Asymmetrical Flow Field-Flow Fractionation for Sizing of Gold Nanoparticles in Suspension

Particle size is arguably the most important physico-chemical parameter associated with the notion of a nanoparticle. Precise knowledge of the size and size distribution of nanoparticles is of utmost importance for various applications. The size range is also important, as it defines the most “activ...

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Veröffentlicht in:	Journal of Visualized Experiments 2020-09 (163)
Hauptverfasser:	Drexel, Roland, Sogne, Vanessa, Dinkel, Magdalena, Meier, Florian, Klein, Thorsten
Format:	Artikel
Sprache:	eng
Schlagworte:	Bioengineering Calibration Dynamic Light Scattering Fractionation, Field Flow - methods Gold - chemistry Hydrodynamics Metal Nanoparticles - chemistry Particle Size Reference Standards Reproducibility of Results Solutions Static Electricity Suspensions - chemistry Time Factors
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creator	Drexel, Roland Sogne, Vanessa Dinkel, Magdalena Meier, Florian Klein, Thorsten
description	Particle size is arguably the most important physico-chemical parameter associated with the notion of a nanoparticle. Precise knowledge of the size and size distribution of nanoparticles is of utmost importance for various applications. The size range is also important, as it defines the most “active” component of a nanoparticle dose.Asymmetrical Flow Field-Flow Fractionation (AF4) is a powerful technique for sizing of particles in suspension in the size range of approximately 1–1000 nm. There are several ways to derive size information from an AF4 experiment. Besides coupling AF4 online with size-sensitive detectors based on the principles of Multi-Angle Light Scattering or Dynamic Light Scattering, there is also the possibility to correlate the size of a sample with its retention time using a well-established theoretical approach (FFF theory) or by comparing it with the retention times of well-defined particle size standards (external size calibration).We here describe the development and in-house validation of a standard operating procedure (SOP) for sizing of an unknown gold nanoparticle sample by AF4 coupled with UV-vis detection using external size calibration with gold nanoparticle standards in the size range of 20–100 nm. This procedure provides a detailed description of the developed workflow including sample preparation, AF4 instrument setup and qualification, AF4 method development and fractionation of the unknown gold nanoparticle sample, as well as the correlation of the obtained results with the established external size calibration. The SOP described here was eventually successfully validated in the frame of an interlaboratory comparison study highlighting the excellent robustness and reliability of AF4 for sizing of nanoparticulate samples in suspension.
doi_str_mv	10.3791/61757
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Besides coupling AF4 online with size-sensitive detectors based on the principles of Multi-Angle Light Scattering or Dynamic Light Scattering, there is also the possibility to correlate the size of a sample with its retention time using a well-established theoretical approach (FFF theory) or by comparing it with the retention times of well-defined particle size standards (external size calibration).We here describe the development and in-house validation of a standard operating procedure (SOP) for sizing of an unknown gold nanoparticle sample by AF4 coupled with UV-vis detection using external size calibration with gold nanoparticle standards in the size range of 20–100 nm. 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Besides coupling AF4 online with size-sensitive detectors based on the principles of Multi-Angle Light Scattering or Dynamic Light Scattering, there is also the possibility to correlate the size of a sample with its retention time using a well-established theoretical approach (FFF theory) or by comparing it with the retention times of well-defined particle size standards (external size calibration).We here describe the development and in-house validation of a standard operating procedure (SOP) for sizing of an unknown gold nanoparticle sample by AF4 coupled with UV-vis detection using external size calibration with gold nanoparticle standards in the size range of 20–100 nm. 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subjects	Bioengineering Calibration Dynamic Light Scattering Fractionation, Field Flow - methods Gold - chemistry Hydrodynamics Metal Nanoparticles - chemistry Particle Size Reference Standards Reproducibility of Results Solutions Static Electricity Suspensions - chemistry Time Factors
title	Asymmetrical Flow Field-Flow Fractionation for Sizing of Gold Nanoparticles in Suspension
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