JP6323550B2 - Operation method of magnetic particles - Google Patents

Description

  The present invention relates to a method for operating magnetic particles for selectively fixing a target substance in a sample to the surface of the magnetic particles. The present invention also relates to a magnetic particle manipulation device used in the method.

  In medical examinations, food safety and hygiene management, monitoring for environmental protection, etc., it is required to extract a target substance from a sample containing a wide variety of contaminants and to use it for detection and reaction. For example, in genetic testing, it is necessary to efficiently extract DNA and RNA from biological samples such as blood, serum, cells, urine, feces, etc. of animals and plants, and viruses before the target nucleic acid is amplified by PCR or the like. is there.

  In order to extract and purify the target substance in the sample, the magnetic particles have a chemical affinity with the target substance and a molecular recognition function on the surface of the magnetic substance having a particle size of about 0.5 μm to several tens of μm. A method of using has been developed and put into practical use. In this method, after fixing the target substance on the surface of the magnetic particles, the magnetic particles are separated and recovered from the liquid phase by a magnetic field operation. If necessary, the recovered magnetic particles are separated into a liquid phase such as a cleaning liquid. And the step of separating and collecting the magnetic particles from the liquid phase is repeated. Thereafter, the magnetic particles are dispersed in the eluate, whereby the target substance fixed to the magnetic particles is released into the eluate, and the target substance in the eluate is recovered. By using magnetic particles, it is possible to recover the target substance with a magnet, which eliminates the need for centrifugation, which is advantageous for automated chemical extraction and purification.

  Magnetic particles capable of selectively fixing a target substance are commercially available as part of a separation / purification kit. The kit contains multiple reagents in separate containers, and the user dispenses and dispenses the reagent with a pipette when using it. Devices for automating these pipette operations and magnetic field operations are also commercially available (for example, Patent Document 1). On the other hand, instead of pipetting, a tubular device in which an aqueous liquid layer such as a dissolving / fixing solution, a washing solution, and an eluent and a gel-like medium layer are alternately layered is used. A method for separating and purifying a target substance by moving it in the longitudinal direction has been proposed (for example, Patent Document 2). When such a tubular device is used, since a series of operations can be performed in a closed system, the risk of contamination is reduced compared to pipetting operations performed in an open system.

WO97 / 44671 International Publication Pamphlet WO2012 / 086243 International Publication Pamphlet

  In both pipetting operations and operations using gel-encapsulated devices, the separation and purification using magnetic particles fixes the target substance to the surface of the magnetic particles, and contaminants attached to the surface of the magnetic particles. In order to bring the surface of the magnetic particles into sufficient contact with the liquid at each stage of washing and removing such as and elution of the target substance, it is necessary to disperse the magnetic particles in the liquid. However, when a magnet is brought close to a container loaded with magnetic particles, the magnetic particles form aggregates, which tends to make dispersion in a liquid difficult.

  In particular, when cells in a biological sample are lysed using a cell lysate containing a surfactant, chaotropic salt, etc., and the target substance such as nucleic acid eluted in the liquid is immobilized on the surface of the magnetic particles, In addition to the target substance, a wide variety of contaminants are included. When these contaminants adhere to the magnetic particles, the surface of the magnetic particles is masked, so that fixation of the target substance is hindered and the recovery rate of the target substance is reduced. For example, in nucleic acid extraction from blood, contaminating proteins derived from cells may adhere to the surface of the magnetic particles and hinder the fixation of the nucleic acids to the magnetic particles.

  In addition, when magnetic particles are strongly aggregated through contaminating proteins attached to the surface, it becomes difficult to disperse the particles in the liquid by a liquid flow such as pipetting, and the purity of the target substance and the recovery rate are reduced. Tend. As a method for preventing such problems associated with aggregation of magnetic particles, a nucleic acid is generally used by using a proteolytic enzyme such as protease K before bringing a liquid such as a cell lysate into contact with the magnetic particles. It is necessary to prevent the aggregation of magnetic particles by decomposing the nucleoprotein bound to the magnetic particles. Further, when enzyme treatment is not performed, a long time is required for stirring by pipetting or vortexing. Therefore, the convenience of separation / purification operation using magnetic particles is lost.

