SYNTHESIS OF METAL OXIDE NANOPARTICLE (FE3O4) - GRAPHENE OXIDE AS MATERIAL OF ACTIVE ELECTROCHEMICAL SENSORS FOR DOPAMINE DETECTION
Dopamine concentration abnormalities in the body, can cause various kinds of disorders and diseases such as Parkinson's, Tourette's syndrome, impaired concentration or hyperactivity depression, anxiety disorders, insomnia, delusional, digestive problems, and various disorders in other p...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/50643 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Dopamine concentration abnormalities in the body, can cause various kinds of disorders and
diseases such as Parkinson's, Tourette's syndrome, impaired concentration or hyperactivity
depression, anxiety disorders, insomnia, delusional, digestive problems, and various disorders
in other physiological systems. Therefore detection of dopamine levels as a method of early
diagnosis on a micro-basis is very important. In this study graphene oxide (GO) was deposited
with Fe3O4 as a supporting material to improve the electrochemical performance of the sensor
in the detection of dopamine. The performance of sensors which surface has been modified by
FeGO is carried out by the Cyclic Voltammetry (CV) and Differential Pulse Voltammetry
(DPV) methods. The results of testing with CV on the solution [Fe(CN)6] showed that a
modification with GO gave the maximum effective surface area value of 0.0127 cm2 which
proves that GO can increase the effective area and conductivity of the sensor. Then the
comparison of dopamine in different consentration between GCE without modification with
modification indicate that the modified GCE shows the ability to detect dopamine with the
highest peak current value (Ip) owned by FeGO of 113.09 ?A / Cm2
for anodic reaction and
105.12 ?A / Cm2
for cathodic reactions. A linear relationship is seen in the CV results between
peak oxidation current densities and reductions in increasing dopamine concentrations. DPV
testing shows that FeGO has a linear range at a concentration of 1 - 20 ?M with a sensitivity
of 5 ?A ?M-1
cm-2
, a detection limit of 0.029 ?M, a quantification limit of 0.097 ?M, with a
relative measurement error of 6.052%. FeGO shows good selectivity where the peak current
is separated by 0.245 V with ascorbic acid which is the closest interference compound. FeGO
testing after being stored for a certain period of time shows a decrease in the peak value of the
current observed with a linear relationship equation.
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