JP4442884B2 - Microfluidic device - Google Patents

Description

  The present invention relates to a microfluidic device used for mixing, separating, analyzing, and the like of a minute sample in biochemistry, analytical chemistry, etc. or in the medical field, and in particular, the flow rate of a minute channel through which the minute sample flows. The present invention relates to a microfluidic device that can be easily controlled.

  In recent years, a microfluid that forms a micro space having functions such as a flow path, a reaction section, a separation section, and a detection section inside a glass or plastic microchip and processes a small amount of sample at high speed in the microchip. Device development is progressing.

(First conventional example)
FIG. 12 shows such a microfluidic device 101 in which the flow control of the sample 104 that flows from the reaction vessel 102 to the separation unit 103 is controlled by a solid such as glass beads or polymer beads contained in the reaction vessel 102. This is performed with fine particles (hereinafter simply referred to as beads) 105 (see Patent Document 1).

(Second conventional example)
FIG. 13 shows a liquid transport apparatus 201 that can be used as a microfluidic device. 13 is opened so that the first flow path 202 and the second flow path 203 are opposed to the third flow path 204, and an opening portion of the first flow path 202 is provided. Heaters 205 and 206 are attached in the vicinity and in the vicinity of the opening of the second channel 203, respectively, and a diaphragm-like valve that opens and closes the opening of the first channel 202 and the opening of the second channel 203. A body 207 is attached to the third flow path 204 side. Then, when the liquid in the first flow path 202 is heated by one heater 205 and bubbles 208 are generated in the liquid in the first flow path 202, the pressure on the first flow path 202 side is changed to the second flow. The pressure is higher than the pressure on the path 203 side, the valve body 207 is pressed against the opening of the second flow path 203 by the pressure on the first flow path 202 side, and the opening of the second flow path 203 is The first flow path 202 and the third flow path 204 are in communication with each other. Further, when the liquid in the second channel 203 is heated by the other heater 206 and bubbles 208 are generated in the liquid in the second channel 203, the pressure on the second channel 203 side is changed to the first flow rate. The pressure becomes higher than the pressure on the path 202 side, and the valve body 207 is pressed against the opening of the first flow path 202 by the pressure on the second flow path 203 side, and the opening of the first flow path 202 becomes the valve body 207. The second flow path 203 and the third flow path 204 communicate with each other (see Patent Document 2).

(Third conventional example)
In addition, a technology for stirring and mixing the liquid in the mixing tank has already been developed by heating the heater in the mixing tank, generating bubbles in the liquid in the mixing tank, and expanding and contracting the bubbles. (See Patent Document 3).

(Fourth conventional example)
In addition, a technique has been developed in which bubbles are generated by electrolysis and a liquid is moved by the bubbles. The technology of the microfluidic device according to the fourth conventional example can eliminate bubbles by electrolysis as well as generating bubbles by electrolysis (see Patent Document 4). .

(Other conventional examples)
A technique is known in which microbubbles in a medium are captured by a laser, and the captured microbubbles are guided by a laser and injected into a microcontainer (see Patent Document 5 as a fifth conventional example).

JP 2001-4628 A (refer to paragraph number 0012 in particular) JP 2004-125172 A (refer to paragraph numbers 0019 and 0020 in particular) JP 2004-53370 A (refer to paragraph number 0016 in particular) JP 2004-43973 A (refer in particular to paragraph numbers 0014, 0019, 0026, 0027) Japanese Patent Laid-Open No. 2003-106950 (in particular, see page 1, paragraph numbers 0006 and 0019)

  However, in the microfluidic device 101 of the first conventional example, the protective plate 107 is bonded to the substrate 106, and the upper part of the reaction vessel 102 is closed by the protective plate 107. It is difficult to easily remove the beads 105 accommodated in the 102 and replacement of the beads 105 is difficult. Further, in such a microfluidic device 101, it is difficult to completely clean the beads 105. Therefore, such a microfluidic device 101 is the same in order to prevent mixing of impurities and enable accurate analysis when, for example, component analysis is performed by changing the type of liquid (sample) 104 to be handled. There was a problem that could not be used repeatedly.