  In view of the above, the present invention provides a method for operating magnetic particles for dispersing magnetic particles in a liquid with high efficiency by a simple operation in separation and purification of a target substance using magnetic particles. With the goal.

  As a result of studies by the present inventors, it has been found that by moving a magnet in the vicinity of the outer wall surface of the container, kinetic energy is given to the magnetic particles, and the magnetic particles can be efficiently dispersed in the liquid. In a preferred embodiment of the present invention, the magnetic particles are dispersed in the liquid by applying vibration to the container while moving the magnet in the vicinity of the outer wall surface of the container. For example, the container can be vibrated by moving the magnet along an uneven structure provided on the outer wall surface of the container.

  In one embodiment, the container is vibrated by reciprocating the magnet connected to the elastic body while abutting the concave-convex structure on the outer wall surface of the container. This method is particularly useful when automating the operation of magnetic particles.

  In the present invention, magnetic particles capable of selectively fixing a target substance are preferably used. Examples of the target substance that can be selectively fixed to the magnetic particles include biologically derived substances such as nucleic acids, proteins, sugars, lipids, antibodies, receptors, antigens, ligands, and cells. For example, by dispersing magnetic particles in a liquid containing the target substance, the target substance can be selectively fixed to the surface of the magnetic particles. In one embodiment of the present invention, the liquid in which the magnetic particles are dispersed contains a component capable of lysing cells such as a chaotropic substance and a surfactant.

  In one embodiment of the present invention, after the target substance is selectively fixed on the surface of the magnetic particles by the above method, the magnetic particles on which the target substance is fixed are brought into contact with the eluate. Thereby, the target substance can be eluted in the eluate and the target substance can be recovered. Such an operation may be performed in a device in which gel-like medium layers and liquid layers are alternately arranged in a container. In this device, the magnetic particles in the liquid layer are moved into the gel-like medium by the magnetic field operation, and then moved into the other liquid layer and dispersed in the liquid layer. For example, when the liquid layer is a cleaning liquid, it is possible to clean and remove adhering impurities on the surface of the magnetic particles. When the liquid layer is an eluent, a target substance such as a nucleic acid fixed on the surface of the magnetic particles can be freely recovered.

  Furthermore, the present invention relates to a device for performing the above magnetic particle manipulation and a kit for producing the device.

  According to the method of the present invention, magnetic particles can be efficiently dispersed in a liquid by applying kinetic energy to the magnetic particles by a magnetic field operation. Therefore, the target substance such as nucleic acid contained in the liquid can be efficiently fixed to the surface of the magnetic particles. In particular, by applying vibration to the container while moving the magnet in the vicinity of the outer wall surface of the container, the dispersion of the magnetic particles in the liquid is promoted, and the operation efficiency can be increased.

It is a figure which shows typically the outline | summary of the operating method of a magnetic particle. It is a figure which represents typically embodiment of the device for a magnetic particle operation for operating a magnetic particle, vibrating a container. It is a figure which shows typically each process of embodiment which isolate | separates and refine | purifies a nucleic acid. It is a figure which shows typically each process of embodiment which isolate | separates and refine | purifies a nucleic acid.

  FIG. 1 is a conceptual diagram for explaining a method of operating magnetic particles. The present invention relates to a method for manipulating magnetic particles for dispersing magnetic particles in a liquid loaded in a container. In FIG. 1A, the container 10 contains a liquid 31 and magnetic particles 71. As the magnetic particles 71, for example, particles capable of fixing a predetermined target substance on the surface thereof are used.

  Examples of the target substance include biological substances such as nucleic acids, proteins, sugars, lipids, antibodies, receptors, antigens, ligands and cells. By dispersing the magnetic particles in the liquid, the target substance is fixed on the surface of the magnetic particles, the target substance fixed on the surface of the magnetic particles is released into the eluate, and the particles adhered to the surface of the magnetic particles. Operations such as washing and removal of objects can be performed.

