Transformation of PVP coated silver nanoparticles in a simulated wastewater treatment process and the effect on microbial communities

BackgroundManufactured silver nanoparticles (AgNPs) are one of the most commonly used nanomaterials in consumer goods and consequently their concentrations in wastewater and hence wastewater treatment plants are predicted to increase. We investigated the fate of AgNPs in sludge that was subjected to aerobic and anaerobic treatment and the impact of AgNPs on microbial processes and communities. The initial identification of AgNPs in sludge was carried out using transmission electron microscopy (TEM) with energy dispersive X-ray (EDX) analysis. The solid phase speciation of silver in sludge and wastewater influent was then examined using X-ray absorption spectroscopy (XAS). The effects of transformed AgNPs (mainly Ag-S phases) on nitrification, wastewater microbial populations and, for the first time, methanogenesis was investigated.ResultsSequencing batch reactor experiments and anaerobic batch tests, both demonstrated that nitrification rate and methane production were not affected by the addition of AgNPs [at 2.5 mg Ag L-1 (4.9 g L-1 total suspended solids, TSS) and 183.6 mg Ag kg -1 (2.9 g kg-1 total solids, TS), respectively].The low toxicity is most likely due to AgNP sulfidation. XAS analysis showed that sulfur bonded Ag was the dominant Ag species in both aerobic (activated sludge) and anaerobic sludge. In AgNP and AgNO3 spiked aerobic sludge, metallic Ag was detected (~15%). However, after anaerobic digestion, Ag(0) was not detected by XAS analysis. Dominant wastewater microbial populations were not affected by AgNPs as determined by DNA extraction and pyrotag sequencing. However, there was a shift in niche populations in both aerobic and anaerobic sludge, with a shift in AgNP treated sludge compared with controls. This is the first time that the impact of transformed AgNPs (mainly Ag-S phases) on anaerobic digestion has been reported.ConclusionsSilver NPs were transformed to Ag-S phases during activated sludge treatment (prior to anaerobic digestion). Transformed AgNPs, at predicted future Ag wastewater concentrations, did not affect nitrification or methanogenesis. Consequently, AgNPs are very unlikely to affect the efficient functioning of wastewater treatment plants. However, AgNPs may negatively affect sub-dominant wastewater microbial communities.

[1]  M. A. Kiser,et al.  Nanomaterial transformation and association with fresh and freeze-dried wastewater activated sludge: implications for testing protocol and environmental fate. , 2012, Environmental Science and Technology.

[2]  David J. Chittleborough,et al.  A method for determination of retention of silver and cerium oxide manufactured nanoparticles in soils , 2010 .

[3]  Paul Westerhoff,et al.  Nanoparticle silver released into water from commercially available sock fabrics. , 2008, Environmental science & technology.

[4]  M A Kiser,et al.  Titanium nanomaterial removal and release from wastewater treatment plants. , 2009, Environmental science & technology.

[5]  T. Sham,et al.  X-ray studies of the structure and electronic behavior of alkanethiolate-capped gold nanoparticles: the interplay of size and surface effects. , 2003, Physical review letters.

[6]  J. Boyer,et al.  Changes in Community Structure of Sediment Bacteria Along the Florida Coastal Everglades Marsh–Mangrove–Seagrass Salinity Gradient , 2010, Microbial Ecology.

[7]  Gregory V Lowry,et al.  Sulfidation processes of PVP-coated silver nanoparticles in aqueous solution: impact on dissolution rate. , 2011, Environmental science & technology.

[8]  K. Hungerbühler,et al.  Estimation of cumulative aquatic exposure and risk due to silver: contribution of nano-functionalized plastics and textiles. , 2008, The Science of the total environment.

[9]  Philippe Ginestet,et al.  Novel predominant archaeal and bacterial groups revealed by molecular analysis of an anaerobic sludge digester. , 2005, Environmental microbiology.

[10]  V. Kunin,et al.  Wrinkles in the rare biosphere: pyrosequencing errors can lead to artificial inflation of diversity estimates. , 2009, Environmental microbiology.

[11]  L. Semprini,et al.  Influence of liberated silver from silver nanoparticles on nitrification inhibition of Nitrosomonas europaea. , 2011, Chemosphere.

[12]  K. K. Hii Chemistry Central Journal , 2007 .

[13]  John Pendergrass,et al.  Project on Emerging Nanotechnologies , 2007 .

[14]  A. Genaidy,et al.  An evidence-based environmental perspective of manufactured silver nanoparticle in syntheses and applications: a systematic review and critical appraisal of peer-reviewed scientific papers. , 2010, The Science of the total environment.

[15]  Michael Burkhardt,et al.  Release of silver nanoparticles from outdoor facades. , 2010, Environmental pollution.

[16]  M. Troussellier,et al.  Evolution of bacterial communities in the Gironde estuary (France) according to a salinity gradient , 1987 .

