. 2021 Jan;10(3):e12052.

doi: 10.1002/jev2.12052. Epub 2021 Jan 12.

Measuring particle concentration of multimodal synthetic reference materials and extracellular vesicles with orthogonal techniques: Who is up to the challenge?

Robert Vogel¹, John Savage², Julien Muzard³, Giacomo Della Camera⁴, Gabriele Vella², Alice Law⁵, Marianne Marchioni³, Dora Mehn⁶, Otmar Geiss⁶, Ben Peacock⁵, Dimitri Aubert⁵, Luigi Calzolai⁶, Fanny Caputo⁷, Adriele Prina-Mello^{2

8}

Affiliations

¹ School of Mathematics and Physics The University of Queensland St Lucia Queensland Australia.
² LBCAM Department of Clinical Medicine Trinity Translational Medicine Institute Trinity College Dublin Dublin Ireland.
³ IZON Science Ltd., Burnside Christchurch New Zealand.
⁴ Institute of Biochemistry and Cell Biology CNR Via P. Castellino 111 Napoli Italy.
⁵ NanoFCM Co., Ltd, Medicity Nottingham UK.
⁶ European Commission Joint Research Centre (JRC) Ispra Italy.
⁷ Department of Biotechnology and Nanomedicine SINTEF Industry Trondheim Norway.
⁸ AMBER Centre CRANN Institute, Trinity College Dublin Dublin Ireland.

PMID: 33473263
PMCID: PMC7804049
DOI: 10.1002/jev2.12052

Measuring particle concentration of multimodal synthetic reference materials and extracellular vesicles with orthogonal techniques: Who is up to the challenge?

Robert Vogel et al. J Extracell Vesicles. 2021 Jan.

. 2021 Jan;10(3):e12052.

doi: 10.1002/jev2.12052. Epub 2021 Jan 12.

Authors

Affiliations

¹ School of Mathematics and Physics The University of Queensland St Lucia Queensland Australia.
² LBCAM Department of Clinical Medicine Trinity Translational Medicine Institute Trinity College Dublin Dublin Ireland.
³ IZON Science Ltd., Burnside Christchurch New Zealand.
⁴ Institute of Biochemistry and Cell Biology CNR Via P. Castellino 111 Napoli Italy.
⁵ NanoFCM Co., Ltd, Medicity Nottingham UK.
⁶ European Commission Joint Research Centre (JRC) Ispra Italy.
⁷ Department of Biotechnology and Nanomedicine SINTEF Industry Trondheim Norway.
⁸ AMBER Centre CRANN Institute, Trinity College Dublin Dublin Ireland.

PMID: 33473263
PMCID: PMC7804049
DOI: 10.1002/jev2.12052

Abstract

The measurement of physicochemical properties of polydisperse complex biological samples, for example, extracellular vesicles, is critical to assess their quality, for example, resulting from their production and isolation methods. The community is gradually becoming aware of the need to combine multiple orthogonal techniques to perform a robust characterization of complex biological samples. Three pillars of critical quality attribute characterization of EVs are sizing, concentration measurement and phenotyping. The repeatable measurement of vesicle concentration is one of the key-challenges that requires further efforts, in order to obtain comparable results by using different techniques and assure reproducibility. In this study, the performance of measuring the concentration of particles in the size range of 50-300 nm with complementary techniques is thoroughly investigated in a step-by step approach of incremental complexity. The six applied techniques include multi-angle dynamic light scattering (MADLS), asymmetric flow field flow fractionation coupled with multi-angle light scattering (AF4-MALS), centrifugal liquid sedimentation (CLS), nanoparticle tracking analysis (NTA), tunable resistive pulse sensing (TRPS), and high-sensitivity nano flow cytometry (nFCM). To achieve comparability, monomodal samples and complex polystyrene mixtures were used as particles of metrological interest, in order to check the suitability of each technique in the size and concentration range of interest, and to develop reliable post-processing data protocols for the analysis. Subsequent complexity was introduced by testing liposomes as validation of the developed approaches with a known sample of physicochemical properties closer to EVs. Finally, the vesicles in EV containing plasma samples were analysed with all the tested techniques. The results presented here aim to shed some light into the requirements for the complex characterization of biological samples, as this is a critical need for quality assurance by the EV and regulatory community. Such efforts go with the view to contribute to both, set-up reproducible and reliable characterization protocols, and comply with the Minimal Information for Studies of Extracellular Vesicles (MISEV) requirements.

