following medicines Ofloxacine, Penicilline, Sulfometoxasole, Lincomycin, Kanamycin, Streptomycin, Clindamycin, Vancomycin, Cefradin and Neomycin were subsequently investigated. Results: The greatest resistance in isolated bacteria has been related to the Ni (MIC: 24 mM) that’s related to the genus of Klebsiella and its minimum MIC is 2mM that’s of Acinetobacter lwoffi, Providencia stuartii, Branhamella. The minimum degree of resistance is related to Cu. Its Maximum MIC related to this metal in swage is 2 mM that’s of Klebsiella pneumoniae and its minimum degree of resistance in copper smeltery effluent is arranged as 1mM related to genus of Pseudomonas alkaligenes. In examining multi metal resistance pattern, the greatest resistance with 8 mM MIC has been related to the Cd, that’s of Ni resistant Moraxella osloensis in Copper smeltery effluent. The highest portion of isolated bacteria were resistant to Pb (P<0.05). The highest resistance of refirary wastewater was to Ni (MIC: 2 mM), which belong to Klebsiella (P<0.05). The lowest belong to Acine to bacter Lwoffi providencia Stuartii, Branhamella (MIC: 2mM) (P<0.05). In urban sewage: the highest resistance belong to copper, which was seen in Klebsiella Pneumoniae (MIC: 2mM). In Antibiogram tests of Klebsiella, Moraxella and Escherichia, it was demonstrated that the metal resistant bacteria were also resistant toward Lincomycin, Kanamycin, Streptomycin, Clindamycin, Vancomycin, Cefradin and Neomycin, as well. Conclusion: Increasing heavy metal resistance in the environment leads to increased antibiotic resistance toward microorganisms.