JP2004167479A - Fine particle sorting/recovering method and fine particle recovering apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fine particle sorting technique and a fine particle recovering technique, in which optical force or optical pressure is used, instead of the conventional cell sorting technique. <P>SOLUTION: This fine particle sorting/recovering method comprises a step to irradiate a fine particle flow passage with a laser beam from such a position that the laser beam intersects the fine particle flow direction and a step to bias the moving direction of the fine particles to be recovered in the direction that the laser beam converges. This fine particle recovering apparatus is provided with a recovering part for recovering the fine particles responsive to the optical force or pressure, a laser beam irradiating part and a flow passage arranged between the recovering part and the laser beam irradiating part for making such a gas or liquid flow that contains the fine particles responsive to the optical force or optical pressure and the fine particles unresponsive to the optical force oroptical pressure. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates to a method and a device for separating and collecting fine particles such as cells, and a flow cytometry and a cell sorter using the same.

  At present, as a method for selecting specific individual cells from a population of fine particles such as cells, a cell sorting technique based on flow cytometry is known (for example, see Non-Patent Document 1).

  In this technique, a suspension of target cells to which antibodies previously labeled with a fluorescent dye or the like are bound is used as a liquid flow, and the cells are first irradiated with excitation light in the flow channel in accordance with the labeled fluorescent dye. The desired cells are identified by analyzing the wavelength and intensity of the fluorescence or scattered light emitted from each cell. Next, a voltage is applied to the cells having the specific properties identified by the analysis results such as the light intensity and the wavelength to charge the cells, and the above-described charged cells are distinguished, quantitated, and statistically analyzed using a deflection electrode. And so on.

  This method can collect and isolate various cultured cells and identify specific cells in immunology, hematology, genetic engineering, etc., since cells can be processed in a large amount and at a high speed in a living state. It is widely used for cloning / proliferation, fractionation of cells expressing a specific antigen on the cell surface, and for dynamic analysis of cell membrane molecules and analysis of cell chromosomes. In particular, it is becoming an indispensable tool for analyzing cell dynamics. This technique has also begun to be used in the clinical field, for example, for the analysis of material components in urine.

  The cell analysis and cell separation device used for the cell sorting technique by the flow cytometry is called a cell sorter (Fluororescence-Activated Cell Sorter, FACS). This apparatus further includes a sorting unit downstream of the analysis unit for analyzing the fluorescence and the like. As the sorting unit, a water droplet charging system is typically known.

  The sorting of cells (particles) by the water droplet charging method is based on, for example, the following principle. That is, the cells in which the scattered light and the fluorescent light are detected by the irradiation of the laser light are charged with a plus or minus electric charge just before the water stream containing the scattered light and the fluorescent light is divided into water droplets. When a water drop containing the charged cells is passed between two polarizing electrode plates having a potential difference during the drop, the water drop is attracted to the polarizing plate and deflected. Since the water droplets containing uncharged cells and the water droplets containing cells other than the desired cells fall vertically, water droplets containing only the desired cells can be separated and collected.

  However, such a technology using a cell sorter requires an ultrasonic generator for generating water droplets containing one cell (particles), and the cell sorter itself is of course very expensive, In addition, there are disadvantages that the maintenance is complicated, and that many kinds of fine particles cannot be separated at a time. That is, when an electrode plate is used, there is no other choice but to charge the cell positively or negatively, and there is a disadvantage that cells that can be electrically distinguished are limited to these two types. Furthermore, since the flow cell and the nozzle are reused, impurities may be mixed. In addition, when the cell solution is subjected to ultrasonic dropletization performed in the cell sorting, problems such as atmospheric pollution by harmful substances are involved.

  As described above, the cell sorter is particularly expensive, and can be operated at low cost without solving the disadvantages of too complicated operation and maintenance and the contamination of impurities. A technique has been proposed in which micro channels are formed on a substrate, and microparticles such as cells are placed in a water flow in the flow channel, and flow cytometry is performed to separate desired microparticles (a technique using a microchip). (See, for example, Non-Patent Documents 2 and 3).

  In cell sorting using this microchip, a T-shaped flow path is formed, and the direction of the solution that feeds the cells is switched between the cells to be sorted and the other cells (flow path selection control). ).

However, in the currently proposed method, the flow of the liquid can be switched only once, and therefore only one kind of fine particles can be separated. It is considered that multiple switching of the liquid flow can separate a plurality of fine particles, but in reality, the switching of the liquid flow is too slow in response time, and therefore, multiple liquid sending is required for the multiple switching. Pumps are required, and connection between them and the chip, switching of valves, and the like become too complicated, and practical use is considered to be difficult.
"Cell Engineering" separate volume, "Flow cytometry freely", supervised by Hiromitsu Nakauchi (Immunology, University of Tsukuba), Shujunsha, published July 1, 1999, pp. 3-23. Anne. Y. Fu, et al., "A microfabricated fluorescence-activated cell sorter", Nature Biotechnology, Vol. 17, November 1999, pp. 1109-1111. Anne Y. Fu, et al., "An Integrated Microfablicated Cell Sorter", Analytical Chemistry, Vol. 74, No. 11, June 1, 2002, pp. 2451-2457 JP-A-5-18887 JP-A-7-104191

  An object of the present invention is to improve and solve disadvantages found in conventional cell sorting techniques, such as the necessity of a device for generating water droplets and the inability to separate and collect a large number of target fine particles at once. To provide a sorting technique and a technique for separating and collecting fine particles therefor.

  The present inventor uses optical pressure (optical force or optical pressure) in place of the conventionally known flow cytometry, in particular, a sorting technique by a water droplet charging method, and a sorting technique by switching liquid flow (flow path selection control). For the first time in developing a fine particle sorting technology.

