DESIGN AND FABRICATION MICROFLUIDIC PLATFORM INTEGRATED WITH ELECTROCHEMICAL SENSOR USING 3D PRINTING METHOD
Lab-on-chip is the miniaturization of a laboratory into a small integrated chip that is centimeters or millimeters in size. The development of lab-on-chip cannot be separated from the microfluidic platform. Microfluidics is the study of fluid flow in microchannels. Microfluidic platforms allow th...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/74794 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Lab-on-chip is the miniaturization of a laboratory into a small integrated chip that
is centimeters or millimeters in size. The development of lab-on-chip cannot be
separated from the microfluidic platform. Microfluidics is the study of fluid flow in
microchannels. Microfluidic platforms allow the movement of small amounts of
samples into each of the lab-on-chip functions so that they can be integrated with
each other. One type of microfluidic development is an electrochemical testing
platform. The microfluidic platform can be integrated with a sensor that can detect
certain analytes. The platform is fabricated with materials that do not affect the
sensor’s performance. The commonly used microfluidic platform fabrication
methods are less integrated, expensive, and require a long process. By using 3D
printing, the fabrication process can be more integrated. The fabrication process
becomes faster and cheaper. The microfluidic platform that will be integrated with
a sensor and potentiostat device must be fabricated properly. The microfluidic
platform must be transparent to facilitate sample observation. The microfluidic
platform also does not interfere with the performance of the integrated sensor so it
can be used as an electrochemical testing platform.
Through several design developments, the microfluidic platform integrated with the
SPCE sensor and EmStat 4M potentiostat device was successfully fabricated. The
fabricated microfluidic platform is transparent. The development of several types
of designs resulted in the microfluidic platform repairing the leakage that occurred
in previous studies. The platform has a microchannel of ~1000 ?m with fabrication
errors almost entirely <10%. The performance of the fabricated microfluidic
platform as an electrochemical testing platform has good accuracy and
repeatability compared to the droplet method. Tests using the platform also tend to
have increased anodic peak current values due to the platform design that allows
the sample to hit the SPCE electrode evenly. |
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