  Further, in the second conventional example, heaters 205 and 206 and a diaphragm-like valve body 207 are not attached in a minute flow path (first flow path 202, second flow path 203, and third flow path 204). In other words, the structure is complicated and the manufacturing is not easy. In addition, the second conventional example has a structure in which heaters 205 and 206 and a diaphragm-like valve body 207 are arranged in the micro flow path (202, 203, 204). As in the first conventional example, cleaning is performed. Since it is not easy, when performing component analysis etc. by changing the type of liquid (sample) to be handled, there is a problem that the same thing cannot be used repeatedly.

  In the third conventional example, the bubbles are simply expanded and contracted in the mixing tank, and the size of the bubbles and the number of bubbles cannot be controlled. For this reason, the technology of the third conventional example is a technology (flow rate variable valve technology) in which the flow rate of the liquid moving in the micro flow channel is accurately controlled by changing the cross-sectional area of the micro flow channel in multiple stages. I couldn't apply it.

  Further, in the fourth conventional example, since bubbles are generated by electrolysis, there is a problem that bubbles can be generated only in a liquid having conductivity, or a charged substance remaining in the liquid. There was a problem that the electrolysis was caused by the applied voltage.

  Further, the fifth conventional example is a technique that merely captures and guides bubbles with a laser, and the number and size of the bubbles cannot be controlled.

  Accordingly, an object of the present invention is to provide a microfluidic device that can control the number of bubbles generated and the size of bubbles, can control the flow of a sample with a simple structure, and can be used repeatedly. To do.

The invention of claim 1 has a light irradiation means for irradiating light in or around the flow path into which the liquid is introduced, and the liquid in the flow path is irradiated by light emitted from the light irradiation means. And a microfluidic device adapted to generate bubbles in the flow path. The microfluidic device is configured to irradiate the bubble with irradiation light from the light irradiation means and to collect the irradiation light from the light irradiation means at one point. And the irradiation energy of the irradiation light irradiated to the bubble from the light irradiation means is controlled to such an extent that the bubble does not grow, and the bubble is moved by the force of the irradiation light generated from the difference in refractive index between the bubble and the liquid. The bubbles are pressed against the wall surface of the flow path so as to capture the bubbles at a fixed location in the flow path.

According to a second aspect of the present invention, in the microfluidic device according to the first aspect of the invention, the light irradiation means includes a condensing position variable mechanism that changes a light irradiation position, and the light irradiation position is determined by the condensing position variable mechanism. By changing the temperature, the liquid at a position different from the position where the bubbles are captured is heated, and the bubbles are moved by the Marangoni effect.

The invention of claim 3 is characterized in that in the microfluidic device according to claim 2, the bubbles can be eliminated or reduced. That is, the flow path of the microfluidic device according to the invention of claim 2 is formed of a material that transmits gas but does not transmit liquid. In addition, a negative pressure chamber is formed in a predetermined position of the flow path so as to be close to the flow path. Then, the gas inside the bubble moved by the Marangoni effect to the predetermined position of the flow path by sucking the negative pressure chamber by the negative pressure generating means and adjusting the pressure in the negative pressure chamber Is sucked into the negative pressure chamber to eliminate or reduce the bubbles.

  The microfluidic device of the present invention can control the number of bubbles generated in the liquid (sample) in the microchannel and the size and position of the bubbles, and can control the flow of the liquid with a simple structure. In addition, the microfluidic device of the present invention can cause bubbles to function like a valve body of a variable valve. In addition, the microfluidic device of the present invention can be used repeatedly because it can easily remove bubbles generated in the flow path and can easily generate new bubbles.

Hereinafter, embodiments of a microfluidic device to which the present invention is applied will be described with reference to the drawings.
[First form]
1 and 2 show a microfluidic device 1 according to a first embodiment of the present invention. 1 is an external perspective view schematically showing the microfluidic device 1 according to the first embodiment of the present invention. FIG. 2 is a schematic plan view showing a part of the microfluidic device 1 in an enlarged manner, omitting a second plate member to be described later.