The present invention provides the invention described in the following items 1 to 13.
Item 1. By irradiating a gas or liquid flow path containing fine particles responsive to light pressure and components not responding to light pressure with a laser beam crossing the flow direction of the gas or liquid, the light pressure in the flow path is reduced. A method of selectively deflecting only the movement direction of fine particles responding to light in the direction of convergence of the laser beam to separate and collect the fine particles from components that do not respond to light pressure. Collection method.
Item 2. Item 4. The method according to Item 1, wherein the fine particles are selected from the group consisting of organic or inorganic polymer materials, metals, cells, microorganisms, and biopolymers that respond to light pressure.
Item 3. A laser beam is intersected in the flow direction of the gas or liquid with respect to the target microparticles responding to the light pressure in the flow path of the gas or liquid containing the fine particles responding to the light pressure and the component not responding to the light pressure. Irradiation selectively deflects only the direction of movement of the target particle in the flow path to the direction of convergence of the laser beam, and separates and collects the particle from other particles and components that do not respond to light pressure. A method for separating and collecting target microparticles, comprising:
Item 4. Item 4. The method for separating and collecting target fine particles according to Item 3, wherein the flow path is formed by a liquid flow.
Item 5. Item 4. The method for separating and recovering target fine particles according to Item 3, wherein the target fine particles are selected from the group consisting of organic or inorganic polymer materials, metals, cells, microorganisms, and biopolymers that respond to light pressure.
Item 6. Item 4. The method for separating and collecting target fine particles according to Item 3, wherein the target fine particles are cells or microorganisms.
Item 7. Flow cytometry, wherein the method for separating and collecting target microparticles according to item 6 is used as a method for sorting target microparticles.
Item 8. A collection unit for collecting fine particles responsive to light pressure, a laser beam irradiation unit, and between the collection unit and the laser beam irradiation unit, contain fine particles responsive to light pressure and components not responsive to light pressure. A particulate collection device having a flow path for flowing gas or liquid,
The recovery unit includes at least one chamber arranged with the opening facing the flow path side,
The laser beam irradiation unit includes at least one irradiation port,
From the laser beam irradiation port, a laser beam, crossing the flow path, toward the opening of the chamber of the recovery unit, is to be irradiated so as to converge behind the opening,
Particle collection device.
Item 9. Item 9. The fine particle collection device according to Item 8, wherein the opening of the chamber of the collection unit and the irradiation port of the laser beam irradiation unit are provided to face each other with a flow path therebetween.
Item 10. Item 9. The fine particle collection device according to Item 8, comprising a laser beam irradiation unit having two or more irradiation ports, and a collection unit having a number of chambers corresponding to the number of the irradiation ports.
Item 11. Item 9. The particle collection device according to item 8, further comprising a detection and analysis unit for detecting and analyzing particles in a gas or liquid flowing through the flow path.
Item 12. The detection and analysis unit works in conjunction with the laser beam irradiation unit, selects target particles based on the data obtained by the detection and analysis unit, and irradiates the laser beam only to the selected target particles. Item 12. The fine particle collection device according to Item 11, wherein
Item 13. Item 9. A cell sorter comprising the particle collection device according to item 8 as a sorting unit.

  The method for separating and collecting fine particles according to the present invention described in the above item 1-2 and the fine particle collecting device according to the present invention described in the item 8 utilize the light pressure of the laser beam, and the fine particles responding to the light pressure are used. As an object to be recovered, it can be recovered separately from components that do not respond to optical pressure (gas and liquid used as a channel medium are also included in the components).

  In addition, the method for separating and collecting target microparticles of the present invention described in the above section 3-6 and the cell sorter of the present invention described in section 13 are, for example, detection and analysis techniques employed in conventionally known flow cytometry and cell sorter. By selecting only target microparticles that respond to light pressure and irradiating a laser beam in the same manner as in paragraphs 1-2 and 8 above, only the target microparticles are converted to other components (including, Fine particles and components that do not respond to light pressure).

  According to these methods and devices of the present invention, particularly the methods and devices described in Items 3-6 and 13, various types of various methods can be used depending on differences in size and structure (physical properties) or differences in labeling substances. Arbitrary plural kinds of cells (target cells) can be separated and collected from a variety of cell populations having properties and functions in a living state without destruction or other damage. Therefore, the method and apparatus of the present invention are useful as assistive technologies such as cloning of specific cells and cloning of growth / differentiation factor receptor genes. Further, it can be effectively used for analysis of various functions of cells and analysis of cell dynamics such as cell membrane molecules and chromosomal DNA molecules. Further, the present invention can be effectively used not only in the field of cell engineering but also in the clinical field, for example, for the analysis of particles in urine.

  Further, the device of the present invention can be in the form of a microchip, and the method of the present invention can be easily and simply performed using such a microchip. That is, there is an advantage that an expensive and complicated operation is not required as compared with the conventional FACS or the like.

  Moreover, if the device of the present invention is used, a plurality of types of fine particles, which were difficult with the technology of performing fluid control using a conventionally proposed microchip, can be very quickly (with a high response speed) in one operation. , Can be accurately and efficiently distinguished. In particular, the use of the apparatus of the present invention has an advantage that the above-mentioned fine particles can be easily discriminated by using a small amount of sample, as compared with a conventional technique of performing fluid control using a microchip.

(1) Method for Separating and Collecting Fine Particles Hereinafter, the method for separating and collecting fine particles of the present invention will be described in detail.

  In the method of the present invention, first, a gas or liquid flow path containing fine particles responding to optical pressure is irradiated with a laser beam so as to intersect the flow direction of the gas or liquid, and the fine particles to be collected flowing through the flow path are collected. By deflecting the direction of movement of the laser beam in the direction of convergence of the laser beam.

