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Methods and apparatus for introducing liquids into microfluidic chambers

a microfluidic system and liquid channel technology, applied in the field of microfluidic systems, can solve the problems of affecting the efficiency of microfluidic system filling, and difficult to remove bubbles from such systems, and achieve the effect of higher energy potential and higher energy potential

Inactive Publication Date: 2005-02-03
AGILENT TECH INC
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

The present invention relates to a method and apparatus for removing gas bubbles from a microfluidic system. The technical effect of the invention is to achieve complete liquid filling of the microfluidic system by reducing the energy potentials of the bubble, the source of liquid, the chamber, the barrier region, and the exit region, so that the bubble has enough energy to exit the system. This is achieved by reducing the energy potentials of the source, chamber, barrier region, and exit region with respect to the energy of the bubble. The invention also avoids the presence of gas bubbles at the end of a procedure by reducing the energy potentials of the source, chamber, barrier region, and exit region. The technical effect of the invention is to improve the efficiency and accuracy of liquid filling in microfluidic systems.

Problems solved by technology

One requirement is that the presence of gaseous bubbles in the system must be minimized, eliminated, or prevented because gaseous bubbles present a problem of hydraulic compliance, which degrades system performance.
Efficient filling of a microfluidic system with liquid can be problematic because gas bubbles such as air bubbles can be trapped in the liquid flow path during introduction of the liquid into the microfluidic system.
Such bubbles are difficult to remove from such systems.
However, the requirement of flushing the buffer solution with the expensive reagent liquid results in some waste of the expensive reagent liquid as well as waste of user time.
The process for establishing a liquid ionic conducting path through an artificially fabricated nanopore often presents difficulties.
Unfortunately, this approach sometimes fails because, when the air pressure is increased, the trapped air bubble may return to its original position, leaving the nanopore blocked.

Method used

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  • Methods and apparatus for introducing liquids into microfluidic chambers
  • Methods and apparatus for introducing liquids into microfluidic chambers
  • Methods and apparatus for introducing liquids into microfluidic chambers

Examples

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embodiment 100

[0071]FIG. 1D shows embodiment 100 at a time subsequent to the time of FIG. 1C. Ambient atmosphere 133 has been further reduced in pressure, and bubbles 130 and 132 have further expanded in volume. Bubble 130 fills a volume 134. Channel 136 comprises a source channel for liquid, narrow region 138 comprises a barrier region, and channel 140 and ambient gaseous volume 142 comprise an exit region.

[0072]FIG. 1E shows embodiment 100 at a time subsequent to the time of FIG. 1D. Ambient atmosphere 133 has been further reduced in pressure, and bubbles 130 and 132 have further expanded in volume. Bubble 130 has expanded past the narrow barrier region 138, and the radii of curvature of bubble boundary 144 are increasing as this boundary moves up in channel 140.

[0073]FIG. 1F shows embodiment 100 at a time subsequent to the time of FIG. 1E. Ambient atmosphere 133 has been further reduced in pressure, and bubble 132 has expanded further in volume. But bubble 130 has burst at boundary 144, and t...

embodiment 200

[0077] In embodiment 200 as illustrated in FIGS. 2A and 2B, firing chamber 202 comprises firing chamber volume 202a, which is surrounded by firing chamber walls 203. Piezoelectric actuator 204 is adjacent to wall area 205 and, during normal operation of the inkjet, causes ink to be ejected from firing orifice 206 to a substrate, not shown, such as paper or glass. Liquid 207, for example, ink, is supplied to firing chamber 202 through orifice 208 from source channel 210. For purposes of the present invention, barrier orifice 212 and an exit region comprising aperture 214 and ambient volume 215 are included with the inkjet firing chamber. Region 216 may be occupied in part by gaseous bubble 218, which is present in spite of careful filling procedures, or which originates within the liquid 207 because of outgassing of dissolved gas. Gaseous bubble 218 can prevent the inkjet from firing because it introduces a gas elasticity to the system; the situation is similar to the problem of air ...

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Abstract

The present invention is directed to methods and apparatus for removing a gaseous bubble confined in a microvolume of liquid in a chamber. A source of liquid, a barrier region and an exit region are provided in fluid communication with the chamber. The source of liquid has an energy potential as regards movement of the gaseous bubble that is higher than the energy potential of the barrier region, the barrier region has a higher energy potential than the chamber, and the chamber has a higher energy potential than the exit region. The energy potential is reduced within the chamber, the source of liquid, the barrier region, and the exit region by an amount such that the energy within the gaseous bubble is sufficient to displace the gaseous bubble from the chamber through the barrier region and out the exit region and to fill the chamber with the liquid from the source.

Description

BACKGROUND OF THE INVENTION [0001] The present invention relates to microfluidic systems, and more particularly, to methods and apparatus for introducing and distributing fluid in channels of a microfluidic system. More particularly, the invention relates to filling microfluidic systems with liquids in a manner such that no gaseous bubbles are present in the system after filling, because such bubbles, if present, degrade the performance of the system. The microfluidic systems include, for example, microdroplet dispensing devices, microdevices with artificial nanopores, and the like. [0002] In the field of diagnostics and therapeutics, it is often useful to attach species to a surface. One important application is in solid phase chemical synthesis wherein initial derivatization of a substrate surface enables synthesis of polymers such as oligonucleotides and peptides on the substrate itself. Substrate bound oligomer arrays, particularly oligonucleotide arrays, may be used in screenin...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): B01D19/00B01L3/00B01L3/02G01N35/10
CPCB01D19/00B01L3/0268G01N2035/1018B01L2200/0642B01L2200/0684B01L3/502723Y10T137/206
Inventor BARTH, PHILLIP W.YEFCHAK, GEORGE E.
Owner AGILENT TECH INC
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