[container]
The material and shape of the container 10 are not particularly limited as long as the magnetic particles in the container can be moved by a magnetic field operation from the outside and can hold the liquid. For example, a tubular container such as a test tube or a cone-shaped container such as an eppendle tube can be used. Further, a straight tubular structure (capillary) having an inner diameter of about 1 to 2 mm and a length of about 50 mm to 200 mm, and a linear groove having a width of about 1 to 2 mm, a depth of about 0.5 to 1 mm, and a length of about 50 mm to 200 mm. A structure or the like in which another flat plate material is bonded to the upper surface of the formed flat plate material can also be used. In addition, the shape of the container is not limited to a tubular shape or a planar shape, and the particle moving path may have a structure having a cross such as a cross or a T-shape.

  In the present invention, since the magnetic particles 71 in the container 10 can be moved by a magnetic field operation, the container after the sample has been charged can be a closed system. If the container is a closed system, contamination from outside can be prevented. Therefore, it is particularly useful when an easily decomposed substance such as RNA is fixed to the magnetic particles for operation. When the container is a closed system, the container can be sealed using a method of heat-sealing the opening of the container or an appropriate sealing means. When it is necessary to take out the particles or aqueous liquid after the operation from the container, it is preferable to use a resin stopper or the like to seal the opening so as to be removable.

  The material of the container 10 is not particularly limited as long as it does not shield the magnetic field from the outside. Polyolefin such as polypropylene and polyethylene, fluorine-based resin such as tetrafluoroethylene, polyvinyl chloride, polystyrene, polycarbonate, cyclic polyolefin, etc. The resin material is mentioned. In addition to these materials, ceramic, glass, silicone, metal and the like can also be used. In order to increase the water repellency of the inner wall surface of the container, coating with a fluorine-based resin or silicone may be performed.

  When optical measurements such as absorbance, fluorescence, chemiluminescence, bioluminescence, and refractive index change are performed during or after the operation of magnetic particles, or when light irradiation is performed, a container having optical transparency is preferable. Used. Moreover, if the container is light-transmitting, it is preferable because the state of particle operation in the container can be visually confirmed. On the other hand, when it is necessary to shield liquid or magnetic particles from light, a container made of metal or the like that does not have light permeability is preferably used. A container having a light transmitting portion and a light shielding portion can also be used depending on the purpose of use.

[Magnetic particles]
The magnetic particles 71 are particles that can selectively fix a target substance in a liquid. The method for immobilizing the target substance on the particle surface is not particularly limited, and various known immobilization mechanisms such as physical immobilization and chemical immobilization can be applied. For example, the target substance is fixed on the surface or inside of the particle by various intermolecular forces such as van der Waals force, hydrogen bond, hydrophobic interaction, ion-ion interaction, and π-π stacking. Target substances such as nucleic acids, proteins, sugars, lipids, antibodies, receptors, antigens, ligands and cells may be immobilized on the particle surface by molecular recognition or the like. For example, when the target substance is a nucleic acid, the nucleic acid can be selectively immobilized on the particle surface by using silica-coated magnetic particles. Further, the target substance is an antibody (e.g., a labeled antibody), when the receptor is an antigen and the ligand such as an amino group on the particle surface, a carboxyl group, an epoxy group, A bi Jin, biotin, digoxigenin, protein A, protein The target substance can be selectively fixed to the particle surface by G or the like.

Examples of the magnetic material include ferromagnetic metals such as iron, cobalt and nickel, and compounds, oxides and alloys thereof. Specifically, magnetite (Fe ₃ O ₄ ), hematite (Fe ₂ O ₃ or αFe ₂ O ₃ ), maghemite (γFe ₂ O ₃ ), titanomagnetite (xFe ₂ TiO _4. (1-x) Fe ₃ O ₄ , ilmenohegmatite (xFeTiO ₃ · (1-x) Fe ₂ O ₃ , pyrotite (Fe _1-x S (x = 0 to 0.13)... Fe ₇ S ₈ (x to 0.13)) , Grayite (Fe ₃ S ₄ ), goethite (αFeOOH), chromium oxide (CrO ₂ ), permalloy, alkoni magnet, stainless steel, samarium magnet, neodymium magnet, barium magnet.