  The principle is as follows. That is, when fine particles responding to light pressure flow into the irradiation area of the irradiated laser beam, a non-uniform light field is generated in the irradiation area. Due to differences in refractive index, dielectric constant, and the like, there is a difference in light power (radiation pressure of light, dielectrophoretic force, etc.) acting on this. This difference in force causes the particles responsive to the light pressure to move along the axial direction of the beam against the hydrodynamic flow direction, towards a tight location in the light field. This force is called an optical force. This light pressure increases as the difference in the refractive index (or dielectric constant) between the fine particles and the substance surrounding the fine particles increases, and increases as the volume of the fine particles increases. For example, a liquid in which polystyrene fine particles (for example, having a diameter of 1 μm), microorganisms such as Escherichia coli, or cells thereof are suspended in water, generally generates a large light pressure.

  Heretofore, there has been an example in which such a principle is applied to a laser trapping technique for capturing fine particles (see Patent Document 1, Patent Document 2, etc.).

  However, the known laser trapping technology is a technology that captures fine particles only at the focal position of the laser beam narrowed down by a lens, and deflects the moving direction (flow direction) of the fine particles by the technology to collect the fine particles. That is, an attempt to irradiate a laser beam onto the flow path of the fine particles so as to deflect the fine particles against the flow direction thereof and to deflect the fine particles in the traveling direction of the beam has not been known so far.

  In fact, for example, the technology described in Patent Document 1 described above is nothing more than a method of storing a suspension of fine particles in a chamber such as a slide glass and irradiating a laser beam to the fine particles to be sampled in the suspension. . The captured fine particles are oriented in an electric field direction by electrostatic force, and then transported by moving a laser beam or a chamber. The technique described in Patent Document 2 also relates only to a device that traps fine particles with a laser beam and controls the position and orientation (posture) thereof. In either case, the moving direction of the fine particles is deflected by the light pressure of the laser beam, and the fine particles are not moved in the convergence direction of the laser beam.

  In the method of the present invention, as described above, the gas or liquid flowing in the flow channel may be any as long as it contains fine particles to which light pressure acts (responds to light pressure). That is, the gas or liquid flowing in the flow path may be any as long as it contains fine particles responsive to light pressure and components not responsive to light pressure. Note that the gas or liquid used as a medium is included in the components that do not respond to the light pressure described above. Fine particles contained in a gas or a liquid may be different from a medium such as a gas or a liquid in terms of refractive index, dielectric constant, and the like, so long as they cause a difference in optical pressure. Representative examples of the fine particles include cells, microorganisms, and biopolymer substances. Cells include animal cells (such as red blood cells) and plant cells. Microorganisms include bacteria such as Escherichia coli; viruses such as tobacco mosaic virus; fungi such as yeast. Biopolymers include chromosomes, liposomes, mitochondria, and organelles (organelles) that constitute various cells.

  The fine particles responsive to light pressure to which the method of the present invention can be applied are not limited to those exemplified above, and various fine particles known to be trapped by a laser trapping technique, for example, organic or inorganic polymer materials , Metal or the like. Organic polymer materials include polystyrene, styrene / divinylbenzene, polymethyl methacrylate, and the like. Inorganic polymer materials include glass, silica, magnetic materials, and the like. Metals include colloidal gold, aluminum and the like.

  Preferably, the microparticles typically have a particle size on the order of nanometers to micrometers, more specifically, a particle size of about 20 nm-50 μm. The shape, size, mass and the like are not particularly limited. Generally, the shape is generally spherical, but may be non-spherical.

In general, the fine particles can be mixed with a medium such as a gas or a liquid, and can be flown in the flow path in a gas or liquid state. Examples of the medium for forming the gas stream or the liquid stream include various gases and liquids used in the conventional laser trapping technology. As a preferable medium (liquid medium) for forming the liquid flow, pure water, PBS (phosphate buffered saline) and the like can be exemplified. The medium preferably has a refractive index or the like smaller than that of the microparticles in relation to the microparticles that respond to light pressure (in this sense, in the present invention, a component that does not respond to light pressure). ). As a particularly preferable liquid flowing through the flow channel, a suspension or the like in which cells are mixed or suspended in the above-mentioned liquid medium can be exemplified. The number of cells in the liquid stream is not particularly limited, but is generally about 1 × 10 ⁵ to 1 × 10 ⁷ cells / ml. The flow velocity can be appropriately determined according to the type of the fine particles, the type of the laser beam to be irradiated thereon, and the like, assuming that the flow direction can be deflected to the convergence direction of the laser beam by the irradiation of the laser beam.

  In the method of the present invention, the laser beam used may be the same as those used in the conventional laser trapping technology in its kind, irradiation conditions and the like. As typical laser beams, for example, a Nd: YAG (neodymium-doped yttrium aluminum garnet) laser beam (wavelength: 1064 nm), an Nd: VAN (neodymium-doped vanadate) laser beam (wavelength: 1064 nm), or the like can be used. This laser beam is particularly suitable because it has little effect on living things. As the irradiation condition, specifically, a condition of 100 mW to 2 W in CW (continuous wave) can be used. Irradiation with a laser beam can be performed intermittently or continuously.

  In the present invention, it is important that the laser beam is irradiated so as to intersect with the flow direction of the gas or liquid containing fine particles. By this irradiation, the particles in the gas stream or liquid stream are deflected in the traveling direction (converging direction) of the laser beam, with the direction of movement opposite to the gas or liquid flow direction, and there is no component that does not respond to light pressure. It can be collected separately. For example, if an appropriate collection chamber is arranged with the opening facing the flow path side in the direction of convergence of the laser beam, only the target fine particles are selectively collected and accumulated in the chamber (concentration).

  In general, the laser beam irradiation is preferably performed in a direction perpendicular to the direction of the air flow or the liquid flow. However, as long as the direction intersects with the direction of the air flow or the liquid flow, that is, the direction in which the fine particles flow is deflected. As far as is possible, the angle is not particularly important.

