Selective identification, characterization and determination of dissolved silver(i) and silver nanoparticles based on single particle detection by inductively coupled plasma mass spectrometry

Laborda, Francisco; Jiménez-Lamana, Javier; Bolea, Eduardo; Castillo, Juan R.

doi:10.1039/c0ja00098a

Cited by 339 publications

(309 citation statements)

References 37 publications

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“…While single particle ICP-MS was proposed for quantification of AgNPs and dissolved Ag(I), it only allows for the quantification of NPs with sizes ≥20 nm, as small NPs are hardly distinguished from the metal ions. 28,29 Although filtration, 30 centrifugation, 7 centrifugal ultrafiltration, 11 and diffusion gradient thin film (DGT) 31 were off-line coupled with ICP-MS, inductively coupled plasma optical emission spectrometer (ICP-OES) or atomic absorption spectroscopy (AAS) for the analysis of AgNPs and Ag(I), these separation techniques are unable to distinguish the small sized AgNP clusters from Ag(I). While this limitation can be overcome by separation with dialysis, 18 cloud point extraction (CPE), 32−37 and ion-exchange resin method, 35,38 these techniques required a relatively long separation time that is between 40 min and 45 h. To overcome this restriction, ICP-MS was online coupled with asymmertric flow field-flow fractionation 39−41 for selective determination of AgNPs in the presence of Ag(I), and with liquid chromatography (LC) 42 or capillary electrophoresis (CE) 43 for speciation test of AgNPs and Ag(I).…”

Section: ■ Introdcutionmentioning

confidence: 99%

Rapid Chromatographic Separation of Dissoluble Ag(I) and Silver-Containing Nanoparticles of 1–100 Nanometer in Antibacterial Products and Environmental Waters

Zhou

Liu

2014

Environ. Sci. Technol.

107

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Sensitive and rapid methods for speciation analysis of nanoparticulate Ag (NAg) and Ag(I) in complex matrices are urgently needed for understanding the environmental effects and biological toxicity of silver nanoparticles (AgNPs). Herein we report the development of a universal liquid chromatography (LC) method for rapid and high resolution separation of dissoluble Ag(I) from nanoparticles covering the entire range of 1−100 nm in 5 min. By using a 500 Å poresize amino column, and an aqueous mobile phase containing 0.1% (v/v) FL-70 (a surfactant) and 2 mM Na 2 S 2 O 3 at a flow rate of 0.7 mL/min, all the nanoparticles of various species such as Ag and Ag 2 S were eluted in one fraction, while dissoluble Ag(I) was eluted as a baseline separated peak. The dissoluble Ag(I) was quantified by the online coupled ICP-MS with a detection limit of 0.019 μg/L. The NAg was quantified by subtracting the dissoluble Ag(I) from the total Ag content, which was determined by ICP-MS after digestion of the sample without LC separation. While the addition of FL-70 and Na 2 S 2 O 3 into the mobile phase is essential to elute NAg and Ag(I) from the column, the use of 500 Å poresize column is the key to baseline separation of Ag(I) from ∼1 nm AgNPs. The feasibility of the proposed method was demonstrated in speciation analysis of dissoluble Ag(I) and NAg in antibacterial products and environmental waters, with very good chromatographic repeatability (relative standard deviations) in both peak area (<2%) and retention time (<0.6%), excellent spiked recoveries in the range of 84.7−102.7% for Ag(I) and 81.3−106.3% for NAg. Our work offers a novel approach to rapid and baseline separation of dissoluble metal ions from their nanoparticulate counterparts covering the whole range of 1−100 nm.

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Section: ■ Introdcutionmentioning

confidence: 99%

Rapid Chromatographic Separation of Dissoluble Ag(I) and Silver-Containing Nanoparticles of 1–100 Nanometer in Antibacterial Products and Environmental Waters

Zhou

Liu

2014

Environ. Sci. Technol.

107

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“…[92][93][94][95][96] However, the size detection limit for this technique is dependent on the signal generated by the ablation of the nanoparticle, which may require a significant amount of ions to generate a recognisable intensity pulse. In addition, although its elemental specificity is a desirable attribute, it may be unable to differentiate between an engineered and naturally occurring nanomaterial of the same elemental composition.…”

mentioning

confidence: 99%

Current status and future direction for examining engineered nanoparticles in natural systems

et al. 2014

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Environmental context. The detection and characterisation of engineered nanomaterials in the environment is essential for exposure and risk assessment for this emerging class of materials. However, the ubiquitous presence of naturally occurring nanomaterials presents a unique challenge for the accurate determination of engineered nanomaterials in environmental matrices. New techniques and methodologies are being developed to overcome some of these issues by taking advantage of subtle differences in the elemental and isotopic ratios within these nanomaterials.Abstract. The increasing manufacture and implementation of engineered nanomaterials (ENMs) will continue to lead to the release of these materials into the environment. Reliably assessing the environmental exposure risk of ENMs will depend highly on the ability to quantify and characterise these materials in environmental samples. However, performing these measurements is obstructed by the complexity of environmental sample matrices, physiochemical processes altering the state of the ENM and the high background of naturally occurring nanoparticles (NNPs), which may be similar in size, shape and composition to their engineered analogues. Current analytical techniques can be implemented to overcome some of these obstacles, but the ubiquity of NNPs presents a unique challenge requiring the exploitation of properties that discriminate engineered and natural nanomaterials. To this end, new techniques are being developed that take advantage of the nature of ENMs to discern them from naturally occurring analogues. This paper reviews the current techniques utilised in the detection and characterisation of ENMs in environmental samples as well as discusses promising new approaches to overcome the high backgrounds of NNPs. Despite their occurrence in the atmosphere and soil, this review will be limited to a discussion of aqueous-based samples containing ENMs, as this environment will serve as a principal medium for the environmental dispersion of ENMs.

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“…In practice, the minimum complete PSD that can be detected depends also on the polydispersity (width) of the sample. In the current case, it was possible to detect the complete PSD of Ag-NPs standards with 30 nm nominal size, in accordance with previous studies (Mitrano et al, 2012a;Laborda et al, 2011).…”

Section: Evaluation Of Analytical Performance and Analytical Figures supporting

confidence: 70%

Determination of emerging contaminants in environmental matrices

Aznar¹

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Selective identification, characterization and determination of dissolved silver(i) and silver nanoparticles based on single particle detection by inductively coupled plasma mass spectrometry

Cited by 339 publications

References 37 publications

Rapid Chromatographic Separation of Dissoluble Ag(I) and Silver-Containing Nanoparticles of 1–100 Nanometer in Antibacterial Products and Environmental Waters

Rapid Chromatographic Separation of Dissoluble Ag(I) and Silver-Containing Nanoparticles of 1–100 Nanometer in Antibacterial Products and Environmental Waters

Current status and future direction for examining engineered nanoparticles in natural systems

Determination of emerging contaminants in environmental matrices

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