An electron microscopy based method for the detection and quantification of nanomaterial number concentration in environmentally relevant media.

Improved detection and characterization of nanomaterials (NMs) in complex environmental media requires the development of novel sampling approaches to improve the detection limit to be close to environmentally realistic concentrations. Transmission electron microscopy (TEM) is an indispensable metrological tool in nanotechnology and environmental nanoscience due to its high spatial resolution and analytical capabilities when coupled to spectroscopic techniques. However, these capabilities are hampered by the conventional sample preparation methods, which suffer from low NM recovery. The current work presents a validated, fully quantitative sampling technique for TEM that overcomes conventional sample preparation shortcomings, and thus enables the use of TEM for measurement of particle number concentration and their detection in complex media at environmentally realistic concentrations. This sampling method is based on ultracentrifugation of NMs from suspension onto a poly-l-lysine (PLL) functionalized TEM grid, using active deposition (by ultracentrifugation) and retention (by PLL interactions with NM surface) of NMs on the substrate, enabling fully quantitative analysis. Similar analysis with AFM was satisfactory in simple media but the lack of chemical-selectivity of AFM limits its applicability for the detection of NMs in complex environmental samples. The sampling approach was validated using both citrate- and PVP-coated AuNMs in pure water, which demonstrated an even distribution of NM on the TEM grid and high NM recovery (80-100%) at environmentally relevant NM concentrations (ca. 0.20-100 μg L(-1)). The applicability of the sampling method to complex environmental samples was demonstrated by the quantification of particle number concentration of AuNMs in EPA soft water (with and without Suwannee River fulvic acid) and lake water. This sample preparation approach is also applicable to other types of NMs with some modifications (e.g. centrifugation force and time) to insure full sample recovery. This TEM sampling method is key to the accurate quantification of NM number concentration, and therefore to improving our understanding of environmental fate, behavior, effects and dose of NMs.

[1]  G. G. Leppard Nanoparticles in the Environment as Revealed by Transmission Electron Microscopy:Detection, Characterisation and Activities , 2012 .

[2]  M. Baalousha,et al.  Rationalizing nanomaterial sizes measured by atomic force microscopy, flow field-flow fractionation, and dynamic light scattering: sample preparation, polydispersity, and particle structure. , 2012, Environmental science & technology.

[3]  M. Baalousha,et al.  Methods for Measuring Concentration (Mass, Surface Area and Number) of Nanomaterials , 2015 .

[4]  A. Malloy,et al.  Characterisation of nanoparticle size and concentration for toxicological studies. , 2011, Journal of biomedical nanotechnology.

[5]  M. Baalousha,et al.  3D characterization of natural colloids by FlFFF-MALLS-TEM , 2005, Analytical and bioanalytical chemistry.

[6]  Mohammed Baalousha,et al.  Aggregation and disaggregation of iron oxide nanoparticles: Influence of particle concentration, pH and natural organic matter. , 2009, The Science of the total environment.

[7]  Michel Boissière,et al.  潜在的な発光および磁気2モード画像化プローブとしてのポリオール合成Zn0.9Mn0.1ナノ粒子:合成,特性評価,および毒性研究 , 2012 .

[8]  David M. Brown,et al.  The Importance of Surface Area and Specific Reactivity in the Acute Pulmonary Inflammatory Response to Particles , 2002 .

[9]  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.

[10]  T. Hofmann,et al.  Nanoparticles: structure, properties, preparation and behaviour in environmental media , 2008, Ecotoxicology.

[11]  Jamie R. Lead,et al.  Quantitative measurement of the nanoparticle size and number concentration from liquid suspensions by atomic force microscopy. , 2014, Environmental science. Processes & impacts.

[12]  Mark R Viant,et al.  Aggregation and dispersion of silver nanoparticles in exposure media for aquatic toxicity tests. , 2011, Journal of chromatography. A.

[13]  Albert A Koelmans,et al.  Analysis of engineered nanomaterials in complex matrices (environment and biota): General considerations and conceptual case studies , 2012, Environmental toxicology and chemistry.

[14]  David M. Brown,et al.  Proinflammogenic Effects of Low-Toxicity and Metal Nanoparticles In Vivo and In Vitro: Highlighting the Role of Particle Surface Area and Surface Reactivity , 2007, Inhalation toxicology.

[15]  NanoParticle Tracking Analysis – The NANOSIGHT system , 2006 .

[16]  Manuel D. Montaño,et al.  Current status and future direction for examining engineered nanoparticles in natural systems , 2014 .

[17]  Fadri Gottschalk,et al.  Environmental concentrations of engineered nanomaterials: review of modeling and analytical studies. , 2013, Environmental pollution.

[18]  Vicki Stone,et al.  Characterization of cerium oxide nanoparticles—Part 1: Size measurements , 2012, Environmental toxicology and chemistry.

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

[20]  E. Achterberg,et al.  Visualisation of natural aquatic colloids and particles -- a comparison of conventional high vacuum and environmental scanning electron microscopy. , 2005, Journal of environmental monitoring : JEM.

[21]  Serge Stoll,et al.  A Generalized Description of Aquatic Colloidal Interactions: The Three-colloidal Component Approach , 1998 .

[22]  Stefan Seeger,et al.  Industrial production quantities and uses of ten engineered nanomaterials in Europe and the world , 2012, Journal of Nanoparticle Research.

[23]  Jamie R Lead,et al.  Nanomaterials in the environment: Behavior, fate, bioavailability, and effects , 2008, Environmental toxicology and chemistry.

[24]  C. Weber Methods for measuring the acute toxicity of effluents and receiving waters to freshwater and marine organisms , 1991 .

[25]  E. Balnois,et al.  Characteristic features of the major components of freshwater colloidal organic matter revealed by transmission electron and atomic force microscopy , 1999 .

[26]  Vincent Castranova,et al.  Nanoparticle inhalation augments particle-dependent systemic microvascular dysfunction , 2008, Particle and Fibre Toxicology.

[27]  I. Jones,et al.  Characterization of cerium oxide nanoparticles—Part 2: Nonsize measurements , 2012, Environmental toxicology and chemistry.

[28]  Craig A. Poland,et al.  Nanotoxicity: challenging the myth of nano-specific toxicity. , 2013, Current opinion in biotechnology.

[29]  A. Malloy,et al.  NanoParticle Tracking Analysis – The Halo™ System , 2006 .

[30]  J. Lead,et al.  Silver nanoparticles: behaviour and effects in the aquatic environment. , 2011, Environment international.

[31]  V. Castranova,et al.  Pulmonary response to intratracheal instillation of ultrafine versus fine titanium dioxide: role of particle surface area , 2008, Particle and Fibre Toxicology.