  From the viewpoint of facilitating particle manipulation in a liquid, the particle size of the magnetic particles is preferably about 0.1 to 20 μm, and more preferably about 0.5 to 10 μm. The shape of the magnetic particles is preferably a spherical shape with uniform particle diameters, but may be irregular and have a certain particle size distribution as long as the particles can be manipulated. The constituent component of the magnetic particles may be a single substance or a plurality of components.

  As the magnetic particles, particles in which a substance for selectively fixing a target substance is attached to the surface of the magnetic substance or those coated with the substance are preferably used. As such magnetic particles, for example, commercially available products such as Dynabeads (registered trademark) sold by Life Technologies and MagExtractor (registered trademark) sold by Toyobo can be used.

[liquid]
The liquid loaded in the container provides a place for chemical operations such as fixation of the target substance on the surface of the magnetic particles and extraction, purification, reaction, separation, detection and analysis of the target substance. As the liquid, an aqueous liquid such as an aqueous solution or a mixed solution of water and an organic solvent is preferably used. In addition to functioning as a mere medium for these chemical operations, the liquid may directly participate in the chemical operation or may contain a compound involved in the operation as a component. The substance contained in the liquid includes a target substance to be fixed on the surface of the magnetic particles, a substance that reacts with the target substance fixed on the surface of the magnetic particles, and a substance fixed on the surface of the magnetic particles by the reaction. Examples thereof include substances that react further with each other, reaction reagents, fluorescent substances, various buffers, surfactants, salts, and other various auxiliary agents, and organic solvents such as alcohol. The aqueous liquid may be provided in any form such as water, an aqueous solution, a water suspension, and the like. Hereinafter, a liquid containing a target substance such as a nucleic acid may be referred to as a “liquid sample”.

  When the target substance contained in the liquid sample is fixed on the surface of the magnetic particles, the liquid contains a wide variety of contaminants in addition to the target substance to be fixed on the surface of the magnetic particles. . For example, when the target substance is a nucleic acid, the liquid sample includes biological samples such as animal and plant tissues, body fluids, and excreta, and nucleic acid inclusions such as cells, protozoa, fungi, bacteria, and viruses. Body fluid includes blood, cerebrospinal fluid, saliva, milk and the like, and excrement includes feces, urine, sweat and the like. A combination of these can also be used. The cells include leukocytes in blood, platelets, exfoliated cells of mucosal cells such as oral cells, and leukocytes in saliva, and combinations thereof can also be used.

  The liquid sample containing the target nucleic acid may be prepared, for example, in the form of a cell suspension, a homogenate, a mixed solution with a cell lysate, or the like. For example, when nucleic acid is separated and purified from a biological sample such as blood, the liquid sample in the container is a biological sample such as blood and a cell lysate (nucleic acid extract) for extracting a target substance therefrom. And a mixture.

  The cell lysate contains components capable of lysing cells such as chaotropic substances and surfactants. Examples of the cell lysate (nucleic acid extract) used for nucleic acid extraction include a buffer containing a chaotropic substance, a chelating agent such as EDTA, Tris-HCl, and the like. The cell lysate may also contain a surfactant such as Triton X-100. Examples of chaotropic substances include guanidine hydrochloride, guanidine isothiocyanate, potassium iodide, urea and the like. A chaotropic salt is a powerful protein denaturant that dissolves cellular proteins and releases nucleic acids in the cell nucleus into the solution, and also has the effect of suppressing the action of nucleolytic enzymes. Further, by using a proteolytic enzyme such as protease K to decompose the nuclear protein bound to the nucleic acid, the purity and recovery rate of the nucleic acid can be improved. In addition to the above, the cell lysate may contain various buffers, salts, and other various auxiliary agents, and organic solvents such as alcohol.

