Revision as of 14:52, 17 October 2016

Team SUSTC-Shenzhen

Test

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Calibration of fluid flow velocity

To visualize the flow profile, rainbow beads (SPHERO^TM Rainbow Calibration Particles, diameter: 6um) were dissolved in the cell culture medium, which contained the dead cells. A series of pumped flow rate(5μl/min, 15μl/min, and 45μl/min) were applied to generate a steady fluid flow. The exposure time was set to 100ms so that the length of the streakline (shown as a gray line in picture) represented the total traveling distance of the beads during the exposure. Fig. 1 shows a typical image of a bead trace in the fast microfluidics channel with a pumped flow rate of 5μl/min. To minimize hydraulic effects of the PDMS walls, the pictures were taken from the midplane of the channel providing the maximum flow velocity. Note that the traveling direction of the beads was left. Each streak was measured separately, and the average length of all streaks in one particular channel divides the exposure time was regarded as the maximum flow velocity of this channel. ^[1]

T--SUSTech Shenzhen--DB56D45F-D056-4A82-897A-2CE77C2C4A12.png

Fig. 1: a typical image of a bead trace in the fast microfluidics channel with a pumped flow rate of 5μl/min.

Experiment

To minimize the error, we took pictures on fast microfluidics channel when pumped flow rate was 5μl/min; on mid microfluidics channel when pumped flow rate was 15μl/min; on slow microfluidics channel when pumped flow rate was 45μl/min, considering that fluid flow velocity is proportional to pumped flow rate.

Data collection blow:

channel	flow rate(μl/min)	length①(um)	length②(um)	length③(um)
fast	5	630	455	610
mid	15	180	160	180
slow	45	48	75	80

Result

We wrote a MatLab program to calculate the maximum flow velocities. Codes were shown below:

MatLab Code:

ex_fast=[630,455,610]*90;

% align the data to um/s by multiply 10 and convert to 45μl/min

ex_mid=[180,160,180]*30;

ex_slow=[48,75,80]*10;

ex_fast_mean=mean(ex_fast); ex_fast_std=std(ex_fast);

ex_mid_mean=mean(ex_mid); ex_mid_std=std(ex_mid);

ex_slow_mean=mean(ex_slow); ex_slow_std=std(ex_slow);

Note: ex_fast_mean is the mean value of maximum flow velocity of fast microfluidics channel when pumped flow rate is 45μl/min, ex_fast_std is its standard deviation, et cetera.

variable	mean(um/s)	variable	std(um/s)
ex_fast_mean	50850	ex_fast_std	8600
ex_mid_mean	5200	ex_mid_std	350
ex_slow_mean	676	ex_slow_std	170

The ratio of maximum velocities in 3 different channels is 13:100:978.

T--SUSTech Shenzhen--855C7E02-2E51-441A-9492-A2B281185010.png

Fig. 2: the graph of fluid flow velocities results under the pumped flow rate of 45μl/min.

Reference

↑ Maneshi MM, Sachs F, Hua SZ, A Threshold Shear Force for Calcium Influx in an Astrocyte Model of Traumatic Brain Injury.J Neurotrauma. 2015 Jul 1, 32(13) : p. 1020-9.

[1] Maneshi MM, Sachs F, Hua SZ, A Threshold Shear Force for Calcium Influx in an Astrocyte Model of Traumatic Brain Injury.J Neurotrauma. 2015 Jul 1, 32(13) : p. 1020-9.

[1]

