RESUMO
Detection of DNA molecules and possible chemotherapy-induced changes in its structure has been the goal of researchers using rapid, sensitive and inexpensive approaches. Therefore, the aim of this study was to fabricate a new electrochemical DNA biosensor using pencil graphite electrodes modified with polypyrrole/Ce doped hexagonal nickel oxide nanodisks or PP/Ce-doped H-NiO-ND composites for determination of Abemaciclib (AMC) and ds-DNA molecules. The DNA biosensor was prepared by immobilizing ds-DNA on the surface of PP/Ce-doped H-NiO-ND/PGE. Differential pulse voltammetry (DPV) was used to electrochemically detect AMC. The results elucidate the extremely high sensitivity of the ds-DNA/PP/Ce-doped H-NiO-ND/PGE biosensor to AMC, with a narrow detection limit of 2.7 nM and a lengthy linear range of 0.01-600.0 µM. The admirable performance of as-fabricated biosensor could be related to the active reaction sites and the unique electrochemical response related to the nanocomposites by enhancing ds-DNA stabilization and accelerating electron transfer on the surface of electrode.
RESUMO
In this project, we have investigated the possibility of mimicking the natural photosynthesis, as well as sensing and adsorption application of aluminum decorated graphitic C3N4 (Al-g-C3N4) QDs (toward some air pollutants containing CO, CO2, and SO2). The results of the potential energy surface (PES) studies show that in all three adsorption processes, the energy changes are negative (-10.70 kcal mol-1, -16.81 kcal mol-1, and -79.97 kcal mol-1 for CO, CO2, and SO2 gasses, respectively). Thus, all of the adsorption processes (mainly SO2) are spontaneous. Moreover, the frontier molecular orbital (FMO) investigations indicate that the Al-g-C3N4 QD could be used as a suitable semiconductor sensor for detection of CO, and CO2 (as carbon oxides) in one hand, and SO2 gaseous species on the other hand. Finally, the results reveal that those QDs could be applied for artificial photosynthesis (in presence of CO2; Δµh-e = 1.43 V), and for water splitting process for the H2 generation (Δµh-e = 1.23 V) as a clean fuel for near future.