[Dispersion of magnetic particles by magnetic field operation]
Hereinafter, an example in which the magnetic particles 71 are dispersed in the liquid sample 31 and nucleic acids are immobilized as target substances on the surfaces of the magnetic particles 71 will be described with reference to FIGS. . First, as shown in FIG. 1A, a liquid sample 31 and magnetic particles 71 are loaded into a container 10. These loading orders are not particularly limited. For example, a solution such as a cell lysate can be loaded in the container 10 in advance, and after adding blood or the like to the solution, magnetic particles can be added. First, blood or the like is charged into the container 10, and a cell lysate and magnetic particles can be added sequentially or simultaneously thereto. Alternatively, magnetic particles may be loaded in the container 10 together with the cell lysate, and blood or the like may be added thereto. A kit in which magnetic particles are loaded together with a cell lysis solution in the container 10 can be prepared in advance. After the liquid sample and magnetic particles are loaded into the container 10, it is preferable to prevent contamination from the outside by closing the upper part of the container 10 with a lid and using the device as a closed system.

  As shown in FIG. 1B, when the magnet 9 is brought close to the outer wall surface of the container, the magnetic particles 71 are attracted to the inner wall surface of the container around the magnet 9. For the magnetic field operation, a magnetic source such as a permanent magnet (for example, a ferrite magnet or a neodymium magnet) or an electromagnet can be used.

  The liquid sample 31 contains impurities such as denatured protein. When the surfaces of the magnetic particles are masked with foreign substances, the magnetic particles 71 have an action of adhering the magnetic particles to each other, so that the magnetic particles 71 attracted to the inner wall surface of the container may form an aggregate. When the magnetic particles form aggregates, the chance of contact between the nucleic acid in the liquid sample and the magnetic particles decreases, and the fixation of the target substance on the particle surface is inhibited. In order to fix the target substance on the surface of the magnetic particles, it is necessary to disperse the aggregated magnetic particles.

  By moving the magnet in the vicinity of the outer wall surface of the container 10, the magnetic flux density in the container changes, so that kinetic energy is given to the magnetic particles. Examples of the moving method of the magnet include linear movement including reciprocating movement, rotational movement, and other movements that draw an irregular orbit. In the operation of the magnetic particles, the position of the container and the magnet may be changed relatively, and the container may be moved with the position of the magnet fixed.

  Since the magnetic particles 71 to which the kinetic energy is given move in the liquid while being attracted to the magnet 9, the magnetic particles 71 frequently collide with the inner wall surface of the container 10. In addition to giving kinetic energy to the magnetic particles by moving the magnet in the vicinity of the outer wall surface of the container, the magnetic particles collide with the inner wall surface of the container, and the aggregates of the magnetic particles are crushed. It is assumed that the magnetic particles are rapidly dispersed in the liquid.

  Thus, according to the method of the present invention, the magnetic particles can be dispersed even when the magnetic particles form aggregates via the denatured protein or the like in the liquid sample 31. When the magnetic particles that have formed aggregates are dispersed in the liquid sample with kinetic energy, the contaminants adhering to the surface of the magnetic particles are desorbed, so that the nucleic acid that is free in the liquid sample Can be selectively fixed to the surface of the magnetic particles.

  In general, in the separation and purification of target substances using magnetic particles, a proteolytic enzyme such as Proteinase K is used before the sample and magnetic particles are brought into contact with each other to prevent aggregation of the magnetic particles due to denatured protein. Is added to the sample, and the enzyme treatment is performed under heating at 50 ° C to 70 ° C. After the protein that binds to nucleic acid is decomposed and removed by enzyme treatment, alcohol such as ethanol is added to increase the hydrophobicity of the liquid sample, and then magnetic particles are added to the liquid sample. Aggregation of particles is suppressed. In addition, since alcohol inhibits an enzyme reaction, in order to perform these operations, it is necessary to add alcohol after performing an enzyme treatment under heating conditions. In addition, the enzyme, magnetic particles and alcohol are stored in separate containers, or separated by a partition provided in the container, and sequentially added to the sample when performing separation / purification operations. There is a need. For this reason, the operation for fixing the target substance to the surface of the magnetic particles is complicated, and complicated processing for providing a partition wall or the like is required on the device, which increases the manufacturing cost of the device.

