Abstract

Polyelectrolyte multilayer (PEM) microchambers can provide a versatile cargo delivery system enabling rapid, site-specific drug release on demand. However, experimental evidence for their potential benefits in live human cells is scarce. Equally, practical applications often require substance delivery that is geometrically constrained and highly localized. Here, we establish human-cell biocompatibility and on-demand cargo release properties of the PEM or polylactic acid (PLA)-based microchamber arrays fabricated on a patterned film base. We grow human N2A cells (a neuroblastoma cell line widely used for studies of neurotoxicity) on the surface of the patterned microchamber arrays loaded with either a fluorescent indicator or the ubiquitous excitatory neurotransmitter glutamate. The differentiating human N2A cells show no detrimental effects on viability when growing on either PEM@PLA or PLA-based arrays for up to ten days in vitro. Firstly, we use two-photon (2P) excitation with femtosecond laser pulses to open individual microchambers in a controlled way while monitoring release and diffusion of the fluorescent cargo (rhodamine or FITC fluorescent dye). Secondly, we document the increases in intracellular Ca2+ in local N2A cells in response to the laser-triggered glutamate release from individual microchambers. The functional cell response is site-specific and reproducible on demand and could be replicated by applying glutamate to the cells using a pressurised micropipette. Time-resolved fluorescence imaging confirms the physiological range of the glutamate-evoked intracellular Ca2+ dynamics in the differentiating N2A cells. Our data indicate that the nano-engineering design of the fabricated PEM or PLA-based patterned microchamber arrays could provide a biologically safe and efficient tool for targeted, geometrically constrained drug delivery.

Highlights

  • Over the past decade, various nano-engineering designs have been explored for their capability for micro-packaging, targeted delivery, and controlled release of bioactive compounds

  • We found that the two protocols for microchamber formation, polyelectrolyte-based multilayer (PEM)@polylactic acid (PLA) and PLA, work well for cargo loading and for laser opening

  • We placed the stamped arrays of microchambers (Fig. 1) filled with either glutamate or fluorescent indicator, or left empty, in the cell culture medium, and subsequently plated the N2A cells to grow on the array surface, or entirely outside the arrays, during 7–10 days (Methods)

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Summary

Introduction

Various nano-engineering designs have been explored for their capability for micro-packaging, targeted delivery, and controlled release of bioactive compounds. Among such systems, the most prominent were nanoparticles and microcapsules,[1,2,3] hydrogels,[4] and nanocomposite films fabricated with the polyelectrolyte-based multilayer (PEM) assembly using the layer-by-layer (LbL) technique.[5,6] Nanostructured PEMs combine multiple functionalities to provide control over cargo release: their shell permeability. Recent advances in PEM films fabricated on patterned surfaces appear to overcome the issue of capsule scattering, by enabling an array of micro-wells or microchambers of predetermined size and spatial distribution.[5,6,14] Composed as LbL-assembled PEM films, this novel strategy of housing bio-. It would seem important to understand whether and how this delivery system can be used in the conditions of live cells and their networks

Methods
Results
Conclusion

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