Your search keyword '"Thibault Tabarin"' showing total 2 results

1. Can single molecule localization microscopy be used to map closely spaced RGD nanodomains?

Author

Mahdie Mollazade, Thibault Tabarin, Philip R Nicovich, Alexander Soeriyadi, Daniel J Nieves, J Justin Gooding, and Katharina Gaus

Subjects

Medicine, Science

Abstract

Cells sense and respond to nanoscale variations in the distribution of ligands to adhesion receptors. This makes single molecule localization microscopy (SMLM) an attractive tool to map the distribution of ligands on nanopatterned surfaces. We explore the use of SMLM spatial cluster analysis to detect nanodomains of the cell adhesion-stimulating tripeptide arginine-glycine-aspartic acid (RGD). These domains were formed by the phase separation of block copolymers with controllable spacing on the scale of tens of nanometers. We first determined the topology of the block copolymer with atomic force microscopy (AFM) and then imaged the localization of individual RGD peptides with direct stochastic optical reconstruction microscopy (dSTORM). To compare the data, we analyzed the dSTORM data with DBSCAN (density-based spatial clustering application with noise). The ligand distribution and polymer topology are not necessary identical since peptides may attach to the polymer outside the nanodomains and/or coupling and detection of peptides within the nanodomains is incomplete. We therefore performed simulations to explore the extent to which nanodomains could be mapped with dSTORM. We found that successful detection of nanodomains by dSTORM was influenced by the inter-domain spacing and the localization precision of individual fluorophores, and less by non-specific absorption of ligands to the substratum. For example, under our imaging conditions, DBSCAN identification of nanodomains spaced further than 50 nm apart was largely independent of background localisations, while nanodomains spaced closer than 50 nm required a localization precision of ~11 nm to correctly estimate the modal nearest neighbor distance (NDD) between nanodomains. We therefore conclude that SMLM is a promising technique to directly map the distribution and nanoscale organization of ligands and would benefit from an improved localization precision.

Published

2017

2. Can single molecule localization microscopy be used to map closely spaced RGD nanodomains?

Author

Alexander H. Soeriyadi, Philip R. Nicovich, Thibault Tabarin, Mahdie Mollazade, Katharina Gaus, J. Justin Gooding, and Daniel J. Nieves

Subjects

0301 basic medicine, DBSCAN, Single molecule localization, Materials science, Polymers, Materials by Structure, Imaging Techniques, Materials Science, lcsh:Medicine, Geometry, Research and Analysis Methods, Spectrum analysis techniques, Microscopy, Atomic Force, k-nearest neighbors algorithm, 03 medical and health sciences, Fluorescence Microscopy, NMR spectroscopy, Adhesives, Fluorescence Imaging, Microscopy, Cell Adhesion, Cluster Analysis, lcsh:Science, Nanoscopic scale, Materials by Attribute, Topology (chemistry), chemistry.chemical_classification, Multidisciplinary, Scanning Probe Microscopy, Simulation and Modeling, lcsh:R, Light Microscopy, Polymer, Polymer Chemistry, Single Molecule Imaging, Atomic Force Microscopy, Coupling (electronics), Chemistry, 030104 developmental biology, Macromolecules, Radii, chemistry, Chemical physics, Physical Sciences, lcsh:Q, Oligopeptides, Mathematics, Research Article

Abstract

Cells sense and respond to nanoscale variations in the distribution of ligands to adhesion receptors. This makes single molecule localization microscopy (SMLM) an attractive tool to map the distribution of ligands on nanopatterned surfaces. We explore the use of SMLM spatial cluster analysis to detect nanodomains of the cell adhesion-stimulating tripeptide arginine-glycine-aspartic acid (RGD). These domains were formed by the phase separation of block copolymers with controllable spacing on the scale of tens of nanometers. We first determined the topology of the block copolymer with atomic force microscopy (AFM) and then imaged the localization of individual RGD peptides with direct stochastic optical reconstruction microscopy (dSTORM). To compare the data, we analyzed the dSTORM data with DBSCAN (density-based spatial clustering application with noise). The ligand distribution and polymer topology are not necessary identical since peptides may attach to the polymer outside the nanodomains and/or coupling and detection of peptides within the nanodomains is incomplete. We therefore performed simulations to explore the extent to which nanodomains could be mapped with dSTORM. We found that successful detection of nanodomains by dSTORM was influenced by the inter-domain spacing and the localization precision of individual fluorophores, and less by non-specific absorption of ligands to the substratum. For example, under our imaging conditions, DBSCAN identification of nanodomains spaced further than 50 nm apart was largely independent of background localisations, while nanodomains spaced closer than 50 nm required a localization precision of ~11 nm to correctly estimate the modal nearest neighbor distance (NDD) between nanodomains. We therefore conclude that SMLM is a promising technique to directly map the distribution and nanoscale organization of ligands and would benefit from an improved localization precision.

Published

2017