  In these drawings, the microfluidic device 1 is a resin material excellent in optical properties such as PDMS (polydimethylsiloxane), PC (polycarbonate), PMMA (polymethyl methacrylate), PS (polystyrene), amorphous polyolefin, or the like. A first plate member 2 formed of a glass material and a second plate member 3 (shown by a two-dot chain line for convenience of explanation) fixed to the first plate member 2 by adhesion or welding. ing. In the present embodiment, the second plate member 3 is formed of the same material as the first plate member 2.

The first plate member 2 has a substantially rectangular cross section on the surface (surface to which the second plate member 3 is fixed) 4 side and a micro groove cross section (for example, the groove width is 100 μm and the groove depth is 130 μm ). ) Micro-grooves 5a are formed. Then, when the second plate member 3 is fixed to the surface 4 of the first plate member 2, the upper opening of the minute groove 5a is covered with the second plate member 3, and the minute flow path 5 corresponding to the minute groove 5a. Is formed.

A sample injection hole 6 is formed on the second plate member 3 side of a portion desired for one end of the microchannel 5, and a portion desired for the other end of the microchannel 5 is disposed on the second plate member 3 side. A sample discharge hole 7 is formed. A light absorber 8 having high light absorptivity is disposed in the middle of the minute channel 5, and the light absorber 8 constitutes a part of the wall surface of the minute channel 5. The light absorber 8 is formed of a resin material containing a high light absorption substance such as carbon. When the light absorber 8 is irradiated with the laser light L, the light absorber 8 efficiently absorbs the laser light L to convert light energy into heat, and locally introduces the liquid introduced into the microchannel 5. Used to generate bubbles 10 by heating. For this reason, the light absorber 8 is formed to have a light receiving area smaller than the projected area of the spherical bubble 10 in the microchannel 5 (cross-sectional area at the diameter position of the bubble 10).

  And the light irradiation means 11 is arrange | positioned in the middle of the microchannel 5 in which this light absorber 8 is arrange | positioned. The light irradiation means 11 includes a laser generator 12, a light introduction part (light guide path) 19 for guiding the light from the laser generation apparatus 12 to a light collection means (light collection optical system) 13, and the light introduction part 19. A light condensing means 13 for adjusting the light condensing position of the light introduced through the light absorber 8 toward the light absorber 8 side, and an energization controller 15 for connecting the laser generator 12 and the external power source 14. Among these, the energization controller 15 controls the energization amount to the laser generator 12. In addition, the condensing unit 13 may include a condensing lens, and may include a condensing position variable mechanism that can move the condensing position along the microchannel 5 as necessary. The light condensing means 13 may be formed integrally with the first plate member 2 or the second plate member 3 of the microfluidic device 1, and together with other configurations of the light irradiating means 11, You may arrange | position to (separate body).

  In addition, according to this embodiment, since it is the structure which makes the light-receiving area of the light absorber 8 smaller than the bubble (bubble used for flow volume adjustment) 10, the condensing means 13 may be abbreviate | omitted. Thus, when the condensing means 13 is omitted, the structure of the microfluidic device 1 can be simplified. Even in the microfluidic device 1 having such a structure, the light energy of the laser light L introduced from the light introducing portion 19 can be absorbed by the light absorber 8 having a very narrow light receiving area, and the light energy of the laser light L can be efficiently obtained. Therefore, desired bubbles can be generated in the liquid in the microchannel 5.

  According to the present embodiment having such a configuration, the laser beam L introduced from the light introducing unit 19 is irradiated to the light absorber 8 through the condensing means 13, and the liquid near the light absorber 8 is locally applied. Is rapidly heated to expand the gas dissolved in the liquid, thereby generating bubbles 10 in the liquid. At this time, the energization controller 15 controls the amount of energization to the laser generator 12 to variably control the irradiation energy of the laser light L output from the laser generator 12, thereby reducing the size of the bubble 10 from small to medium. The flow control of the liquid can be performed in multiple stages by changing the cross-sectional area in which the liquid in the micro flow path 5 can flow from the middle to the large. Thus, according to the present embodiment, the bubble 10 can function as a variable flow rate valve or an open / close valve of the micro flow path 5.