Keywords: extracellular vesicles; liposomes; multimodal samples; nanomedicine; orthogonal techniques; particle concentration; particle size distribution; polystyrene.

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Conflict of interest statement

R.V. is a contractor at IZON Science, J.M. and M.M. are employed by IZON Science and their contributions to this paper were made as part of their contract/employment. A.L., B.P., D.A. are employees of NanoFCM and their contributions to this paper were made as part of their employment.

Figures

**FIGURE 1**
NTA, TRPS, nFCM, CLS, AF4‐MALS and MADLS measurements of monomodal CPN100, CPN150, CPN200 and CPN240. The nominal standard deviation of the NIST‐traceable CPN150 standards as given by the particle provider are indicated for all six techniques. NTA, TRPS, nFCM and MADLS measurements were averaged over 3 runs and CLS over 2. AF4‐MALS was only performed once. AF4‐MALS measurement of sample H was scaled down by a factor of 5, to make it comparable with the other sample measurements

**FIGURE 2**
NTA, TRPS, CLS, nFCM and AF4‐MALS measurements of trimodal sample J (CPN60/CPN100/CPN150 at 1/1/1). NTA, TRPS and nFCM measurements were averaged over 3 runs, and CLS over two runs. AF4‐MALS was only performed once. The NTA inset shows the multi‐Gaussian fit of its PSD. The CLS inset shows the baseline‐correction of the mass‐weighted PSD, whilst the AF4‐MALS inset shows the respective number density‐based fractogram and sample specific particle peak positions

**FIGURE 3**
NTA, TRPS, CLS, nFCM, AF4‐MALS and MADLS measurements of quadrimodal sample C (CPN100/CPN150/CPN200/CPN240 at 25/25/25/25). NTA, TRPS, nFCM and MADLS measurements were averaged over 3 runs and CLS over 2. AF4‐MALS was only performed once. The NTA inset shows the multi‐Gaussian fit of its PSD. The CLS inset shows the base‐line correction of the respective mass‐weighted PSD, whilst the AF4‐MALS inset shows the number density‐based fractogram and sample specific particle peak positions. The MADLS inset shows the intensity‐weighted PSD

**FIGURE 4**
NTA, TRPS, nFCM, CLS, AF4‐MALS and MADLS measurements of quadrimodal sample I (CPN100/CPN150/CPN200/CPN240 at 10/50/30/10). NTA, TRPS, nFCM and MALDS measurements were averaged over 3 runs and CLS over 2. AF4‐MALS was only performed once. The NTA inset shows the multi‐Gaussian fit of its PSD. The CLS inset shows the base‐line correction of the respective mass‐weighted PSD, whilst the AF4‐MALS inset shows the number density‐based fractogram and sample specific particle peak positions. The MADLS inset shows the intensity‐weighted PSD

**FIGURE 5**
Number‐weighted PSDs of PEGylated liposome sample, as measured with NTA, TRPS, nFCM and AF4‐MALS. All results are averaged over 3 repeat runs each

**FIGURE 6**
Number‐weighted PSDs of EV containing plasma sample, as measured with NTA, TRPS, nFCM and CLS. NTA and TRPS results are averaged over 3 repeat runs each. For CLS the two repeat runs are shown in order to demonstrate the discrepancy between repeat runs. Respective mass‐weighted PSDs are shown In the CLS inset. nFCM was only performed once

See this image and copyright information in PMC

References

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Measuring particle concentration of multimodal synthetic reference materials and extracellular vesicles with orthogonal techniques: Who is up to the challenge?

Affiliations

Measuring particle concentration of multimodal synthetic reference materials and extracellular vesicles with orthogonal techniques: Who is up to the challenge?

Authors

Affiliations

Abstract

Conflict of interest statement

Figures

References

Publication types

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Substances

LinkOut - more resources

Full Text Sources

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