Team:EPF-Lausanne/Tools/Microfluidics/HowTo2

From 2011.igem.org

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(Hooking it all up: preparing tubes and priming the chip)
(A basic microfluidics control setup)
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== A basic microfluidics control setup ==
== A basic microfluidics control setup ==
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Building the setup is relatively straightforward, once you have understood what components are needed and their purpose, and once you have have the parts. Connecting the components is basic plumbing: just remember to wrap plumber's tape around all metallic screw threads, and the connect the pressure regulators in the correct orientation. With this in mind, we'll go through the parts of a microfluidics setup one by one, and from there you should be able to build your own.
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Building the setup is relatively straightforward, once you have determined which components are needed and their purpose, and once you have collected the parts. Connecting the components is basic plumbing: just remember to wrap plumber's tape around all metallic screw threads, and then connect the pressure regulators in the correct orientation. With this in mind, we'll go through the parts of a microfluidics setup one by one, and from there you should be able to build your own.
=== Injecting fluids: mains pressure and tubing, pressure regulators ===
=== Injecting fluids: mains pressure and tubing, pressure regulators ===
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Our chips have a second ''control layer'' above or below the main ''flow layer''. The layers are separated by a thin membrane of PDMS, and their channels overlap in specific locations. When channels of the control layer are pressurized, the membrane bends into the flow layer and blocks it. This creates a microfluidic 'on-chip' valve.
Our chips have a second ''control layer'' above or below the main ''flow layer''. The layers are separated by a thin membrane of PDMS, and their channels overlap in specific locations. When channels of the control layer are pressurized, the membrane bends into the flow layer and blocks it. This creates a microfluidic 'on-chip' valve.
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[[File:EPFL-Solenoids.jpg|thumb|left|Our array of solenoid valves, on a manifold. These allow individual pressurising of on-chip valves of the control layer.]]
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[[File:EPFL-Solenoids.jpg|thumb|left|Our array of solenoid valves, on a manifold. These allow individual pressurisation of on-chip valves of the control layer.]]
The channels of the control layer are filled in the same way as the flow layer, but require much higher pressure to bend the membrane. We typically used about 2 bar or 30 psi. Each independant valve in the control layer is pressurised by a different tube, regulated by a three-way valve. These switch between high pressure (from mains pressure, and the pressure regulator) to low pressure (atmospheric pressure), and hence allow quick toggling of the microfluidic valve between the open (unpressurised) and closed (pressurised) state. Three way valves come in manually- or electrically-controlled flavours. The manual kind is simpler and more reliable; we use them for the MITOMI chips. The electric kind (more specifically ''solenoid'' valves) we use for the web-controlled setup.
The channels of the control layer are filled in the same way as the flow layer, but require much higher pressure to bend the membrane. We typically used about 2 bar or 30 psi. Each independant valve in the control layer is pressurised by a different tube, regulated by a three-way valve. These switch between high pressure (from mains pressure, and the pressure regulator) to low pressure (atmospheric pressure), and hence allow quick toggling of the microfluidic valve between the open (unpressurised) and closed (pressurised) state. Three way valves come in manually- or electrically-controlled flavours. The manual kind is simpler and more reliable; we use them for the MITOMI chips. The electric kind (more specifically ''solenoid'' valves) we use for the web-controlled setup.

Revision as of 20:37, 21 September 2011