  Further, according to the present embodiment, since the light absorber 8 is irradiated with the laser light L, light energy can be efficiently converted into heat, and the power consumption of the light irradiation means 11 can be kept low. Can do.

  In addition, according to the present embodiment, the flow rate adjustment of the microchannel 5 is performed with the bubbles 10, and therefore, by erasing the bubbles 10 generated in the microchannel 5, Easy to clean. In addition, since the microfluidic device 1 according to the present embodiment can easily generate new bubbles in addition to the extinguished bubbles, there is a problem that the measurement target sample and the cleaning residual sample are mixed. It is difficult to use repeatedly when analyzing different samples.

  In the present embodiment, when the condensing means 13 includes a condensing position variable mechanism (not shown), the bubble 10 is captured at a predetermined position by the laser light L and stopped (held). Needless to say, the bubble 10 captured by the laser beam L can be moved in accordance with the change of the condensing positions P1, P2 and P3 of the laser beam L (see FIG. 2). Moreover, in this embodiment, when the condensing means 13 is installed separately from the microfluidic device 1, by moving the condensing means 13 relative to the microchannel 5, the bubble generation position (P1) and Can heat the liquid at another location and move the bubbles 10 by the Marangoni effect. Thus, the condensing means 13 also functions as a bubble moving means. In order to capture and stop the bubble 10 with the laser light L, the irradiation energy of the laser light L applied to the bubble 10 may be controlled to an irradiation energy that does not cause the bubble 10 to grow. If it does in this way, from the difference of the refractive index of the bubble (gas) 10 and the refractive index of a liquid, the force which presses the bubble 10 against the wall surface of the microchannel 5 by the laser beam L will arise, and the force which the laser beam L produces | generates As a result, the bubbles 10 are trapped at a fixed location.

  If such a condensing position P1 (P2, P3) can be moved, a plurality of microchannels 16, 17 can be opened and closed with one bubble 10, as shown in FIG. It becomes possible.

  In addition, if such a condensing position P1 (P2, P3) can be moved, as shown in FIG. 4, the holding object 18 such as protein or particulate matter is adsorbed and held in the bubble 10. The object 18 can be held or moved to a predetermined position by the bubble 10. In addition, according to this embodiment in which the bubble 10 having adsorbed the holding object 18 can be moved by the Marangoni effect, the restriction on the holding object 18 is reduced as compared with the case where the holding object 18 is moved using the optical tweezer technology. . For example, when the holding object 18 is moved using the technique of optical tweezers, there is a limitation that the refractive index of the holding object 18 must be larger than that of the liquid and must be transparent.

  Further, if such a condensing position P1 (P2, P3) can be moved, as shown in FIG. 5, the bubble is placed at a predetermined position (position where the bubble 10 is to be erased) of the microchannel 5 as shown in FIG. After the erasing unit 20 is arranged and the bubble 10 is moved to the position where the bubble erasing unit 20 is arranged, the bubble erasing unit 20 can erase the bubble. In addition, the bubble erasing means 20 of the present embodiment is disposed at a predetermined position of the micro flow path 5 of the first plate member 2 formed of a material such as silicone rubber (for example, PDMS) that allows gas to pass but does not transmit liquid. A negative pressure chamber 21 for sucking the bubbles 10 is formed close to the micro flow path 5, and the inside of the negative pressure chamber 21 is sucked by a negative pressure generating means (not shown) such as an external vacuum pump. The pressure in the pressure chamber 21 is set to be about 100 kPa lower than the external pressure. Note that the wall portion 22 that partitions the negative pressure chamber 21 and the micro flow path 5 is extremely thin (for example, as thin as about 30 μm) so that the gas inside the bubble 10 can be efficiently sucked. . According to such a configuration, the gas forming the bubble 10 is sucked into the negative pressure chamber 21, and the bubble 10 is reduced to a desired size at the position where the negative pressure chamber 21 is formed (FIGS. 5A to 5B). )) Or completely disappear. Here, selection of whether the bubble 10 is reduced to a desired size or the bubble 10 is completely extinguished is made possible by adjusting the pressure in the negative pressure chamber 21. And after the bubble 10 disappears, the substance adsorbed in the bubble 10 can flow in the microchannel 5.

