Abstract

The active transport of cargo molecules within cells is essential for life. Developing synthetic strategies for cargo control in living or inanimate thermal systems could lead to powerful tools to manipulate chemical gradients at the microscale and thus drive processes out of equilibrium to realize work. Here we demonstrate a colloidal analog of the complex biological shuttles responsible for molecular trafficking in cells. Our colloidal shuttles consist of magneto-dielectric particles that are loaded with cargo particles or living cells through size-selective dielectrophoretic trapping using electrical fields. The loaded colloidal shuttle can be transported with magnetic field gradients before cargo is released at the target location by switching off the electrical field. Such spatiotemporal control over the distribution of chemically active cargo in a reversible fashion can be potentially exploited for fundamental biological research or for the development of novel technologies for advanced cell culturing, drug discovery and medical diagnosis.

Highlights

  • The active transport of cargo molecules within cells is essential for life

  • We propose a colloidal analog of the carrier system used for the transport of biomolecules in living systems, which we name “colloidal shuttles”

  • In contrast to the complex molecular machinery used in biology, our colloidal shuttles are driven and controlled purely by physical forces imposed by external magnetic and electrical fields

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Summary

Introduction

The active transport of cargo molecules within cells is essential for life. Developing synthetic strategies for cargo control in living or inanimate thermal systems could lead to powerful tools to manipulate chemical gradients at the microscale and drive processes out of equilibrium to realize work. Electrical fields are used to enable loading and release of cargo through modulation of dielectrophoretic forces in the vicinity of the colloidal shuttle.

Results
Conclusion

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