  When targeting a plurality of fine particles having different characteristics in response to light pressure, for example, a plurality of the collection chambers are arranged in parallel, and a plurality of laser beams are irradiated toward the opening of each chamber. Thereby, each of the target fine particles (target fine particles) can be collected in a separate chamber.

(2) Method for Separating and Collecting Target Microparticles The above-described method for separating and collecting microparticles according to the present invention can be applied to, for example, a flow cytometry sorting method. That is, the method of the present invention can be replaced with a conventional water droplet charging method as a sorting unit in flow cytometry. According to flow cytometry using the method of the present invention, only desired fine particles (target fine particles) can be selectively separated and collected (sorting).

  Flow cytometry (cell sorting, FACS) to which the method of the present invention is applied can be performed, for example, as follows.

  That is, for a sample (gas or liquid) containing fine particles (fine particles responding to light pressure) to be collected, scattered light (forward) is obtained by performing the same operation as the operation in the known flow cytometry detection unit and analysis unit in advance. Scattered light, side scattered light) and fluorescence are detected and analyzed. Next, the sample containing the fine particles (gas or liquid) is caused to flow through the flow channel according to the method of the present invention, crosses the flow of the gas or liquid, and passes through the flow channel to the desired fine particles to be recovered (target fine particles). By selectively irradiating a laser beam, only the target fine particles are deflected in the direction of movement of the laser beam, and collected separately from other fine particles and components that do not respond to light pressure.

  Preferred specific examples of the target fine particles include cells to which an antibody labeled with a fluorescent dye or the like is bound (coated) according to general FACS, and a biopolymer similarly labeled with a fluorescent dye or the like. These selections can be performed according to conventional FACS. For example, by irradiating an argon laser, the intensity and wavelength of the fluorescence or the intensity of the scattered light are detected, and the obtained detection result (data) is analyzed to determine the specific fluorescence intensity and the wavelength and the scattered light of the target fine particles. Fine particles having strength or the like can be selected.

  In addition, various test subjects present inside or on the surface of the cell, for example, proteins expressed in the cells, using two or more fluorescent dyes or luminescent proteins such as GFP (Green fluorescent protein, green luminescent protein) By performing multiple dyeing, a plurality of types of fine particles emitting a desired emission wavelength can be simultaneously selected as target fine particles. These operations can be the same as the respective operations in the detection unit and the analysis unit of a conventionally known flow cytometry or cell sorter (for example, see Non-Patent Document 1).

  The sorting method of the present invention is a method in which a minute amount of a solution is used as a sample flowing through a flow channel, and it is a method capable of detecting and separating and collecting fine particles in the sample, for example, an immunodetection system utilizing an antigen-antibody reaction. It can be suitably applied. In this case, by labeling the antibody to be used with a fluorescent substance in advance, micrometer-sized fine particles generated by an immune reaction such as an antigen-antibody reaction are selectively guided from a channel to a chamber by laser beam irradiation. By measuring the fine particles separated and collected in the chamber and accumulated (concentrated), an immunoreactant can be detected with high sensitivity. In particular, by using different fluorescent substances according to the type of antibody used in this method, different types of antigen-antibody reactants (i.e., different cells etc.) can be separated and collected at the same time based on the difference in fluorescence intensity and wavelength. And can be analyzed (multiplex detection).

  In the case where the fluorescent label is not used, beads having different sizes depending on the type of the antibody can be used instead of the fluorescent substance. In this case, after coating the beads with an antibody, the antibody is mixed with a sample sample such as blood to cause an immunoreaction, and when a liquid containing the obtained reactant (fine particles) is used as a sample flowing through a flow path, the fine particles are used. Based on the difference in the sizes of different antigen-antibody reactants (that is, different cells, etc.) at the same time, they can be separately collected and analyzed.

(3) Particle collection device The particle collection device of the present invention includes a collection unit for collecting fine particles responsive to light pressure, a laser beam irradiation unit, and a light pressure unit between the collection unit and the laser beam irradiation unit. And a flow path for flowing gas or liquid containing fine particles responsive to the pressure and components not responding to the light pressure. The recovery section has at least one chamber arranged with the opening facing the flow path side, and the laser beam irradiation section has at least one irradiation port. Further, the irradiation of the laser beam from the laser beam irradiation port is performed toward the opening of the chamber of the collection section, crossing the flow path, and the laser beam is converged farther from the opening of the chamber of the collection section. Is done as follows.

  FIGS. 1 and 2 are schematic diagrams of a fine particle recovery apparatus according to one embodiment of the present invention. FIGS. 1 and 2 are schematic diagrams of a device of the present invention in the form of a microchip for collecting fluorescent latex beads (about 2 μm in diameter) described in detail in Examples below. FIG. 1 (a) is a front view of the particle collection device. FIG. 1 (b) is an enlarged view of a portion surrounded by a dotted line in FIG. 1 (a) .In addition, a laser beam (3b) is emitted from an irradiation port (3a) of a laser beam irradiation section (3). It shows a state of irradiation.

  FIG. 7 is an image view of the flow channel (2) and the collection unit (1) of the particle collection apparatus of the present invention shown in FIGS. 1 and 2 taken from the front. In FIG. 7, in order to facilitate understanding, red ink is passed through the channel (2). The red spots on the right and left sides are the channel inlet (5) and the channel outlet (6), respectively, and the red line connecting them is the channel (2). As shown in FIG. 1 (a), the fine particle collection device (chip) has a hole serving as a channel inlet (5) and a channel outlet (6) on a 5 mm thick PDMS substrate (60 mm × 24 mm, 5 mm thick). And a groove having a width of 50 μm and a depth of 25 μm is created so as to connect them (this will be the flow path (2)). Further, a groove having a width of 35 μm × a depth of 35 μm and a depth of 25 μm is formed so as to be perpendicular to the groove (this becomes the chambers (1a, 1b)). Next, a 100 μm-thick PDMS film (60 mm × 24 mm, 5 mm thickness) is attached so as to cover the groove from above the substrate. Thus, a flow path (flow path (2)) and a recovery section (recovery chambers (1a, 1b)) of the fine particle recovery apparatus are formed.