  On the other hand, according to the method of the present invention, even when the magnetic particles form an aggregate, the magnetic particles are subjected to a magnetic field operation to give kinetic energy to the aggregated state of the magnetic particles. And can be dispersed in a liquid sample. According to this method, the enzyme treatment before adding the magnetic particles can be omitted. Since the enzyme treatment can be omitted, the cost required for the separation / purification operation can be reduced. In addition, since the addition of an enzyme is not required, the operation of adding a sample or dispensing is not required, the operation can be simplified, and the operation can be performed in a closed system, so that the risk of contamination can be reduced. Dispersion by pipetting needs to be performed in an open system, whereas the method of the present invention can be performed in a closed system, so that the risk of contamination can be reduced. Furthermore, since the magnetic particles can be dispersed in the liquid by a simple operation of moving the magnet relative to the container, automation can be easily achieved. As described above, in order to maintain a closed system and reduce contamination, it is preferable that the number of additional operations such as liquid is small. Therefore, in a preferred embodiment of the present invention, no enzyme treatment is performed, and no enzyme is added to the liquid sample 31 (however, the enzyme originally contained in the biological sample may coexist in the liquid sample. ).

  In order to disperse the magnetic particles efficiently, the magnet 9 is preferably reciprocated along the outer wall surface of the container 10. In particular, in the present invention, it is preferable to apply vibration to the container while moving the magnet in the vicinity of the outer wall surface of the container. By performing the magnetic field operation while vibrating the container, the dispersion of the magnetic particles tends to be promoted. This is considered to be caused by an increase in the kinetic energy of the magnetic particles and an increase in the collision frequency between the magnetic particles and the inner wall surface of the container.

  The method of vibrating the container while moving the magnet near the outer wall surface of the container is not particularly limited. For example, the magnetic field operation can be performed while bringing a vibrating body such as a vortex mixer into contact with the container. Moreover, as shown in FIG. 2, the method of moving the magnet 9 along the uneven structure of this container using the container 11 which has the uneven structure 13 in an outer wall surface is mentioned. That is, if the magnet 9 is moved in the longitudinal direction of the pipe (the vertical direction in FIGS. 2A and 2B) while the magnet 9 is pressed against the uneven structure 13 on the outer wall surface of the container, the direction intersects the moving direction. The container can be vibrated. According to this method, since it is not necessary to separately prepare a means for generating vibration, the magnetic particles can be dispersed in the liquid simply and efficiently.

  The uneven structure 13 on the outer wall surface of the container preferably has a plurality of unevenness continuously along the outer wall surface of the container 11. The size of the unevenness is not particularly limited as long as the container can be vibrated with the movement of the magnet. The height of the unevenness is set to, for example, about 0.5 mm to 10 mm. Examples of the method of providing the concavo-convex structure on the outer wall surface of the container include a method of forming the concavo-convex structure integrally with the container body, and a method of attaching the concavo-convex structure to the surface of the container via an appropriate bonding means.

  By moving the magnet 9 along the unevenness of the outer wall surface of the container while the operator holds the magnet 9, the container 11 can be vibrated while moving the magnet. Further, in order to cause the movement of the magnet to follow the concavo-convex structure of the container, a follow-up mechanism in which a magnet and an elastic body are connected can be used as schematically shown in FIG. In the follow-up mechanism shown in FIG. 2B, a spring 25 is provided as an elastic body in the frame body 21, and one end of the spring 25 is connected to a fixing member 27 fixed in the frame body 21. The other end of the spring 25 is connected to the movable member 29, and the magnet 9 and the spring 25 are connected to each other by fitting and fixing the magnet 9 to the movable member 29. A guide bar 28 is connected to the magnet 9, and the guide bar 28 is inserted into an insertion hole 27 a provided in the center of the fixed member 27, and the movable member 29, the magnet 9, and the guide bar 28 are inserted. Is configured to be movable in the longitudinal direction (left-right direction in the figure) within the frame body 21. If the follower mechanism is moved up and down along the outer wall surface of the container 11 while holding the frame body 21 of the follower mechanism 20, the state in which the magnet 9 is pressed against the concavo-convex structure 13 by the elastic force of the spring 25 is maintained. However, the magnet can be moved in the vertical direction. Therefore, the container can be vibrated more efficiently and the magnetic particles can be dispersed.

