Abstract
We have developed a lab-on-a-chip system for continuous and non-invasive monitoring of microfluidic cell
cultures using integrated high-frequency contactless impedance spectroscopy. Electrically insulated
microfabricated interdigitated electrode structures were embedded into four individually addressable
microchambers to reliably and reproducibly detect cell-substrate interactions, cell viability and metabolic
activity. While silicon nitride passivated sensor substrates provided a homogeneous cell culture surface
that minimized cell orientation along interdigitated electrode structures, the application of highfrequency
AC fields reduced the impact of the 300 nm thick passivation layer on sensor sensitivity. The
additional implementation of multivariate data analysis methods such as partial least square (PLS) for
high-frequency impedance spectra provided unambiguous information on intracellular pathway
activation, up and down-regulation of protein synthesis as well as global cellular stress responses. A
comparative cell analysis using connective tissue fibroblasts showed that high-frequency contactless
impedance spectroscopy and time-resolved quantification of IL-6 secretion using ELISA provided similar
results following stimulation with circulating pro-inflammatory cytokines IL-1b and TNFa. The
combination of microfluidics with contactless impedance sensing and time-resolved quantification of
stress factor release will provide biologist with a new tool to (a) establish a variety of uniform cell culture
surfaces that feature complex biochemistries, micro- and nanopatterns; and (b) to simultaneously
characterize cell responses under physiologically relevant conditions using a complementary noninvasive
cell analysis method.
Original language | English |
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Pages (from-to) | 5271-5282 |
Number of pages | 12 |
Journal | Analyst |
Volume | 139 |
Issue number | 20 |
DOIs | |
Publication status | Published - 2014 |
Research Field
- Biosensor Technologies