AI Article Synopsis
- * A study highlights the use of organic electrochemical transistors (OECTs) to monitor how nanoparticles affect cells in real-time, showing their potential for assessing toxicity.
- * OECTs can evaluate how different coatings on nanoparticles impact both barrier and non-barrier tissues, providing valuable insights into how these materials interact with living cells over time.
Article Abstract
Nanomaterials are being widely used in medical applications and consumer products such as cosmetics, fabrics, and food packaging, although their impact on health and the environment is yet to be understood. Strategies enabling reliable and reproducible safety assessment of nanomaterials are needed because predicting their toxic effects is challenging as there is no simple correlation between their properties and the interaction with living systems. Here, the real-time monitoring of toxic effects induced by nanoparticles on cells using organic electrochemical transistors (OECTs) is reported. Noteworthy, OECTs are able to assess the coating-dependent toxicity of nanoparticles on both barrier and non-barrier tissue cells and, moreover, to monitor the cell health status as a function of exposure time, allowing useful insight on the interaction processes between nanomaterials and cells. These results demonstrate that OECTs are effective devices for real-time cell monitoring and in vitro assessment of nanomaterial toxicity.
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| http://dx.doi.org/10.1002/adbi.201900204 | DOI Listing |
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