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In this chapter, we present techniques, based on molecular-scale nanofabrication and selective self-assembly, for the presentation of biomolecules of interest (ligands, receptors, etc.) on a surface with precise spatial control and arbitrary geometry at the single-molecule level. Metallic nanodot arrays are created on glass coverslips and are then used as anchors for the immobilization of biological ligands via thiol linking chemistry. The nanodot size is controlled by both lithography and metallization. The reagent concentration in self-assembly can be adjusted to ensure single-molecule occupancy for a given dot size. The surrounding glass is backfilled by a protein-repellent layer to prevent nonspecific adsorption. Moreover, bifunctional surfaces are created, whereby a second ligand is presented on the background, which is frequently a requirement for simulating complex cellular functions involving more than one key ligand. This platform serves as a novel and powerful tool for molecular and cellular biology, e.g., to study the fundamental mechanisms of receptor-mediated signaling.

Original publication

DOI

10.1007/978-1-4939-6881-7_18

Type

Chapter

Publication Date

2017

Volume

1584

Pages

307 - 331

Keywords

Bifunctional biomimetic surfaces, Fluorescence microscopy, Nanofabrication, Self-assembly, Single-molecule, Animals, Humans, Lymphocyte Activation, Microarray Analysis, Nanoparticles, Signal Transduction, T-Lymphocytes