Administering Pesticide Assays in In Vivo-Implanted Biosensors
Suw Young Ly A D , Young Sam Jung B , Chang Hyun Lee C and Bang Won Lee AA Biosensor Research Institute in Seoul National University of Technology, 172 Gongreung 2 dong Nowon-gu, Seoul 139-743, South Korea.
B Department of Chemistry, Korea University, Anam 5-2, Sungbook-gu, Seoul 136-701, South Korea.
C Pyongtaek University, Division of General Education, 111 Yongyi-dong, Pyeongtaek-si, Gyeonggi-do 450-701, South Korea.
D Corresponding author. Email: suwyoung@snut.ac.kr
Australian Journal of Chemistry 61(10) 826-832 https://doi.org/10.1071/CH08028
Submitted: 24 January 2008 Accepted: 6 August 2008 Published: 6 October 2008
Abstract
An analytical pesticide assay of O-ethyl-O-4-(nitrophenyl)phenyl phosphonothioate (EPN) was carried out using the following: a carbon nanotube paste electrode, a mercury-immobilized carbon nanotube paste electrode, a glassy carbon electrode, a metal–gold electrode, and a DNA-immobilized carbon nanotube paste electrode (DPE), which is two-fold more sensitive than other sensors. The DPE was optimized using cyclic and square wave stripping voltammetry. Linear working ranges approached 5–55 mg L–1 EPN and the nano-range of 10–210 ng L–1 in a 0.1 mol L–1 NH4H2PO4 electrolyte solution, with a speedy analytical time of 30-s stripping. The detection limit was 2.57 ng L–1 (7.94 × 10–12 mol L–1), and the precision was 0.102% relative standard deviation (n = 15) at the 10.0 mg L–1 EPN spike. This indicates that the method is more sensitive than common voltammetric methods. This method was applied to fruit samples using patch- and needle-type electrodes, specifically on the skin tissues of an orange and an apple. Moreover, the implanted electrode was interfaced with a fish brain cell at the electrochemical workstation. Results showed that the aforementioned method can be used to conduct a pesticide assay in neuro-treated and non-treated cell systems.
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