@@ Line 9: / Line 9: @@
 = Calibration of fluid flow velocity =
-To visualize the flow profile, rainbow beads (SPHERO<sup>TM</sup> Rainbow Calibration Particles, diameter: 6um) were dissolved in the cell culture medium, which contained the dead cells. A series of pumped flow rate(5ul/min, 15ul/min, and 45ul/min) were applied to generate a steady fluid flow. The exposure time was set to 100ms so that the length of the streakline (shown as a gray line in picture) represented the total traveling distance of the beads during the exposure. Fig. 1 shows a typical image of a bead trace in the fast microfluidics channel with a pumped flow rate of 5ul/min. To minimize hydraulic effects of the PDMS walls, the pictures were taken from the midplane of the channel providing the maximum flow velocity. Note that the traveling direction of the beads was left. Each streak was measured separately, and the average length of all streaks in one particular channel divides the exposure time was regarded as the maximum flow velocity of this channel.  <ref>Maneshi MM, Sachs F, Hua SZ, ''A Threshold Shear Force for Calcium Influx in an Astrocyte Model of Traumatic Brain Injury.''J Neurotrauma. 2015 Jul 1, '''32'''(13) : p. 1020-9. </ref>
+To visualize the flow profile, rainbow beads (SPHERO<sup>TM</sup> Rainbow Calibration Particles, diameter: 6um) were dissolved in the cell culture medium, which contained the dead cells. A series of pumped flow rate(5μl/min, 15μl/min, and 45μl/min) were applied to generate a steady fluid flow. The exposure time was set to 100ms so that the length of the streakline (shown as a gray line in picture) represented the total traveling distance of the beads during the exposure. Fig. 1 shows a typical image of a bead trace in the fast microfluidics channel with a pumped flow rate of 5μl/min. To minimize hydraulic effects of the PDMS walls, the pictures were taken from the midplane of the channel providing the maximum flow velocity. Note that the traveling direction of the beads was left. Each streak was measured separately, and the average length of all streaks in one particular channel divides the exposure time was regarded as the maximum flow velocity of this channel.  <ref>Maneshi MM, Sachs F, Hua SZ, ''A Threshold Shear Force for Calcium Influx in an Astrocyte Model of Traumatic Brain Injury.''J Neurotrauma. 2015 Jul 1, '''32'''(13) : p. 1020-9. </ref>
-{{SUSTech_Image | filename=T--SUSTech_Shenzhen--DB56D45F-D056-4A82-897A-2CE77C2C4A12.png | caption=Fig. 1: a typical image of a bead trace in the fast microfluidics channel with a pumped flow rate of 5ul/min. | width=1000px}}
+{{SUSTech_Image | filename=T--SUSTech_Shenzhen--DB56D45F-D056-4A82-897A-2CE77C2C4A12.png | caption=Fig. 1: a typical image of a bead trace in the fast microfluidics channel with a pumped flow rate of 5μl/min. | width=1000px}}
 == Experiment ==
-To minimize the error, we took pictures on fast microfluidics channel when pumped flow rate was 5ul/min; on mid microfluidics channel when pumped flow rate was 15ul/min; on slow microfluidics channel when pumped flow rate was 45ul/min, considering that fluid flow velocity is proportional to pumped flow rate.
+To minimize the error, we took pictures on fast microfluidics channel when pumped flow rate was 5μl/min; on mid microfluidics channel when pumped flow rate was 15μl/min; on slow microfluidics channel when pumped flow rate was 45μl/min, considering that fluid flow velocity is proportional to pumped flow rate.
 Data collection blow:
 {| class="table table-striped"
-! channel !! flow rate(ul/min) !! length①(um) !! length②(um) !! length③(um)
+! channel !! flow rate(μl/min) !! length①(um) !! length②(um) !! length③(um)
 |-
 | fast || 5 || 630 || 455 || 610
@@ Line 32: / Line 32: @@
 ex_fast=[630,455,610]*90;
 </p><p>
-% align the data to um/s by multiply 10 and convert to 45ul/min
+% align the data to um/s by multiply 10 and convert to 45μl/min
 </p><p>
 ex_mid=[180,160,180]*30;
@@ Line 46: / Line 46: @@
 </div>
 </html>
-Note: ex_fast_mean is the mean value of maximum flow velocity of fast microfluidics channel when pumped flow rate is 45ul/min, ex_fast_std is its standard deviation, et cetera.
+Note: ex_fast_mean is the mean value of maximum flow velocity of fast microfluidics channel when pumped flow rate is 45μl/min, ex_fast_std is its standard deviation, et cetera.
 {| class="table table-striped"
@@ Line 60: / Line 60: @@
 The ratio of maximum velocities in 3 different channels is 13:100:978.
-{{SUSTech_Image | filename=T--SUSTech_Shenzhen--855C7E02-2E51-441A-9492-A2B281185010.png | caption=Fig. 2: the graph of fluid flow velocities results under the pumped flow rate of 45ul/min. | width=1000px}}
+{{SUSTech_Image | filename=T--SUSTech_Shenzhen--855C7E02-2E51-441A-9492-A2B281185010.png | caption=Fig. 2: the graph of fluid flow velocities results under the pumped flow rate of 45μl/min. | width=1000px}}
 = Reference =

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