Systems for monitoring and controlling fluid flow rates in microfluidic systems
First Claim
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1. A system comprising:
- a microfluidic device that comprises a first channel network that includes at least a first microfluidic channel;
a flow controller operably coupled to the channel network to control fluid movement through the channel network;
a signal detector in sensory communication with a second position of the at least first microfluidic channel;
a computer operably coupled to the flow controller and the signal detector for instructing operation of the flow controller and for receiving data from the signal detector, the computer being programmed to;
receive a user input flow rate value;
instruct the flow controller to inject a detectable signal into a first position in the first microfluidic channel at a first time;
receive a detect signal from the detector that corresponds to detection of the detectable signal at the second position at a second time in the first microfluidic channel;
determine a flow rate of fluid in the first microfluidic channel from a distance between the first and second positions and the first and second times; and
instruct the flow controller to increase or decrease a flow rate in the first microfluidic channel to achieve the user input flow rate value.
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Abstract
The present invention generally provides methods and systems for monitoring and controlling electroosmotic flow rates in microfluidic systems. Generally, such methods and systems monitor flow rates in electroosmotically driven microfluidic systems by flowing signaling elements within these channels and measuring the flow rate of these signals. The methods of monitoring flow rates are also applied to methods and systems for continuously monitoring and controlling these flow rates in electroosmotically driven microfluidic systems.
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9 Claims
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1. A system comprising:
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a microfluidic device that comprises a first channel network that includes at least a first microfluidic channel;
a flow controller operably coupled to the channel network to control fluid movement through the channel network;
a signal detector in sensory communication with a second position of the at least first microfluidic channel;
a computer operably coupled to the flow controller and the signal detector for instructing operation of the flow controller and for receiving data from the signal detector, the computer being programmed to;
receive a user input flow rate value;
instruct the flow controller to inject a detectable signal into a first position in the first microfluidic channel at a first time;
receive a detect signal from the detector that corresponds to detection of the detectable signal at the second position at a second time in the first microfluidic channel;
determine a flow rate of fluid in the first microfluidic channel from a distance between the first and second positions and the first and second times; and
instruct the flow controller to increase or decrease a flow rate in the first microfluidic channel to achieve the user input flow rate value. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. In a computer that is operably coupled to a microfluidic system that includes a microfluidic device having a microfluidic channel network disposed therein, which network includes at lea t a first microfluidic channel, a detector in sensory communication with the first microfluidic channel and a flow controller operably coupled to the channel network to direct fluid movement through the channel network, a software program for:
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receiving a use input flow rate value;
initiating an inject signal instructing the flow controller to inject a detectable signal into the first microfluidic channel at a first position;
receiving a detect signal from the detector;
calculating a flow rate of fluid in the first microfluidic channel; and
instructing the flow controller to increase or decrease the flow rate in the first microfluidic channel in order to match the user input flow rate value. - View Dependent Claims (9)
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Specification