Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM

Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM

Introduction: Extracellular vesicles (EVs) are shed from cells and carry markers of the parent cells. Vesicles derived from cancer cells reach the bloodstream and locally influence important physiological processes. It has been previously shown that procoagulant vesicles are circulating in patients&...

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Main Authors: Julie Hardij, Francesca Cecchet, Alexandre Berquand, Damien Gheldof, Christian Chatelain, François Mullier, Bernard Chatelain, Jean-Michel Dogné
Format: Article
Language:English
Published: Taylor & Francis Group 2013-08-01
Series:Journal of Extracellular Vesicles
Subjects:
extracellular vesicles
tissue factor
atomic force microscopy
coagulation
biomarker
Online Access:http://www.journalofextracellularvesicles.net/index.php/jev/article/download/21045/29818
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spelling doaj-2b38d0ff1f2443de82937e68c3a145602020-11-24T23:57:05ZengTaylor & Francis GroupJournal of Extracellular Vesicles2001-30782013-08-01201910.3402/jev.v2i0.21045Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFMJulie HardijFrancesca CecchetAlexandre BerquandDamien GheldofChristian ChatelainFrançois MullierBernard ChatelainJean-Michel DognéIntroduction: Extracellular vesicles (EVs) are shed from cells and carry markers of the parent cells. Vesicles derived from cancer cells reach the bloodstream and locally influence important physiological processes. It has been previously shown that procoagulant vesicles are circulating in patients’ fluids. These EVs are therefore considered as promising biomarkers for the thrombotic risk. Because of their small size, classical methods such as flow cytometry suffer from limitation for their characterisation. Atomic force microscopy (AFM) has been proposed as a promising complementary method for the characterisation of EVs. Objectives: The objectives of this study are: (a) to develop and validate AFM with specific antibodies (anti-TF) and (b) to compare air and liquid modes for EVs’ size and number determination as potential biomarkers of the prothrombotic risk. Methods: AFM multimode nanoscope III was used for air tapping mode (TM). AFM catalyst was used for liquid Peak Force Tapping (PFT) mode. Vesicles are generated according to Davila et al.'s protocol. Substrates are coated with various concentrations of antibodies, thanks to ethanolamine and glutaraldehyde. Results: Vesicles were immobilised on antibody-coated surfaces to select tissue factor (TF)-positive vesicles. The size range of vesicles observed in liquid PFT mode is 6–10 times higher than in air mode. This corresponds to the data found in the literature. Conclusion: We recommend liquid PFT mode to analyse vesicles on 5 µg/ml antibody-coated substrates.www.journalofextracellularvesicles.net/index.php/jev/article/download/21045/29818extracellular vesiclestissue factoratomic force microscopycoagulationbiomarker
collection DOAJ
language English
format Article
sources DOAJ
author Julie Hardij
Francesca Cecchet
Alexandre Berquand
Damien Gheldof
Christian Chatelain
François Mullier
Bernard Chatelain
Jean-Michel Dogné
spellingShingle Julie Hardij
Francesca Cecchet
Alexandre Berquand
Damien Gheldof
Christian Chatelain
François Mullier
Bernard Chatelain
Jean-Michel Dogné
Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM
Journal of Extracellular Vesicles
extracellular vesicles
tissue factor
atomic force microscopy
coagulation
biomarker
author_facet Julie Hardij
Francesca Cecchet
Alexandre Berquand
Damien Gheldof
Christian Chatelain
François Mullier
Bernard Chatelain
Jean-Michel Dogné
author_sort Julie Hardij
title Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM
title_short Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM
title_full Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM
title_fullStr Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM
title_full_unstemmed Characterisation of tissue factor-bearing extracellular vesicles with AFM: comparison of air-tapping-mode AFM and liquid Peak Force AFM
title_sort characterisation of tissue factor-bearing extracellular vesicles with afm: comparison of air-tapping-mode afm and liquid peak force afm
publisher Taylor & Francis Group
series Journal of Extracellular Vesicles
issn 2001-3078
publishDate 2013-08-01
description Introduction: Extracellular vesicles (EVs) are shed from cells and carry markers of the parent cells. Vesicles derived from cancer cells reach the bloodstream and locally influence important physiological processes. It has been previously shown that procoagulant vesicles are circulating in patients’ fluids. These EVs are therefore considered as promising biomarkers for the thrombotic risk. Because of their small size, classical methods such as flow cytometry suffer from limitation for their characterisation. Atomic force microscopy (AFM) has been proposed as a promising complementary method for the characterisation of EVs. Objectives: The objectives of this study are: (a) to develop and validate AFM with specific antibodies (anti-TF) and (b) to compare air and liquid modes for EVs’ size and number determination as potential biomarkers of the prothrombotic risk. Methods: AFM multimode nanoscope III was used for air tapping mode (TM). AFM catalyst was used for liquid Peak Force Tapping (PFT) mode. Vesicles are generated according to Davila et al.'s protocol. Substrates are coated with various concentrations of antibodies, thanks to ethanolamine and glutaraldehyde. Results: Vesicles were immobilised on antibody-coated surfaces to select tissue factor (TF)-positive vesicles. The size range of vesicles observed in liquid PFT mode is 6–10 times higher than in air mode. This corresponds to the data found in the literature. Conclusion: We recommend liquid PFT mode to analyse vesicles on 5 µg/ml antibody-coated substrates.
topic extracellular vesicles
tissue factor
atomic force microscopy
coagulation
biomarker
url http://www.journalofextracellularvesicles.net/index.php/jev/article/download/21045/29818
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