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Development of a Phosphate Biosensor for Soil and Ground Water [PO43-] Detection Serkan Akar Florida International University/Applied Research Center.

Published byEeva-Kaarina Melasniemi Modified over 5 years ago

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Presentation on theme: "Development of a Phosphate Biosensor for Soil and Ground Water [PO43-] Detection Serkan Akar Florida International University/Applied Research Center."— Presentation transcript:

1 Development of a Phosphate Biosensor for Soil and Ground Water [PO43-] Detection Serkan Akar Florida International University/Applied Research Center Dept. of Biomedical Engineering Master’s Student

2 Background The recent research shows that stored uranium in Hanford causes extensive contamination in the soil and ground water. Phosphate PO43- reacts with Uranium and reduces it from U6+ to U4+. (Stabilization of Uranium) The detection/quantification of [PO4] is essential.

3 Method Develop an enzymatic biosensor which will carry out the reaction and produce H2O2. The produced H2O2 is detected via electro-chemical methods. The concentration of [PO4] is then calculated from the calibration curve obtained as a result of addition of PO4 in the solution.

4 Reaction Pyr+PO4+O POX Acetyl P + H2O2 + CO2

5 Detection Mechanism The reaction produces H2O2 which can be electro-chemically detected. H2O H+ + 2e- + O2 The Sensing Response is obtained from oxidation current of above reaction

6 Experimental Setup

7 Experimental Setup

8 CV Background Buffer Solution

9 Amperometry Background
Current Time DCPA of The Buffer

10 Graphs of H2O2 PO43- Addition Points

11 Normalized Data

12 Conclusion Obtained data clearly indicates that PO4 can be detected and measured/quantified successfully by the designed system.

13 Acknowledgement Dr. Leonel Lagos (DOE Fellows Program Director)
Dr. Vekalet Tek ( ARC Mentor) Dr. Thomas G. Thundat (ORNL Mentor)

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