  In addition, according to the present embodiment, the energy of the laser light L emitted from the light introducing unit 19 can be controlled by the energization controller 15 and the generation timing of the bubbles 10 can be adjusted at a predetermined interval. The liquid to be separated can be accurately separated by the bubble 10 every predetermined amount.

  In the present embodiment, the irradiation width of the laser light L is about 50 to 60 μm, the heating width of the light absorber 8 is also the same, and one bubble 10 is generated. Even if a plurality of small bubbles are generated in the process of growing large bubbles, the plurality of small bubbles are absorbed into the large bubbles by the Ostwald growth of the bubbles and become one large bubble.

  In the present embodiment, the light introducing unit 19 exemplifies a mode of emitting the laser light L, but is not limited thereto, and light other than the laser light (for example, a xenon lamp, a mercury lamp, a halogen lamp, or an LED) is used. You may make it use the thing of the structure which irradiates.

In the present embodiment, the bubble 10 generated by irradiating the light absorber 8 with the laser light L is a sphere separated from the wall surface of the microchannel 5 by controlling the contact angle between the microchannel 5 and the liquid. It can be controlled whether it becomes a shape or a hemispherical shape along the wall surface of the microchannel 5. Examples of a method for controlling the contact angle between the microchannel 5 and the liquid include a method using oxygen plasma, excimer UV, silane coupling, and graft polymerization.
[Second form]
FIG. 6 is a modification of the first embodiment and shows a second embodiment of the present invention. In addition, although this 2nd form shows the light absorber 8a of the aspect different from the light absorber 8 of the above-mentioned 1st form, since another structure is the same as that of the 1st form, it is 1st form. The same reference numerals are given to the same components as those in FIG. 1, and the description that overlaps with the first embodiment will be omitted.

  As shown in FIG. 6, the microfluidic device 1 of the present embodiment is formed such that the size of the light absorber 8a disposed in the microchannel 5 is a light receiving area larger than the projected area of the bubbles 10, The light from the light introducing portion 19 is condensed on the light absorber 8a by the condensing means 13 so that the light energy can be efficiently converted into heat energy, and a desired bubble is formed in the liquid in the microchannel 5. 10 is generated. Here, the magnification of the lens, the focal length, and the like of the condensing unit 13 are determined so that the irradiation area of the laser light L onto the light absorber 8a is smaller than the projected area of the bubble 10 onto the light absorber 8a. ing.

According to this embodiment having such a configuration, it is possible to obtain the same effect as that of the first embodiment.
[Third embodiment]
FIG. 7 shows a modification of the first embodiment and shows a third embodiment of the present invention. In addition, although this 3rd form shows the bubble erasing means 23 of the aspect different from the bubble erasing means 20 of the above-mentioned 1st form, since the other structure is the same as that of a 1st form, 1st form The same reference numerals are given to the same components as those in FIG. 1, and the description that overlaps with the first embodiment will be omitted.

  As shown in FIG. 7, in the microfluidic device 1 of the present embodiment, a hydrophilic wall surface region 24 and a hydrophobic wall surface region 25 are formed in the microchannel 5 and the bubbles 10 are used as a substantially spherical body. In addition, when the bubble 10 is held in the hydrophilic wall region 24 (see FIG. 7A) and the bubble 10 is crushed as if it disappeared, the bubble 10 is moved to the hydrophobic wall region 25 (FIG. 7). (See (b)).

