AI Article Synopsis
- - The study presents a novel method for silver (Ag) deposition using a redox enzyme and a quinone substrate that eliminates the need for a washing step, which is usually necessary to avoid oxidation during electrochemical processes.
- - It was discovered that the quinone substrate is initially reduced by the enzyme and can then be restored while facilitating the deposition of silver, without undergoing unwanted oxidation during subsequent electrochemical oxidation.
- - This improved Ag deposition method enables the detection of thyroid-stimulating hormone (TSH) in very low concentrations (down to about 100 fg/mL) in artificial serum, showcasing its potential for sensitive clinical diagnostics.
Article Abstract
Enzyme-induced seedless Ag deposition is useful for selective Ag deposition and subsequent electrochemical Ag oxidation; however, a washing step is required after the deposition and before the electrochemical oxidation as the enzyme substrate can be oxidized during the electrochemical oxidation. Here, we report a fast Ag deposition method using a redox enzyme and quinone substrate that does not require a washing step. We found that the quinone substrate is reduced by a redox enzyme label, which is later oxidized to its original form via the reduction of Ag to Ag. Moreover, the quinone substrate is not electrochemically oxidized during the electrochemical Ag oxidation. We selected one diaphorase and 1,4-naphthoquinone from among seven redox enzymes (four diaphorases and three glucose-oxidizing enzymes) and six quinones, respectively. We applied this Ag deposition method for the detection of thyroid-stimulating hormone (TSH) over a dynamic range from 100 fg/mL to 100 ng/mL and found that TSH could be detected at concentrations as low as approximately 100 fg/mL in artificial serum. Therefore, the Ag deposition strategy developed in this study exhibits promising potential for ultrasensitive clinical applications.
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| http://dx.doi.org/10.1016/j.bios.2021.113773 | DOI Listing |
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