  The particle collection apparatus of the present invention shown in each figure has a particle collection section (1 in FIG. 1 (b)) having two chambers (1a and 1b in FIG. 1 (b)), and one irradiation port (FIG. (b), a laser beam irradiation section having 3a) (3 in FIG. 1 (b)), and a flow path (FIG. 1) between the particle collection section (1) and the laser beam irradiation section (3). In (b), 2) is provided. The irradiation port (3a) is disposed so as to face the opening of the chamber (1a) of the fine particle collection unit via the flow path (2), so that the laser beam enters the chamber from the opening. It has become. Further, the gas or liquid sample containing the target microparticles to be collected enters the flow channel (2) through the flow channel inlet (5) from a in FIG. It is designed to flow from 5) in the direction of the channel outlet (6), and then to be discharged from the channel outlet (6) to b. In addition, in FIG. 1 (b), (4) is an outer wall constituting a bottom surface of the particle collection device. A flow path (2) is formed between the outer wall and the particulate collection section (1).

  The fine particle collecting section shown in FIG. 1 has chambers (1a, 1b) having a volume of 35 μm × 25 μm (area of bottom or opening) × 35 μm (length from opening to bottom, depth). However, the volume and opening size of the chamber provided in the particle collection section of the apparatus of the present invention are not limited thereto, and the purpose of use of the particle collection apparatus, the size of the collection section, and collection in one chamber are desired. It can be appropriately selected and set according to the size and amount of the fine particles, the diameter of the laser beam to be irradiated, and the like. The channel (2) shown in FIG. 1 has a cubic channel diameter with a cross-sectional area of 50 μm × 25 μm. However, the cross-sectional shape and the cross-sectional area (in other words, the flow path diameter) of the flow path (2) of the device of the present invention are not limited thereto, and are not limited to gas and liquid flowing through the flow path, and the size of the fine particles. It can be appropriately selected and set according to the conditions.

  The collection of fine particles by the fine particle collection device is performed, for example, as follows. First, a gas or liquid sample (preferably a liquid sample) containing target microparticles to be collected is flowed from the channel inlet (5) to the channel outlet (6) into the channel (2). While the sample is flowing through the flow path (2), a laser beam (3b) is irradiated from the irradiation port (3a) so as to be focused into the chamber (1a). Then, the laser beam emitted from the irradiation port (3a) is applied to the channel (2) in which the gas or liquid sample containing the target fine particles to be collected flows. At this time, when the target fine particles enter the laser beam irradiation area of the flow path (2), the target fine particles are affected by the light pressure of the laser beam, and the traveling direction of the target fine particles is deflected toward the chamber (1a). Then, it is collected in the chamber (1a).

  FIG. 2 is a diagram illustrating the laser beam irradiation unit (3) in the particle collecting apparatus shown in FIG. 1 in more detail. However, the particle collecting apparatus having the laser beam irradiation unit (3) shown in FIG. 2 is one embodiment of the present invention, and the present invention is not particularly limited thereto. In FIG. 2, (7) is Nd: VAN leather, (8) is a beam expander, (9) is a reflection mirror 1, (10) is a dichroic mirror 2, (11) is a dichroic mirror 1, and ( 12) shows the objective lens 1 respectively. (13) shows a mercury lamp, (14) shows a neutral-density filter (ND filter), and (15) shows a barrier filter for excitation. Further, (16) shows a fluorescence barrier filter, (17) shows a reflection mirror 2, (18) shows a laser beam cut filter, and (19) shows a CCD camera 1.

  According to the embodiment shown in FIG. 2, the laser beam emitted from the laser beam irradiation source Nd: VAN laser (7) has its beam diameter adjusted by the beam expander (8) positioned in the forward direction of the laser beam. You. Next, the laser beam is bent by the reflection mirror 1 (9), the dichroic mirror 2 (10), and the dichroic mirror 1 (11), passes through the objective lens 1 (12), and passes through the irradiation port (3b ) Is applied to the opening of the chamber (1a) of the particle collection unit. By doing so, the laser beam (3b) from the Nd: VAN laser (7) can be focused on the chamber (1a).

  At this time, it is preferable to adjust so that the laser beam is converged far from the opening of the chamber, preferably near the bottom of the chamber. The convergence of the laser beam can be performed, for example, by using an objective lens as described above. The objective lens 1 (12) in FIG. 2 is freely movable up and down, and it is possible to adjust the convergence position of the laser beam up and down by the movement. Note that, as described above, the convergence position of the laser beam only needs to be farther from the opening of the chamber of the fine particle collection unit (1). It does not matter whether inside or outside the chamber as long as it is far from the opening. Preferably, near the bottom of the chamber, both inside and outside the chamber.

  Here, the laser beam used is generally a circular laser beam, but is not particularly limited thereto, and may be an elliptical laser beam or the like.

  As a preferred embodiment of the device of the present invention, as shown in FIG. 1, there is an embodiment in which an opening of a chamber of a particle collection unit and an irradiation port of a laser beam irradiation unit are provided to face each other with a flow path therebetween. it can. According to this aspect, the laser beam is incident so as to be perpendicular to the flow path, in other words, the flow of the gas or liquid containing the target fine particles (air flow or liquid flow). However, without being limited to this, if the laser beam intersects the flow path and enters the opening of the chamber of the particle collection unit, the irradiation of the chamber of the particle collection unit and the irradiation port of the laser beam irradiation unit is performed. The arrangement can be set arbitrarily.

