Issue 22, 2015

Self-assembled magnetic bead chains for sensitivity enhancement of microfluidic electrochemical biosensor platforms

Abstract

In this paper, we present a novel approach to enhance the sensitivity of microfluidic biosensor platforms with self-assembled magnetic bead chains. An adjustable, more than 5-fold sensitivity enhancement is achieved by introducing a magnetic field gradient along a microfluidic channel by means of a soft-magnetic lattice with a 350 μm spacing. The alternating magnetic field induces the self-assembly of the magnetic beads in chains or clusters and thus improves the perfusion and active contact between the analyte and the beads. The soft-magnetic lattices can be applied independent of the channel geometry or chip material to any microfluidic biosensing platform. At the same time, the bead-based approach achieves chip reusability and shortened measurement times. The bead chain properties and the maximum flow velocity for bead retention were validated by optical microscopy in a glass capillary. The magnetic actuation system was successfully validated with a biotin–streptavidin model assay on a low-cost electrochemical microfluidic chip, fabricated by dry-film photoresist technology (DFR). Labelling with glucose oxidase (GOx) permits rapid electrochemical detection of enzymatically produced H2O2.

Graphical abstract: Self-assembled magnetic bead chains for sensitivity enhancement of microfluidic electrochemical biosensor platforms

Supplementary files

Article information

Article type
Paper
Submitted
07 Jul 2015
Accepted
07 Sep 2015
First published
23 Sep 2015
This article is Open Access
Creative Commons BY license

Lab Chip, 2015,15, 4314-4321

Author version available

Self-assembled magnetic bead chains for sensitivity enhancement of microfluidic electrochemical biosensor platforms

L. Armbrecht, C. Dincer, A. Kling, J. Horak, J. Kieninger and G. Urban, Lab Chip, 2015, 15, 4314 DOI: 10.1039/C5LC00796H

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