Effect of various carbon electrodes on MIP-Based sensing proteins using poly(Scopoletin): A case study of ferritin
Künye
Yarman, A. (2024). Effect of various carbon electrodes on MIP-Based sensing proteins using poly(Scopoletin): A case study of ferritin. Biomimetics, 9 (426). 1-11.Özet
Sensitivity in the sub-nanomolar concentration region is required to determine important
protein biomarkers, e.g., ferritin. As a prerequisite for high sensitivity, in this paper, the affinity of the
functional monomer to the macromolecular target ferritin in solution was compared with the value
for the respective molecularly imprinted polymer (MIP)-based electrodes, and the influence of various
surface modifications of the electrode was investigated. The analytical performance of ferritin sensing
was investigated using three different carbon electrodes (screen-printed carbon electrodes, singlewalled-carbon-nanotube-modified screen-printed carbon electrodes, and glassy carbon electrodes)
covered with a scopoletin-based MIP layer. Regardless of the electrode type, the template molecule
ferritin was mixed with the functional monomer scopoletin, and electropolymerization was conducted
using multistep amperometry. All stages of MIP preparation were followed by evaluating the
diffusional permeability of the redox marker ferricyanide/ferrocyanide through the polymer layer by
differential pulse voltammetry. The best results were obtained with glassy carbon electrodes. The
MIP sensor responded up to 0.5 µM linearly with a Kd of 0.30 µM. Similar results were also obtained
in solution upon the interaction of scopoletin and ferritin using fluorescence spectroscopy, resulting
in the quenching of the scopoletin signal, with a calculated Kd of 0.81 µM. Moreover, the binding of
1 µM ferritin led to 49.6% suppression, whereas human serum albumin caused 8.6% suppression.