  Further, as another preferred embodiment of the present invention, there is provided a laser beam irradiation unit having two or more irradiation ports, and a fine particle collection unit having a plurality of chambers corresponding to the number of irradiation ports. Examples can be given. According to such an apparatus, a plurality of target fine particles responding to light pressure can be separately collected in separate chambers.

  FIG. 3 shows a schematic diagram of an example of such a multiplex sorting apparatus. In the figure, (101) indicates a reservoir containing a liquid or gas sample containing target fine particles to be collected. In the figure, (104-1), (104-2), (104-3), ... and (104-n) are fine particle collection chambers ((104-1a), (104-2a), (104-3a),... And (104-na)] (corresponding to the particle collection unit (1) and the chambers (1a, 1b) in FIG. 1). Reference numeral (105) denotes a laser beam controller including a laser beam irradiation unit (corresponding to the laser beam irradiation unit (3) in FIG. 1). Here, corresponding to the number of the plurality of irradiation ports ((105-1), (105-2), (105-3), ... and (105-n)) provided in the laser beam irradiation unit , The fine particle collection unit also includes a plurality of chambers ((104-1a), (104-2a), (104-3a),... And (104-na)). (2) is a channel through which the sample flows, and (106) is a drainage reservoir for collecting the same.

  The particle collecting apparatus of the present invention in this aspect is for detecting and analyzing particles responding to the light pressure in gas or liquid flowing through the flow path, in addition to the laser beam irradiation unit, the fine particle collection unit and the flow path described above. It is preferable to provide a detection and analysis unit. In this case, with respect to the detection and analysis unit, the device portion including the laser beam irradiation unit, the fine particle collection unit, and the flow path can be referred to as a sorting unit. The one provided with the sorting unit and the detection and analysis unit is a cell sorter. In FIG. 3, (102) and (103) correspond to a detection unit, (102) indicates a detection laser, and (103) indicates a detector. In FIG. 3, the analysis unit is incorporated in a laser controller indicated by (105).

  Here, the detection and analysis unit can be the same as the detection and analysis unit used in conventionally known flow cytometry or cell sorter. For example, the detection unit, a sample (liquid sample or gas sample, preferably a liquid sample) flowing in the flow channel (liquid flow, air flow) laser light (e.g., argon, diode, die, single helium neon, etc.) laser or Dual laser), obtained from the microparticles passing through the flow path, forward scattered light (FSC) or side scattered light (SSC), or, if the target microparticles are previously labeled with a fluorescent substance, the fluorescence It can be provided with a detector for measuring various kinds of fluorescence of the labeled fine particles. Further, the analysis unit may include an analysis display device for digitally converting the data detected by the detector and displaying the data as a cytogram or a histogram. The forward scattered light (FSC) changes in light intensity, for example, reflecting the size of a cell, and the side scattered light (SSC) changes in light intensity, for example, reflecting the complexity of the internal structure of the cell. Fluorescent substances used for labeling target microparticles by flow cytometry or cell sorter are also well known, and can be used in the present invention in the same manner (for example, see Non-Patent Document 1).

  According to a preferred aspect of the fine particle collection device of the present invention, in the device, the detection unit and the analysis unit are interlocked with the laser beam irradiation unit in the sorting unit, and are obtained in the detection unit and analyzed in the analysis unit. Based on the data, a design is made such that the laser beam is selectively applied to the target microparticle only when the selected target microparticle flows into the irradiation area of the flow channel.

  Utilizing such a preferred particle collection device of the present invention, one or two or more of samples (gas sample or liquid sample) containing a plurality of fine particles responding to light pressure, depending on the characteristics of each fine particle. The target microparticles can be selectively separated and separately collected.

  For example, a method for separating and collecting target microparticles using the apparatus of the present invention shown in FIG. 3 will be described as an example as follows.

  Each of a plurality of different target microparticles (e.g., cells, microorganisms, proteins, etc.) is bound to each of the fluorescently labeled antibodies by an immunoreaction such as an antigen-antibody reaction, and a sample solution containing these (e.g., a suspension of cells or the like) is nozzled. By irradiating a laser beam at a high flow rate and irradiating a laser beam, scattered light and fluorescence are emitted from the target fine particles passing through the liquid flow. The light intensity, the fluorescence wavelength, and the like are measured by the detection unit, and the obtained result is analyzed by the analysis unit. Then, based on the obtained information (data), the laser controller (105) determines the irradiation position and timing of the laser beam, etc., and when the target fine particles pass through the flow path (2), selectively apply to the target fine particles. Is irradiated with a laser beam. The target microparticles irradiated with the laser beam are deflected by the light pressure in the flow direction, and are collected in the chamber of the collection unit. Thus, even when there are a plurality of target microparticles to be collected, based on the difference in the intensity or wavelength of the scattered light or fluorescence emitted by the collection, the collection unit (104-1) ... (104-n) can be collected in each chamber. The fine particles (e.g., cells, microorganisms, proteins, etc.) collected in each chamber are subjected to detection of an immune reaction in the chamber, or the fine particles accumulated in each chamber are taken out and separately subjected to biochemical analysis according to a conventional method. Immunoassay can also be performed by subjecting it to a quantitative analysis.

  In the above, it is possible to prepare laser beam irradiation ports as many as the number of collection chambers, but instead, use a known laser operation technology to change the direction of one laser using a polygon mirror etc. It is also possible to scan and control the laser irradiation position and timing.

  The collection of the individual target particles is performed as a result of deflecting the flow direction of the target particles by the light pressure of the laser beam emitted from the laser beam irradiation port. The position where the flow direction of the target fine particles is deflected can be controlled by controlling the laser beam irradiation port, or by moving the collection section or its chamber position while keeping the position of the irradiation port fixed. it can.