  In particular, when automating the operation of the magnetic particles, it is preferable to use a tracking mechanism in which a magnet and an elastic body are connected. For example, by connecting a rotating mechanism such as a stepping motor and a follow-up mechanism via a cam or a crank, the magnet can be reciprocated while being pressed against the concavo-convex structure on the outer wall surface of the container to disperse the magnetic particles. it can. At this time, the container is preferably fixed using an appropriate fixing jig. In order to efficiently vibrate the container, the container is preferably fixed via an elastic member such as a cushioning material.

  In the follow-up mechanism 20 shown in FIG. 2B, a spring 25 is connected to the magnet 9 so that the magnet 9 is pressed against the concavo-convex structure 13, but the elastic body connected to the magnet is other than the pressing force. It may be that which gives the power of. For example, the container can be vibrated by moving the magnet while colliding with the convex portion of the concavo-convex structure using a follow-up mechanism in which a magnet and a leaf spring are connected.

[Operation after dissolution / fixation]
The magnetic particles 71 on which the target substance is fixed are separated from the liquid sample 31 and subjected to another process. For example, in the separation and purification of nucleic acid, the magnetic particles 71 are washed in a washing solution to remove impurities adhering to the surface, and then the nucleic acid fixed to the magnetic particles in the eluate is freely eluted. Thus, the target nucleic acid can be recovered. The recovered nucleic acid can be subjected to operations such as concentration and drying as necessary, and then subjected to analysis, reaction, and the like.

  Washing and elution operations can be performed by known methods. For example, with the magnet close to the container and the magnetic particles fixed in the container near the magnet, the liquid in the container is removed, and then a new liquid (cleaning solution or eluate) is poured into the container. By dispersing the magnetic particles with the above, washing operation and elution operation can be performed. The dispersion of the magnetic particles in the liquid can be carried out by stirring operations such as pipetting and vortexing. Also in the operation of washing and elution, the magnetic particles may be dispersed by giving kinetic energy to the magnetic particles by moving the magnet in the vicinity of the outer wall surface of the container.

  In the above, the example of separating and purifying nucleic acid using magnetic particles has been mainly shown, but the target substance immobilized on the surface of the magnetic particles is not limited to nucleic acids, and the present invention is not limited to nucleic acids. Applicable to various target substances. For example, by using magnetic particles whose surface is coated with molecules capable of selectively immobilizing antibodies such as protein G and protein A, the target magnetic field antibody is magnetically treated by performing the same magnetic field operation as described above. It can be selectively fixed on the surface of the body particles. The magnetic particles on which the antibody is immobilized are sequentially brought into contact with a liquid containing the test antigen or an enzyme-labeled secondary antibody, and then the enzyme bound to the secondary antibody immobilized on the surface of the magnetic particle. By monitoring the color development reaction with the color developing substance, an enzyme-linked immunosorbent assay (ELISA) can be performed.

  As described above, if the type of the target substance and the type of liquid loaded in the device are changed according to the target operation, the present invention is not limited to extraction, purification and separation of the target substance, It can also be applied to reactions, detection, qualitative / quantitative analysis, etc.

[Operation using a device encapsulating a gel-like medium]
The method of the present invention is a method for separating and purifying a target substance using a device in which an aqueous liquid layer and a gel-like medium layer are alternately layered as disclosed in Patent Document 2 (WO2012 / 086243) described above. It can also be applied to. When such a device is used, since a series of operations can be performed in a closed system, the risk of contamination can be reduced as compared with pipetting operations performed in an open system.

