DESIGN AND FABRICATION OF A FLOW CELL PLATFORM USING 3D PRINTING METHOD FOR THE INTEGRATION OF MULTI SCREEN PRINTED ELECTRODE-BASED SENSOR FOR THE DETECTION OF SODIUM AND POTASSIUM IONS
Microfluidics is a field of study and technology that explores the behavior of fluids and manufacturing techniques for fluid manipulation on a small scale. Microfluidics holds the potential for advancements in the miniaturization of experiments, making it highly conducive to continuous developmen...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/80966 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Microfluidics is a field of study and technology that explores the behavior of fluids
and manufacturing techniques for fluid manipulation on a small scale.
Microfluidics holds the potential for advancements in the miniaturization of
experiments, making it highly conducive to continuous development. The use of 3D
printing technology represents a significant development in manufacturing
techniques to create flexible and cost-effective microfluidic platforms. Meanwhile,
the functional development of microfluidics can be achieved through its integration
with other fields, such as biosensors. The integrated flow-cell platform aids the
biosensing process by providing a closed detection environment, reducing costs
and time, and allowing better fluid control access.
In this final project, the fabrication of a flow cell was conducted using 3D printing
methods. The printed results demonstrated good accuracy with errors in
microchannel and sensor slot designs of less than 14%. Leveraging the flexibility
of this method, exploration and optimization were conducted for the design of flow
cells for integration with single and multi electrochemical sensors for the detection
of sodium and potassium ions in the body. Based on the conducted tests, the
detection process of sodium and potassium in a single-sensor integrated flow cell
proceeded well, with respective Limits of Detection (LOD) of 0.149 mM and 51,461
?M. Meanwhile, in the measurement of mixed sodium and potassium solutions
using a multi-sensor integrated flow cell, differences in the selectivity of sodium
and potassium sensors were obtained. The sodium sensor reading only changed by
0.111% in the presence of potassium ions, whereas the potassium sensor reading
changed by 29.530% in the presence of sodium ions. Both the single-sensor and
multi-sensor integrated flow cells facilitated measurements under dynamic flow
conditions successfully, with maximum flow rates for sodium, potassium, and mixed
sodium and potassium solutions being below 10 mL/hour, 50 mL/hour, and 25
mL/hour, respectively. |
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