  The apparatus shown in FIG. 3 can be applied to a case where cells having a plurality of pieces of fluorescence information are collected in separate chambers for each piece of fluorescence information (multi-sorting). In this case as well, the analysis of each cell collected in each chamber can be performed in the chamber, or can be taken out of the chamber and analyzed. By utilizing such an apparatus of the present invention, a plurality of different cells can be simultaneously separated and collected by one apparatus (for example, one chip in the case of a chip form).

  As described above, the collection method and apparatus of the present invention can collect fine particles responsive to light pressure in a desired collection chamber by deflecting and moving them in the direction of convergence of the laser beam by utilizing light pressure. You can do it. In addition, the method and apparatus can also use a conventional flow cytometry or cell sorter detection and analysis techniques to select desired target microparticles from a plurality of microparticles that respond to light pressure. (Multiple fractional collection). The light pressure used in the present invention itself is easily controllable, and the use thereof has an advantage that the apparatus of the present invention and its peripheral devices can be simplified. Furthermore, in the fine particle sorting technology using the method and the device of the present invention, there is no need for fluid control such as forming water droplets as in a conventional water droplet charging method, and the desired fine particles can be easily sorted using a small amount of sample. Can do.

  Hereinafter, examples will be given to explain the present invention in more detail.

Example 1
(1) Test Method For this test, the particle recovery apparatus (microchip form) of the present invention shown in FIGS. 1 and 2 was used.

  The particle collecting section (1) provided on the chip has two micro gloves (35 μm × 35 μm × 25 μm, chambers (1a) and (1b)) for collecting fine particles. The microchannel (50 μm width × 25 μm depth, channel (2)) through which the sample containing fine particles flows is partitioned from the outside by an outer wall (4) (made by PDMS). In consideration of the working distance of the objective lens 1 (12 in FIG. 2), the outer wall (4) is set so that the Nd: VAN laser beam (wavelength: 1064 nm) converges near the bottom of the chamber (1a) (micro globe). Was 300 μm in thickness.

  An inverted fluorescence microscope (Axiovert 135TV, Carl Zeiss) was used for this test in combination with a laser manipulation system. The laser beam emitted from the Nd: VAN laser (7) was condensed using the microscope objective lens (12) facing the outer wall (4), and was introduced into the chamber (1a). The beam diameter was adjusted by inserting a beam expander (8) into the laser beam path, so that the laser focus and the observation plane were matched with the same objective lens.

  Further, to observe the behavior of the fine particles flowing through the flow path (2), in order to take a fluorescent image of the fine particles, another objective lens 2 (20) and a color CCD camera 2 (21), was installed in the horizontal direction . By the CCD camera 2 (21), an image of the fine particles introduced into the chamber (1a) while changing the traveling direction from the flow path (2) can be captured. Further, a CCD camera 1 (19) was arranged so that the collected fine particles in the chamber could be photographed from below.

In this test, fluorescent latex beads (Polysciences, Inc.) having a diameter of 2 μm were used as fine particles responding to light pressure. A liquid in which the fine particles were suspended in ultrapure water at a concentration of 1 × 10 ⁵ particles / ml was used as a sample liquid. The sample liquid was introduced into the flow channel (2) from the flow channel inlet (5) through (a) using a syringe pump (syringe feeder). The speed of the sample liquid flowing in the flow path (2) was 192 μm / sec. The sample liquid passed through the flow path (2) was recovered from the flow path outlet (6) to (b).

  The laser beam (3b) was focused on one (1a) of the two chambers (1a, 1b). This chamber (1a) was used as a chamber for collecting fine particles, and the other (1b) was used as a negative control chamber.

(2) Results FIG. 4 shows a spot of a specific fluorescent latex bead A followed by movement in the flow channel. In FIG. 4, black arrows (indicating the upward direction) indicate the position and irradiation direction of the laser beam irradiation light, and white arrows indicate the position and movement direction of the bead A. From this figure, the beads A (see (a) in FIG. 4; this is assumed to be t = 0) flowing along the liquid flow in the flow channel come to the laser beam irradiation area (see FIG. 4). (b), t = 0.13), the direction of motion is deflected in the beam traveling direction (see (c) of FIG. 4, t = 0.17), and it can be seen that it enters the chamber of the recovery unit ((d) of FIG. 4). ), T = 0.21). That is, when the 2 μm fluorescent beads flowing through the flow path enter the irradiation area of the Nd: VAN laser beam (1600 mW), they oppose the flow caused by hydrodynamic force and gravity, and along the optical axis of the beam by light pressure. It is deflected and moves in the direction of convergence of beam irradiation, and is collected in the chamber.

  In this method, specific target microparticles can be selected and collected in individual chambers depending on whether or not a laser beam is applied.

  In order to confirm the optical recoverability in this method, it was examined whether or not the fluorescent latex beads passing through the channel could be collected and accumulated (concentrated) in the chamber over time. That is, laser beam irradiation was continuously performed, and the fluorescence intensity in the chamber (1a) (35 μm × 35 μm × 25 μm) was measured over time. The results obtained are shown in FIG.

  The fluorescence intensity was measured using an image analysis software (NIH image: http://rsb.info.nih.gov/nih-image/) after capturing the image recorded on the videotape into a computer. Was determined by analyzing the fluorescence intensity of each video frame (30 frames / second). The value indicates a relative value (a.u. in FIG. 5 is an abbreviation for arbitrary unit).

 FIG. 5 shows elapsed time (seconds) (laser beam irradiation time) on the horizontal axis and the above-mentioned fluorescence intensity (unit: au) on the vertical axis, and describes the transition of the fluorescence intensity in the chamber (1a) over time. It is a graph.