[17]  Yinguang Chen,et al.  Long-term effects of titanium dioxide nanoparticles on nitrogen and phosphorus removal from wastewater and bacterial community shift in activated sludge. , 2011, Environmental science & technology.

[18]  S. Chae,et al.  Effects of silver nanoparticles on biological nitrogen removal processes. , 2012, Water science and technology : a journal of the International Association on Water Pollution Research.

[19]  M. Elimelech,et al.  Aggregation kinetics of alginate-coated hematite nanoparticles in monovalent and divalent electrolytes. , 2006, Environmental science & technology.

[20]  R. Scholz,et al.  Modeled environmental concentrations of engineered nanomaterials (TiO(2), ZnO, Ag, CNT, Fullerenes) for different regions. , 2009, Environmental science & technology.

[21]  Michael E. Lassman,et al.  Evidence for iron, copper and zinc complexation as multinuclear sulphide clusters in oxic rivers , 2000, Nature.

[22]  J. Baross,et al.  Bacterial diversity in a subseafloor habitat following a deep-sea volcanic eruption. , 2003, FEMS microbiology ecology.

[23]  Hansruedi Siegrist,et al.  Behavior of metallic silver nanoparticles in a pilot wastewater treatment plant. , 2011, Environmental science & technology.

[24]  D. Moreira,et al.  Archaeal and bacterial community composition of sediment and plankton from a suboxic freshwater pond. , 2007, Research in microbiology.

[25]  Fate and effect of silver on the anaerobic digestion process , 2000 .

[26]  Ketil Hylland,et al.  Characterization of the effluent from a nanosilver producing washing machine. , 2011, Environment international.

[27]  G. Yi Semiconductor Nanostructures for Optoelectronic Devices: Processing, Characterization and Applications , 2012 .

[28]  Víctor Puntes,et al.  Effect of cerium dioxide, titanium dioxide, silver, and gold nanoparticles on the activity of microbial communities intended in wastewater treatment. , 2012, Journal of hazardous materials.

[29]  Damien J Batstone,et al.  Increased temperature in the thermophilic stage in temperature phased anaerobic digestion (TPAD) improves degradability of waste activated sludge. , 2011, Journal of hazardous materials.

[30]  Paul Westerhoff,et al.  Fate and biological effects of silver, titanium dioxide, and C60 (fullerene) nanomaterials during simulated wastewater treatment processes. , 2012, Journal of hazardous materials.

[31]  O. Choi,et al.  Nitrification inhibition by silver nanoparticles. , 2009, Water science and technology : a journal of the International Association on Water Pollution Research.

[32]  D. Batstone,et al.  4.17 – Anaerobic Processes , 2011 .

[33]  M. D. Kahl,et al.  Effects of laboratory test conditions on the toxicity of silver to aquatic organisms , 1998 .

[34]  D. Chittleborough,et al.  Retention and dissolution of engineered silver nanoparticles in natural soils , 2012 .

[35]  J. Kromkamp,et al.  Changes in Phytoplankton Biomass in the Western Scheldt Estuary During the Period 1978–2006 , 2010 .

[36]  Bernd Nowack,et al.  Behavior of silver nanotextiles during washing , 2009 .

[37]  T. Rajh,et al.  Fe2O3 Nanoparticle Structures Investigated by X-ray Absorption Near-Edge Structure, Surface Modifications, and Model Calculations , 2002 .

[38]  N. Youssef,et al.  Novel High-Rank Phylogenetic Lineages within a Sulfur Spring (Zodletone Spring, Oklahoma), Revealed Using a Combined Pyrosequencing-Sanger Approach , 2012, Applied and Environmental Microbiology.

[39]  Wolfgang Knoll,et al.  Characterization and Applications , 2011 .

[40]  Kelly G Pennell,et al.  Kinetics and mechanisms of nanosilver oxysulfidation. , 2011, Environmental science & technology.

[41]  J E O N G K I M,et al.  Discovery and Characterization of Silver Sulfide Nanoparticles in Final Sewage Sludge Products , 2010 .

[42]  G. Batley,et al.  Fate of Manufactured Nanomaterials in the Australian Environment , 2010 .

[43]  Zhiqiang Hu,et al.  Potential nanosilver impact on anaerobic digestion at moderate silver concentrations. , 2012, Water research.

[44]  Kaiyang Li,et al.  Removal of silver nanoparticles in simulated wastewater treatment processes and its impact on COD and NH(4) reduction. , 2012, Chemosphere.

[45]  F. Chen,et al.  Experimental factors affecting PCR-based estimates of microbial species richness and evenness , 2010, The ISME Journal.

[46]  C. Gunsch,et al.  Impacts of silver nanoparticle coating on the nitrification potential of Nitrosomonas europaea. , 2012, Environmental science & technology.

[47]  Elisabeth Müller,et al.  Removal of oxide nanoparticles in a model wastewater treatment plant: influence of agglomeration and surfactants on clearing efficiency. , 2008, Environmental science & technology.