  According to such a configuration, the microchannel 5 is narrowed by the spherical bubbles 10 in the hydrophilic wall region 24 and the flow of the liquid is restricted, but the bubbles 10 are moved to the hydrophobic wall region 25. Then, the volume of the bubbles 10 is the same, but the state in which the bubbles 10 are crushed as if they were pressed against the hydrophobic wall region 25 and blocked by the spherical bubbles 10 is eliminated, and the liquid flows. It is possible to increase the cross-sectional area of the flow path. Therefore, the channel cross-sectional area of the microchannel 5 can be changed also with such a configuration.

If the bubble erasing means 20 of the first embodiment is applied to the third embodiment and the negative pressure chamber 21 is formed in the hydrophobic wall region 25, the bubble 10 is crushed by the hydrophobic wall region 25. Therefore, the contact area between the wall surface on which the negative pressure chamber 21 is formed and the bubble 10 is larger than that in the second embodiment, and the time required until the bubble 10 is extinguished can be shortened (FIG. 5 and FIG. 5). (See FIG. 7).

  As shown in FIG. 8, the microfluidic device 1 according to the present embodiment forms a recess 27 for containing the bubble 10 on the wall surface of the microchannel 5, and the bubble from the bubble generation position to the formation position of the recess 27. 10 is moved by the Marangoni effect, and the bubble 10 is accommodated (retracted) from the minute flow path 5 into the recess 27.

  In the present embodiment having such a configuration, if the bubble 10 is held in the microchannel 5, flow control can be performed by narrowing the channel cross-sectional area of the microchannel 5, and the bubble 10 is placed in the recess 27. If accommodated, the substance adsorbed in the bubble 10 can be retracted (removed) from the microchannel 5 and the microchannel 5 can be fully opened.

  In addition, as the bubble erasing means, a device that breaks bubbles with ultrasonic waves may be used. Further, it is conceivable to cool the liquid in the microchannel 5 to reduce the volume of the bubbles 10 or to increase the solubility of the liquid gas so that the bubbles are dissolved in the liquid.

  FIG. 9 is a diagram schematically showing Example 1 of the microfluidic device 1 to which the present invention is applied. The microfluidic device 1 shown in FIG. 9 divides two different types of samples (liquids) 30 and 31 into a predetermined amount of liquid droplets 30a and 31a by bubbles 10 and thereafter separates both liquid droplets 30a and 31a. It is supposed to be combined. In FIG. 9, pressure is applied to the first microchannel 32, the second microchannel 33, and the combined channel 34 so that the samples 30 and 31 flow from the left side to the right side in the drawing.

  In the microfluidic device 1 shown in FIG. 9, in order to divide and combine the liquids 30 and 31 as described above, the first microchannel 32 that causes the first sample 30 to flow and the second sample 31 that flows. The first microplate 33 is formed with a second microchannel 33 to be formed, and a combined channel 34 as a microchannel in which the first microchannel 32 and the second microchannel 33 merge in a Y shape. . And the light introduction part 19 and the light absorber 8 (8a) of the light irradiation means 11 are each arrange | positioned in the position where the 1st microchannel 32 and the 2nd microchannel 33 respond | correspond. As described in detail in the first embodiment, the light irradiation means 11 is energized and controlled by the energization controller 15, so that the bubbles 10 generated in the first microchannel 32 and the second microchannel 33 The size and timing can be made the same, and the first sample 30 of the first microchannel 32 and the second sample 31 of the second microchannel 33 can be separated by the same amount by bubbles. Therefore, in the process in which the divided liquid droplet 30a of the first sample 30 and the divided liquid droplet 31a of the second sample 31 are merged and combined by the same amount in the combined flow path 34 and flow downstream. A desired chemical reaction or the like is accurately performed.

  In the first embodiment, the first sample 30 of the first microchannel 32 and the second sample 31 of the second microchannel 33 are divided by the same amount, and then the same amount of liquid droplets divided. Although the example which couple | bonds 30a and 31a was shown, changing the magnitude | size of the bubble 10 which divides the 1st sample 30 and the 2nd sample 31, and changing the ratio of the samples 30 and 31 couple | bonded by the merge channel 34 It may be.