  As is clear from the results shown in FIG. 5, the fluorescence intensity in the chamber (1a) increases in proportion to time over 90 seconds. From this, it can be seen that by continuously irradiating the laser beam, the flow of the target fine particles passing through the flow path is deflected toward the chamber by light pressure, and the target fine particles can be collected and accumulated (concentrated) in the chamber. .

  The photographing result by the CCD camera after 90 seconds is as shown in FIG. In FIG. 6, (a) shows the collection chamber (1a), and (b) shows the collection chamber (1b). “White arrow flow” indicates the flow direction of a liquid (sample liquid) containing fluorescent latex beads in the flow channel, and the black arrow indicates the direction of laser beam irradiation.

  As shown in FIG. 6, the chamber (1a) was filled with fluorescent beads to about 1/3 of its volume. On the other hand, in the negative control chamber (chamber (1b)) in which the light pressure of the laser beam did not act, no fluorescence was observed, and it was confirmed that latex beads were not recovered. The results confirm that a series of collections and enrichments occur based on the deflection and movement of the microparticles due to light pressure (by laser beam irradiation).

  The present invention provides a method and an apparatus for collecting fine particles such as cells, and a flow cytometer and a cell sorter using the same.

  The recovery method and apparatus of the present invention are useful as support technologies such as cloning of cells and cloning of growth / differentiation factor receptor genes. It is also useful for analyzing various functions of cells and analyzing cell dynamics such as cell membrane molecules and chromosomal DNA molecules. Further, the present invention can be effectively used not only in the field of cell engineering but also in the clinical field, for example.

FIG. 1 is a schematic view showing one embodiment (example) of the fine particle recovery device of the present invention. (a) is a front view of a part of the particulate collection device (a collection unit and a flow path), and (b) is an enlarged view of a part surrounded by a dotted line in (a). FIG. 2 is a schematic diagram illustrating a laser beam irradiation unit of the particle collection device shown in FIG. 1 in more detail. FIG. 1 is a schematic view showing one embodiment of the fine particle collection device (multiplex sorting device) of the present invention suitable for multiplex recovery and multiplex detection. FIG. 9 is an image diagram showing the results of the test performed in Example 1 (a state in which fluorescent latex beads A are collected in a collection chamber by being irradiated with a laser beam is photographed with time). 5 is a graph showing a change in fluorescence intensity in the collection chamber, showing that fine particles are collected and accumulated over time in the collection chamber in the test performed in Example 1. FIG. 4 is an image diagram showing a photograph of a collection chamber and a negative control chamber 90 seconds after laser beam irradiation in the test performed in Example 1. FIG. 2 is an image diagram corresponding to FIG. 1 (a), showing a part (a flow path and a collecting section) of the fine particle collecting apparatus, as viewed from the front.

Explanation of reference numerals

(1) Particle collection unit
(1a), (1b) Chamber provided in the particle collection unit
(2) Channel
(3) Laser beam irradiation section
(3a) Laser beam irradiation port
(3b) Laser beam

Claims (13)

By irradiating a gas or liquid flow path containing fine particles responsive to light pressure and components not responding to light pressure with a laser beam crossing the flow direction of the gas or liquid, the light pressure in the flow path is reduced. A method of selectively deflecting only the movement direction of fine particles responding to light in the direction of convergence of the laser beam to separate and collect the fine particles from components that do not respond to light pressure. Collection method. 2. The method according to claim 1, wherein the fine particles are selected from the group consisting of an organic or inorganic polymer material responsive to light pressure, a metal, a cell, a microorganism, and a biopolymer. A laser beam is intersected in the flow direction of the gas or liquid with respect to the target microparticles responding to the light pressure in the flow path of the gas or liquid containing the fine particles responding to the light pressure and the component not responding to the light pressure. Irradiation selectively deflects only the direction of movement of the target particle in the flow path to the direction of convergence of the laser beam, and separates and collects the particle from other particles and components that do not respond to light pressure. A method for separating and collecting target microparticles, comprising: 4. The method for separating and recovering target fine particles according to claim 3, wherein the flow path is formed by a liquid flow. 4. The method for separating and collecting target microparticles according to claim 3, wherein the target microparticles are selected from the group consisting of organic or inorganic polymer materials, metals, cells, microorganisms, and biopolymers that respond to light pressure. 4. The method for separating and collecting target microparticles according to claim 3, wherein the target microparticles are cells or microorganisms. 7. Flow cytometry, wherein the method for separating and collecting target microparticles according to claim 6 is used as a method for sorting target microparticles. A collection unit for collecting fine particles responsive to light pressure, a laser beam irradiation unit, and between the collection unit and the laser beam irradiation unit, contain fine particles responsive to light pressure and components not responsive to light pressure. A particulate collection device having a flow path for flowing gas or liquid,
The recovery unit includes at least one chamber arranged with the opening facing the flow path side,
The laser beam irradiation unit includes at least one irradiation port,
From the laser beam irradiation port, the laser beam, crossing the flow path, toward the opening of the chamber of the recovery unit, is to be irradiated so as to converge farther from the opening,
Particle collection device. 9. The particle collection device according to claim 8, wherein an opening of a chamber of the collection unit and an irradiation port of the laser beam irradiation unit are provided to face each other with a flow path therebetween. 9. The fine particle collection device according to claim 8, further comprising a laser beam irradiation unit having two or more irradiation ports, and a collection unit having a number of chambers corresponding to the number of the irradiation ports. 9. The fine particle collection device according to claim 8, further comprising a detection and analysis unit for detecting and analyzing fine particles in a gas or a liquid flowing through the flow path. The detection and analysis unit works in conjunction with the laser beam irradiation unit, selects target particles based on the data obtained by the detection and analysis unit, and irradiates the laser beam only to the selected target particles. 12. The fine particle recovery device according to claim 11, wherein 9. A cell sorter comprising the particle collection device according to claim 8 as a sorting unit.