Monitoring of Cell Layer Integrity with a Current‐Driven Organic Electrochemical Transistor

Lingstedt, Leona V.; Ghittorelli, Matteo; Brückner, Maximilian; Reinholz, Jonas; Crăciun, N. Irina; Torricelli, Fabrizio; Mailänder, Volker; Gkoupidenis, Paschalis; Blom, Paul W. M.

doi:10.1002/adhm.201900128

Cited by 22 publications

(38 citation statements)

References 26 publications

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“…Caco-2 Cell Exposure to PLL in Transwell Filter: Experiments were performed on day 14 after seeding, corresponding to a TER of ≈400 Ω cm 2 . [45,40] The TER was measured with a handheld Volt-Ohm meter EVOM2 from World Precision Instruments. Before adding polyl-lysine (PLL) in DI water (0,56 × 10 −6 m, M W = 30-70 kDa, Sigma Aldrich) apical to the cell layer, the same volume of electrolyte was removed before to keep the ionic concentration similar.…”

Section: Methodsmentioning

confidence: 99%

“…An investigation on irreversible barrier tissue disruption with hydrogen peroxide using a current‐driven OECT confirmed the improved ion sensitivity compared to transient response measurements. [ 40 ] Therefore, a current‐driven OECT is an attractive alternative to electrically monitor in real‐time the reversible opening and closing of TJs, which is of great importance for drug delivery.…”

Section: Introductionmentioning

confidence: 99%

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Monitoring Reversible Tight Junction Modulation with a Current‐Driven Organic Electrochemical Transistor

Lieberth

Brückner

Torricelli

et al. 2021

Adv Materials Technologies

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The barrier functionality of a cell layer regulates the passage of nutrients into the blood. Modulating the barrier functionality by external chemical agents like poly‐l‐lysine (PLL) is crucial for drug delivery. The ability of a cell layer to impede the passage of ions through it and therefore to act as a barrier, can be assessed electrically by measuring the resistance across the cell layer. Here, an organic electrochemical transistor (OECT) is used in a current‐driven configuration for the evaluation of reversible modulation of tight junctions in Caco‐2 cells over time. Exposure to low and medium concentrations of PLL initiates reversible modulation, whereas a too high concentration induces an irreversible barrier disruption due to nonfunctional tight junction proteins. The results demonstrate the suitability of OECTs to in situ monitor temporal barrier modulation and recovery, which can offer valuable information for drug delivery applications.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Monitoring Reversible Tight Junction Modulation with a Current‐Driven Organic Electrochemical Transistor

Lieberth

Brückner

Torricelli

et al. 2021

Adv Materials Technologies

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“…Developing high‐performance organic field effect transistors (OFETs) has been a bottleneck in exploiting the merits of organic semiconductors (OSCs) such as solution‐processability, mechanical flexibility, and bio‐compatibility, for realizing practical organic optoelectronic device applications. [ 1–14 ] One of the main challenges remaining for utilizing OFETs is a high contact resistance originating from an injection barrier at the OSC–metal interface. [ 1–14 ] An inefficient charge injection across such non‐ohmic contacts not only lowers the effective mobility of OFETs but limits the range of operation voltage due to a highly non‐linear (S‐shaped) output characteristic curve at low bias voltage, [ 15,16 ] which is not desirable for analog circuit applications.…”

Section: Introductionmentioning

confidence: 99%

Highly Stable Contact Doping in Organic Field Effect Transistors by Dopant‐Blockade Method

Kim

Broch

Lee

et al. 2020

Adv Funct Materials

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In organic device applications, a high contact resistance between metal electrodes and organic semiconductors prevents an efficient charge injection and extraction, which fundamentally limits the device performance. Recently, various contact doping methods have been reported as an effective way to resolve the contact resistance problem. However, the contact doping has not been explored extensively in organic field effect transistors (OFETs) due to dopant diffusion problem, which significantly degrades the device stability by damaging the ON/OFF switching performance. Here, the stability of a contact doping method is improved by incorporating "dopant-blockade molecules" in the poly(2,5-bis(3-hexadecylthiophen-2-yl)thieno[3,2-b]thiophene) (PBTTT) film in order to suppress the diffusion of the dopant molecules. By carefully selecting the dopant-blockade molecules for effectively blocking the dopant diffusion paths, the ON/OFF ratio of PBTTT OFETs can be maintained over 2 months. This work will maximize the potential of OFETs by employing the contact doping method as a promising route toward resolving the contact resistance problem.

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“…To improve the sensitivity, we recently proposed a current-driven OECT architecture, achieving selective K + sensitivity up to 414 10 −3 V dec −1 over an ion concentration range 10 −2 M − 1 M at a supply voltage equal to 0.8 V 26 . However, although sensitive this approach requires a read-out scheme not ideally suitable for real-time ion sensing 27 . Therefore, while OECTs are a promising technology for ion detection and real-time monitoring, current approaches still require additional electronic circuits for signal amplification because of the limited sensitivity.…”

Section: Introductionmentioning

confidence: 99%

Multiscale real time and high sensitivity ion detection with complementary organic electrochemical transistors amplifier

et al. 2020

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Ions are ubiquitous biological regulators playing a key role for vital processes in animals and plants. The combined detection of ion concentration and real-time monitoring of small variations with respect to the resting conditions is a multiscale functionality providing important information on health states. This multiscale functionality is still an open challenge for current ion sensing approaches. Here we show multiscale real-time and high-sensitivity ion detection with complementary organic electrochemical transistors amplifiers. The ion-sensing amplifier integrates in the same device both selective ion-to-electron transduction and local signal amplification demonstrating a sensitivity larger than 2300 mV V −1 dec −1 , which overcomes the fundamental limit. It provides both ion detection over a range of five orders of magnitude and real-time monitoring of variations two orders of magnitude lower than the detected concentration, viz. multiscale ion detection. The approach is generally applicable to several transistor technologies and opens opportunities for multifunctional enhanced bioelectronics.

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Monitoring of Cell Layer Integrity with a Current‐Driven Organic Electrochemical Transistor

Cited by 22 publications

References 26 publications

Monitoring Reversible Tight Junction Modulation with a Current‐Driven Organic Electrochemical Transistor

Monitoring Reversible Tight Junction Modulation with a Current‐Driven Organic Electrochemical Transistor

Highly Stable Contact Doping in Organic Field Effect Transistors by Dopant‐Blockade Method

Multiscale real time and high sensitivity ion detection with complementary organic electrochemical transistors amplifier

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