Sensing of Barrier Tissue Disruption with an Organic Electrochemical Transistor

Scherrine A. Tria; Marc Ramuz; Leslie H. Jimison; Adel Hama; Roisin M. Owens

doi:10.3791/51102

JoVE Journal
Bioengineering

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JoVE Journal Bioengineering

Sensing of Barrier Tissue Disruption with an Organic Electrochemical Transistor

阻隔组织破坏与有机电化学晶体管传感

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11:17 min

February 10, 2014

DOI: 10.3791/51102-v

Scherrine A. Tria¹, Marc Ramuz¹, Leslie H. Jimison², Adel Hama¹, Roisin M. Owens¹

¹Department of Bioelectronics,Ecole Nationale Superieure des Mines, ²Research and Exploratory Development Division, Applied Physics Laboratory,Johns Hopkins University

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Overview

This study demonstrates the use of an organic electrochemical transistor (OECT) integrated with live cells to monitor ion flux across the gastrointestinal epithelial barrier. The OECT can detect changes in ion flow, indicating the health of barrier tissue.

Key Study Components

Area of Science

Neuroscience
Biophysics
Biomedical Engineering

Background

Barrier tissues are crucial for maintaining homeostasis.
Disruption of tight junctions can lead to various health issues.
Current methods for monitoring barrier integrity can be costly and time-consuming.
Organic electronic devices offer a potential low-cost alternative.

Purpose of Study

To develop a rapid diagnostic tool for monitoring barrier tissue health.
To assess the sensitivity of the OECT in detecting ion flow changes.
To evaluate the impact of toxic compounds on barrier integrity.

Methods Used

Fabrication of an organic electrochemical transistor.
Integration of a healthy barrier tissue layer onto the OECT device.
Measurement of source-drain current to monitor ion flow.
Application of a calcium chelator (EGTA) to disrupt tight junctions.

Main Results

The OECT successfully detected increased ion flux when barrier integrity was compromised.
Results indicate that the device can serve as a diagnostic tool for barrier tissue health.
Demonstrated advantages over traditional methods like impedance spectroscopy.
Potential for high-throughput screening applications.

Conclusions

The OECT is a promising tool for monitoring gastrointestinal barrier health.
Low-cost production makes it suitable for widespread use.
Further studies could enhance its application in toxicology and health diagnostics.

Frequently Asked Questions

What is the main advantage of using OECTs?

OECTs offer a low-cost and sensitive method for monitoring ion flow across barrier tissues.

How does the OECT detect changes in ion flow?

It measures changes in the source-drain current in response to ion flux variations.

What role does EGTA play in this study?

EGTA is used to disrupt tight junctions, allowing for the measurement of increased ion flux.

Can this method be used for high-throughput screening?

Yes, the low-cost nature of OECTs makes them suitable for high-throughput applications.

What types of tissues can be monitored with this technique?

The technique can be applied to various barrier tissues, including gastrointestinal epithelium.

Is this method more effective than traditional techniques?

The OECT method shows advantages in sensitivity and cost compared to traditional methods like impedance spectroscopy.

有机电化学晶体管集成了活细胞，并用于监视整个胃肠道上皮屏障离子流。在本研究中，增加了离子通量，涉及到中断紧密连接的，诱导的钙螯合剂EGTA（乙二醇 - 双（β-氨基乙基醚）-N，N，N'，N'-四乙酸的存在下酸），进行测定。

以下实验的总体目标是开发一种低成本、灵敏且快速的诊断方法，用于监测屏障组织的健康状况。这是通过制造有机电化学晶体管实现的，该晶体管可以通过测量晶体管源极漏极电流的变化来快速、灵敏地监测电解质中离子流的变化。作为第二步，将在过滤器上生长的健康屏障组织层整合到 OECT 设备上，以监测通过屏障组织层的离子流，如果细胞层健康，该层将被部分阻塞。

如果添加的有毒化合物破坏或破坏屏障组织层，则通过细胞层的离子流将不再受阻。获得的结果表明，OECT 可以成功检测模型化合物的毒性作用，这表明我们可以将晶体管的测量结果用作监测屏障组织健康状况的诊断方法。与阻抗谱等现有方法相比，该技术的主要优点是有机电子器件有可能以低成本生产，因此适合高通量筛选。

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