Electrochemical Nano‐Roughening of Gold Microstructured Electrodes for Enhanced Sensing in Biofluids

• Published in: Angewandte Chemie Vol. 135; no. 19
• Main Authors: González‐Martínez, Eduardo, Saem, Sokunthearath (Kevin), Beganovic, Nadine E., Moran‐Mirabal, Jose M.
• Format: Journal Article
• Language: English
• Published: Weinheim Wiley Subscription Services, Inc 02.05.2023
• Subjects: Antifouling; Blood plasma; Bovine serum albumin; Chemistry; Chemoreception; Copper; Drinking water; Electrochemical analysis; Electrochemistry; Electrodes; Electron microscopy; Enzyme-Free Glucose Sensing; Glucose; Gold; Heavy Metal Sensing; High Electroactive Surface Area; Nanoroughening; Roughening; Sensitivity; Serum albumin; Surface roughness
• ISSN: 0044-8249; 1521-3757
• DOI: 10.1002/ange.202218080

A key challenge for sensor miniaturization is to create electrodes with smaller footprints, while maintaining or increasing sensitivity. In this work, the electroactive surface of gold electrodes was enhanced 30‐fold by wrinkling followed by chronoamperometric (CA) pulsing. Electron microscopy showed increased surface roughness in response to an increased number of CA pulses. The nanoroughened electrodes also showed excellent fouling resistance when submerged in solutions containing bovine serum albumin. The nanoroughened electrodes were used for electrochemical detection of Cu2+ in tap water and of glucose in human blood plasma. In the latter case, the nanoroughened electrodes allowed highly sensitive enzyme‐free sensing of glucose, with responses comparable to those of two commercial enzyme‐based sensors. We anticipate that this methodology to fabricate nanostructured electrodes can accelerate the development of simple, cost‐effective, and high sensitivity electrochemical platforms. Hierarchically structured high electroactive surface area gold electrodes were fabricated using a simple and inexpensive thermal wrinkling approach and a chronoamperometric pulsing nanoroughening method. The nanoroughened electrodes showed antifouling capabilities and could be used for the sensitive electrochemical detection of copper in tap‐water and for the enzyme‐free detection of glucose in human blood serum samples.