2018
DOI: 10.1016/j.snb.2017.09.104
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Miniaturized multiparametric flexible platform for the simultaneous monitoring of ionic: Application in real urine

Abstract: International audienceBiomonitoring is a research topic that has largely relied on cell culture systems. Recently, the development of “Organ-on-a-Chip” (OC) platforms and the need for a continuous monitoring of these systems has increased its interest. However, the biomonitorization in these systems is still at its infancy due to the difficulty to adapt the sensors to microfluidic OC systems. In this work we have fabricated a modular, versatile, scalable, multi-analyte sensing platform, which integrates dissol… Show more

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Cited by 11 publications
(9 citation statements)
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“…24 However, in the last few years, various strategies have been proposed for real-time monitoring without compromising the operation of the OOC. Some works have focussed on the monitoring of the physical parameters external to the cell culture area of the OOC, using modular sensing platforms 23,[25][26][27] in-line with the microfluidic system to measure the inlets and outlets without disturbing the cell culture area. Recently, Zhang et al 23 presented a fully integrated multi-sensing platform to achieve automated in-situ monitoring of biophysical (pH, oxygen, temperature) and biochemical parameters of a liver-and heart-on-a-chip model systems.…”
Section: 15mentioning
confidence: 99%
“…24 However, in the last few years, various strategies have been proposed for real-time monitoring without compromising the operation of the OOC. Some works have focussed on the monitoring of the physical parameters external to the cell culture area of the OOC, using modular sensing platforms 23,[25][26][27] in-line with the microfluidic system to measure the inlets and outlets without disturbing the cell culture area. Recently, Zhang et al 23 presented a fully integrated multi-sensing platform to achieve automated in-situ monitoring of biophysical (pH, oxygen, temperature) and biochemical parameters of a liver-and heart-on-a-chip model systems.…”
Section: 15mentioning
confidence: 99%
“…To achieve good accuracy, it was essential to choose an appropriate anionic site, as it affected selectivity as well as sensitivity [32,40,41]. We selected two different salts, namely, NaTFPB and KTClPB, widely used in recent works [42][43][44][45][46]. Considering that the extensive conditioning protocol is often disregarded in flexible film electrodes and wearable platforms, we provide the experiment results on using both salts after the same period of conditioning.…”
Section: Effect Of Membrane Ingredientmentioning
confidence: 99%
“…Discrete sensing channels enabled the flexibility to replenish and replace the beads as desired prior to saturation. In addition, the group was able to demonstrate a multiplexing capability with both TGF-β1 and hepatocyte growth factor simultaneously using multiple sets of beads with different fluorescent markers.
Figure 9Examples of Instrumented Organ-on-chip Models of the Liver and Kidneys(A) Detection of TGF-β1 within a reconfigurable device to allow communication between injured hepatocytes and stellate cells via an aptamer-based electrochemical sensor.(B) On-chip detection of the hepatocyte growth factor and TGF-β1 secreted by primary hepatocytes via a fluorescent-bead-based optical sensor.(C) Transferrin and albumin production from human primary hepatocytes cultured in the bioreactor quantified via a bead-based electrochemical immunosensor.(D) Continuous real-time monitoring of hepatocyte metabolic function via a glucose/lactate enzyme-based electrochemical sensors and oxygen sensing phosphorescent microprobes.(E) Hepatocyte oxygen consumption rate assessed via inkjet-printed electrochemical dissolved oxygen sensors and commercial Clark-type sensors.(F) Permeability study of an MDCK-2 cell monolayer cultured on the membrane of a bilayer chip via TEER electrodes.(G) Assessment of renal epithelial cell growth and tight junction integrity quantified within a continuous fluid shear stress model via integrated TEER electrodes.(H) TEER measurements from a human renal epithelial cell monolayer cultured in a multi-use microfluidic device with integrated electrodes.(I) Electrical cell–substrate impedance monitoring of MDCK-2 cells to investigate wound healing and barrier integrity via an organic electrochemical transistor.(J) Electrochemical measurement of dissolved oxygen, Na + and K + ion concentration, and pH in kidney exactments via potentiometric and amperometric electrodes.Reprinted and adapted with permission from: A (Zhou et al., 2015); B (Son et al., 2017); C (Riahi et al., 2016); D (Bavli et al., 2016); E (Moya et al., 2018b); F (Douville et al., 2010); G (Ferrell et al., 2010); H (Brakeman et al., 2016); I (Curto et al., 2017); and J (Moya et al., 2018a). TGF-β1, transforming growth factor; MDCK-2, Madin Darby canine kidney-2; TEER, transepithelial electrical resistance.
…”
Section: Liver-on-chipmentioning
confidence: 99%
“…Reprinted and adapted with permission from: A (Zhou et al., 2015); B (Son et al., 2017); C (Riahi et al., 2016); D (Bavli et al., 2016); E (Moya et al., 2018b); F (Douville et al., 2010); G (Ferrell et al., 2010); H (Brakeman et al., 2016); I (Curto et al., 2017); and J (Moya et al., 2018a). TGF-β1, transforming growth factor; MDCK-2, Madin Darby canine kidney-2; TEER, transepithelial electrical resistance.…”
Section: Liver-on-chipmentioning
confidence: 99%
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