  In the first embodiment, the separation of the samples 30 and 31 by the bubbles 10 is controlled by appropriately performing the light irradiation intermittently by the light irradiation means 11. Here, appropriately interrupting the light irradiation means that the light irradiation is intermittently performed every predetermined time, or the boundary between the bubble 10 and the samples 30 and 31 is detected by an optical sensor or a capacitance sensor, For example, the light irradiation is intermittently performed at a predetermined control timing based on the detection position.

  FIG. 10 is a diagram schematically showing Example 2 of the microfluidic device 1 to which the present invention is applied. In FIG. 10, pressure is applied to the first microchannel 32, the second microchannel 33, and the combined channel 34 so that the samples (liquids) 30 and 31 flow from the left side to the right side in the drawing. ing.

  In the microfluidic device 1 shown in FIG. 10, the first microchannel 32 and the second microchannel 33 formed in the first plate member 2 are joined to the joint channel 34 in a Y shape, The light introduction part 19 and the light absorber 8 (8a) are arranged on the first microchannel 32 side. Then, the light absorber 8 (8 a) disposed in the first microchannel 32 is irradiated with the laser light L from the light introducing portion 19 of the light irradiation means 11, and the first sample 30 in the first microchannel 32 is irradiated. Bubbles 10 are generated, the first microchannel 32 is narrowed by the bubbles 10, and the first sample 30 flowing from the first microchannel 32 into the combined channel 34 and the second microchannel 33 flow into the combined channel 34. The flow rate ratio of the second sample 31 can be changed as appropriate. Note that the size of the bubble 10 generated in the first microchannel 32 can be changed by controlling the irradiation energy of the laser light L emitted from the light introduction unit 19 of the light irradiation unit 11 as described above. it can.

  FIG. 11 is a diagram schematically showing Example 3 of the microfluidic device 1 to which the present invention is applied. In FIG. 11, pressure is applied in the microchannel 40 so that the sample (liquid) 39 flows from the left side to the right side in the drawing.

  The microfluidic device 1 shown in FIG. 11 includes a first light irradiation means 41, a second light irradiation means 42, in order from the upstream side to the downstream side of the microchannel 40 formed in the first plate member 2. Third light irradiation means 43 is arranged along the microchannel 40.

  And in the 1st light irradiation part A to which the light from the 1st light irradiation means 41 is irradiated, the light absorber 44 which exhibits higher light absorptivity than the other part of the microchannel 40 is arrange | positioned. ing. When the light absorber 44 is irradiated with the laser light L from the first light irradiation means 41, the light absorber 44 absorbs the light and generates heat to generate the bubbles 10 in the liquid 39 in the microchannel 40. Thus, the 1st light irradiation means 41 functions as a bubble generation means which produces the bubble 10. FIG. Note that the bubble 10 is carried downstream by the liquid 39 flowing in the microchannel 40 by blocking the irradiation of the laser light L of the first light irradiation means 41 or reducing the irradiation energy.

  The second light irradiation unit B irradiated with the laser light L from the second light irradiation unit 42 and the third light irradiation unit C irradiated with the laser light L from the third light irradiation unit 43 include Further, a substance that easily absorbs light such as the light absorber 44 is not arranged. As a result, the laser beam L is irradiated from the second light irradiation means 42 to the bubble 10 flowing along with the liquid 39 in the microchannel 40, and the bubble 10 is pressed against the wall surface of the microchannel 40 with light pressure. The bubble 10 can be held in the second light irradiation part B. At this time, even if the irradiation energy of the laser light L emitted from the second light irradiation means 42 is large, the wall surface of the micro flow path 40 of the second light irradiation unit B hardly generates heat. In the second light irradiation part B, the bubble 10 is not newly generated or the bubble 10 does not grow. Therefore, even if the irradiation energy of the laser light L of the second light irradiation means 42 is increased in accordance with the flow speed of the liquid 39 in the microchannel 40, the bubbles 10 are made stronger without causing the above-described adverse effects due to heat generation. The second light irradiation part B can be reliably held with light pressure. As described above, the second light irradiation means 42 functions as a bubble holding means for holding the bubble 10 in the second light irradiation portion B.

