Fabrication of electrochemical biosensor on the basis of the label-free DNA and modified nanomaterial to detect Fig mosaic virus
Niloofar Rajabi 1 , Mohammadreza Safarnejad 2 , Farshad Rakhshandehroo 3 , Masoud Shamsbakhsh 4 , Hodjattallah Rabbani 5
1 - Department of Plant Protection, College of Agricultural Sciences and Food Industries, Science
and Research Branch, Islamic Azad University; 2 Department of Plant Viruses, Iranian Research
2 - Department of Plant Viruses, Iranian Research Institute of Plant Protection, Agricultural Research Education and Extension Organization, Tehran,Iran
3 - Plant Protection, College of Agricultural Researches and Food Technologies, Science and Research Branch, Islamic Azad University
4 - Department of Plant Pathology, Faculty of Agriculture, Tarbiat Modares University, Tehran,
Iran
5 - Experimental Oncology Head of Antigen and Antibody Engineering Department, Monoclonal Antibody Research Centre Avicenna Research Institute, Tehran, Iran
Keywords: Fig mosaic virus, DNA label free electrochemical biosensor, optimizing, calibration,
Abstract :
Today, electrochemical biosensors are highly regarded due to their high sensitivity and accuracy in tracking target nucleic acids. On the other hand, due to the economic importance of fig trees, rapid and accurate diagnosis of its diseases, including Fig Mosaic Disease (FMD), which is one of the most important and destructive viral diseases of fig trees plays an effective role in the management and control of this disease. In this study, a novel label free electrochemical DNA-based biosensor was optimized to qualitatively and quantitatively identify the presence of FMV in the infected samples. In this regard, in order to optimize and improve the performance of the designed biosensor, the concentration parameters of the DNA probe to form self-assembled monolayers and the time required to perform the hybridization process in the biological range with the greatest impact on the DNA biosensor were investigated. According to the data of the calibration curve, the first linear range at -3 μM to 3 μM was obtained with the equation of the line y= 4.81x+34.58 and the detection coefficient (R2= 0.9967). In this research, the omtimized biosensor to detect a stable, high selective, easy and fast FMV-DNA, promises a diagnostic method with high efficiency and accuracy.
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