2D magnetic nanoporous carbon with bridge-type aptamer assembly for pesticide detection based on a regenerative field-effect transistor biosensor

Abstract

Field-effect transistor (FET)-based biosensors have garnered attention due to their sensitivity to surface charge changes and advantages in real-time detection. However, these biosensors often suffer from several disadvantages such as their limited sensitivity and a high cost. Here, we reported an ultra-sensitive and reusable nanoporous-based FET biosensor hybridized with bridge-type aptamers. The sensor consisted of a two-dimensional magnetic iron-cobalt nanoparticle-embedded nanoporous carbon (Fe-Co/NPC) functionalized with bridge-type aptamers. The edges of the nanopores exhibited high surface energy and chemical activity, enabling effective interactions with the aptamers. Moreover, the nanoporous structures provided additional space, which could improve molecular recognition sites and sensor sensitivity. Our sensor could be used to detect organophosphorus pesticides (OPs) in vegetables down to 100 fM in real time and identify OPs from other pesticides. Furthermore, the magnetic properties of Fe-Co/NPC allowed us to reuse a single sensor chip up to 8 times, which significantly reduced the production cost of our sensors. In this respect, our Fe-Co/NPC-FET sensor could be a powerful tool for practical applications such as food safety detection.