  By blocking the irradiation of the laser light L of the second light irradiation means 42 or reducing the irradiation energy, the bubble 10 is moved from the second light irradiation part B to the third light irradiation part C side with a minute flow path. It is carried by a liquid 39 that flows within 40. Also in the third light irradiation part C, the bubbles 10 can be held by the laser light L from the third light irradiation means 43 as in the case of the second light irradiation part B. As described above, the third light irradiation means 43 functions as a bubble holding means for holding the bubble 10 in the third light irradiation portion C.

It is a typical external appearance perspective view of the microfluidic device to which this invention is applied. It is a typical top view which abbreviate | omits the 2nd plate member of the microfluidic device to which this invention is applied, and shows it partially expanded. It is a schematic plan view of the microfluidic device which shows the aspect which opens and closes several flow paths with air bubbles. It is a typical top view of the 1st plate member for showing one mode of a bubble function. It is a typical top view of the microfluidic device which shows the 1st aspect of a bubble elimination means. It is a schematic plan view which shows the 2nd form of the microfluidic device to which this invention is applied, and is a schematic plan view of the microfluidic device corresponding to FIG. It is a figure which shows the 3rd form of this invention, and is a typical top view of the microfluidic device which shows the 2nd aspect of a bubble elimination means. It is a figure which shows the 4th form of this invention, and is a typical top view of the microfluidic device which shows the 3rd aspect of a bubble elimination means. It is a typical top view of the microfluidic device concerning Example 1 of the present invention. It is a typical top view of the microfluidic device concerning Example 2 of the present invention. It is a typical top view of the microfluidic device concerning Example 3 of the present invention. It is a figure which shows the microfluidic device which concerns on a 1st prior art example, (a) is a typical top view which removes a protection plate, (b) is the cross section which cut | disconnects and shows along the AA line of (a) FIG. It is a typical top view of the liquid conveyance apparatus which concerns on a 2nd prior art example.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Microfluidic device, 5, 16, 17, 40 ... Micro flow path, 8, 8a, 44 ... Light absorber, 10 ... Bubble, 11 ... Light irradiation means, 13 ... Condensing means ( Condensing optical system, bubble moving means), 19... Light introducing portion (light guide path), 20, 23, 26... Bubble erasing means, 30 a, 31 a .. droplet, 32. 2nd microchannel, 34 ... Combined channel (microchannel), 41 ... 1st light irradiation means (light irradiation means), 42 ... 2nd light irradiation means (light irradiation means), 43 ... Third light irradiation means (light irradiation means), A ... First light irradiation section, B ... Second light irradiation section

Claims (3)

A light irradiating means for irradiating light in or around the flow path into which the liquid is introduced, and the liquid in the flow path is heated by the irradiation light from the light irradiating means; A microfluidic device adapted to generate bubbles therein ,
Irradiating light from the light irradiating means to the bubble, condensing the irradiating light from the light irradiating means at one point, and irradiating the bubble with irradiation energy from the light irradiating means. The bubble is pressed against the wall surface of the flow channel by the force of the irradiation light generated from the difference in refractive index between the bubble and the liquid, and the bubble is trapped at a certain location in the flow channel. ,
A microfluidic device characterized by that. The light irradiation means includes a light collection position variable mechanism that changes the light irradiation position,
The light irradiation position is changed by the condensing position variable mechanism, the liquid at a position different from the place where the bubbles are captured is heated, and the bubbles are moved by the Marangoni effect.
The microfluidic device according to claim 1 . The flow path is formed of a material that is permeable to gas but not liquid,
In a predetermined position of the flow path, a negative pressure chamber is formed close to the flow path,
By sucking the negative pressure chamber by negative pressure generating means and adjusting the pressure in the negative pressure chamber, the gas inside the bubbles moved to the predetermined position of the flow path by the Marangoni effect is Sucking into a negative pressure chamber to eliminate or reduce the bubbles,
The microfluidic device according to claim 2 .

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