Cellular self-organization on micro-structured surfaces.

Micro-patterned surfaces are frequently used in high-throughput single-cell studies, as they allow one to image isolated cells in defined geometries. Commonly, cells are seeded in excess onto the entire chip, and non-adherent cells are removed from the unpatterned sectors by rinsing. Here, we report on the phenomenon of cellular self-organization, which allows for autonomous positioning of cells on micro-patterned surfaces over time. We prepared substrates with a regular lattice of protein-coated adhesion sites surrounded by PLL-g-PEG passivated areas, and studied the time course of cell ordering. After seeding, cells randomly migrate over the passivated surface until they find and permanently attach to adhesion sites. Efficient cellular self-organization was observed for three commonly used cell lines (HuH7, A549, and MDA-MB-436), with occupancy levels typically reaching 40-60% after 3-5 h. The time required for sorting was found to increase with increasing distance between adhesion sites, and is well described by the time-to-capture in a random-search model. Our approach thus paves the way for automated filling of cell arrays, enabling high-throughput single-cell analysis of cell samples without losses.

The defined presentation of nanoparticles to cells and their surface controlled uptake.

New approaches and standardized test procedures to study the impact of nanoparticles (NPs) on living cells are urgently needed for the evaluation of potential hazards relating human exposure to NPs. Here we study semiconductor quantum dots (QDs) preparation on solid surfaces and the subsequent internalization by cells seeded on top of the NP layer. Controlled densities of NPs are adsorbed to solid surfaces coated with extra-cellular macromolecules. The fraction of QDs taken up by the cells is assessed by automated fluorescence microscopy z-scans. We find that NPs aggregate during the uptake process, forming clusters inside cells that are able to enter the cell nucleus. NP uptake is dependent on surface functionalization and can be hindered by increasing the strength of the adhesion force between NPs and the surface. Studying time dependent uptake, we show that particles are able to exit cells.

Getting across the plasma membrane and beyond: intracellular uses of colloidal semiconductor nanocrystals.

Semiconductor nanocrystals (NCs) are increasingly being used as photoluminescen markers in biological imaging. Their brightness, large Stokes shift, and high photostability compared to organic fluorophores permit the exploration of biological phenomena at the single-molecule scale with superior temporal resolution and spatial precision. NCs have predominantly been used as extracellular markers for tagging and tracking membrane proteins. Successful internalization and intracellular labelling with NCs have been demonstrated for both fixed immunolabelled and live cells. However, the precise localization and subcellular compartment labelled are less clear. Generally, live cell studies are limited by the requirement of fairly invasive protocols for loading NCs and the relatively large size of NCs compared to the cellular machinery, along with the subsequent sequestration of NCs in endosomal/lysosomal compartments. For long-period observation the potential cytotoxicity of cytoplasmically loaded NCs must be evaluated. This review focuses on the challenges of intracellular uses of NCs.