DEVELOPMENT OF MULTI-CHANNEL POTENTIOSTAT ELECTROCHEMICAL BIOSENSOR READER DEVICE
Along with the development of technology in the biomolecular field, there are many methods that aim to consider measurement variations including electrochemical biosensor measurements. The biosensor itself was chosen because it is considered to have several advantages that are able to detect vari...
Saved in:
| Main Author: | |
|---|---|
| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/65834 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Along with the development of technology in the biomolecular field, there are many
methods that aim to consider measurement variations including electrochemical
biosensor measurements. The biosensor itself was chosen because it is considered
to have several advantages that are able to detect various types of analytes, speed
up the measurement duration and are relatively inexpensive instruments. This is
what makes biosensors widely used, especially in the health sector. In general,
electrochemical-based analyzers are often chosen because of their simplicity,
durability, and advantages as well as their minimal maintenance. One tool that is
quite important in measuring electrochemical-based biosensors is a potentiostat
which is a tool that functions to assist biosensors. However, there are obstacles in
the procurement of potentiostat, causing the need for potentiostat fabrication that
focuses on low prices so that it can be reached by small and medium-sized units in
order to develop a multifunctional mini laboratory and its supporting activities.
Given the minimal space required the development of small and portable
instruments may be needed to reach more adopters of the technology. In this
research, we created a potentiostat system (ESPotensio) based on the ESP32
microcontroller for signal acquisition, processing, and data communication.
Various measurement methods are implemented not only limited to Cyclic
Voltammetry but also other methods, such as Linear Sweep Voltammetry, analysis
using several Pulse Voltammetry methods, and observation of current activity
against time with Chronoamperometry. Applying various measurement methods
aims to make this potentiostat more functional and reliable in some special cases
where this method is required. In addition, measurements can also be carried out
simultaneously in semi-parallel for three analytes simultaneously with three
measurement channels. The test results show that this tool can produce
voltammograms with an average accuracy of more than 80% for each method when
compared to Emstat Pico, a commercial potentiostat, as a reference.
|
|---|