  Hereinafter, an example in which nucleic acid is separated and purified using a device in which an aqueous liquid layer and a gel-like medium layer are alternately stacked will be described with reference to FIG. In the tubular device 150 shown in FIG. 3A, the nucleic acid extract 130, the first cleaning liquid 132, the second cleaning liquid 133, and the nucleic acid elution liquid 134 are arranged along the direction in which the magnetic particles 171 are moved. It is loaded in the tubular container 110 via the gel-like medium layers 121, 122, 123 between them.

  The gel-like medium forming the gel-like medium layers 121, 122, 123 may be in the form of a gel or a paste before the particle operation. The gel-like medium is preferably a chemically inactive substance that is insoluble or hardly soluble in the liquid in the liquid layer adjacent to the gel-like medium. When the liquid layer is composed of an aqueous liquid, the gel-like medium is preferably an oily gel that is insoluble or hardly soluble in the aqueous liquid. The gel-like medium layer is preferably a chemically inert substance. Here, being insoluble or hardly soluble in the liquid means that the solubility in the liquid at 25 ° C. is approximately 100 ppm or less. Chemically inactive substances refer to the liquid layer, magnetic particles, and magnetic particles in contact with the liquid layer and the operation of magnetic particles (that is, the operation of moving the magnetic particles in a gel-like medium). A substance that does not have a chemical effect on a fixed substance.

  The material and composition of the gel medium are not particularly limited. The gel-like medium is formed by adding a gelling agent to a water-insoluble or poorly water-soluble liquid substance such as liquid oil or fat, ester oil, hydrocarbon oil, or silicone oil, for example. The gel (physical gel) formed by the gelling agent forms a three-dimensional network by weak intermolecular bonding forces such as hydrogen bonds, van der Waals forces, hydrophobic interactions, electrostatic attraction forces, Reversibly sol-gel transition by external stimulus such as heat. As the gelling agent, hydroxy fatty acid, dextrin fatty acid ester, glycerin fatty acid ester and the like are used. The amount of the gelling agent used is appropriately determined in consideration of the physical properties of the gel, for example, in the range of 0.1 to 5 parts by weight with respect to 100 parts by weight of the water-insoluble or hardly water-soluble liquid substance. The

  The method for gelation is not particularly limited. For example, a water-insoluble or poorly water-soluble liquid material is heated, a gelling agent is added to the heated liquid material, the gelling agent is completely dissolved, and then cooled to a sol-gel transition temperature or lower. Thus, a physical gel is formed. The heating temperature is appropriately determined in consideration of the physical properties of the liquid substance and the gelling agent.

  In addition, a hydrogel material (for example, gelatin, collagen, starch, pectin, hyaluronic acid, chitin, chitosan, alginic acid, or a derivative thereof) prepared by equilibrium swelling in a liquid is used as a gel-like medium. You can also. Hydrogels include those obtained by chemically cross-linking hydrogel materials, gelling agents (for example, salts of alkali metals and alkaline earth metals such as lithium, potassium and magnesium, or salts of transition metals such as titanium, gold, silver and platinum, Furthermore, the thing etc. which gelatinized with silica, carbon, an alumina compound, etc. can also be used.

The gel medium and the liquid can be charged into the container 110 by an appropriate method. When a tubular container is used, it is preferable that the opening at one end of the container is sealed prior to loading, and the gel-like medium and the aqueous liquid are sequentially loaded from the opening at the other end. Inner diameter to small structures, such as a capillary of about 1 to 2 mm, when loading the gel-like medium, for example, by mounting the metal needle in Le Arokku syringe, the gel-like medium to a predetermined position in the capillary Loading is performed by an extrusion method.

  The capacities of the gel-like medium and the liquid loaded in the container can be appropriately set according to the amount of magnetic particles to be operated, the type of operation, and the like. When a plurality of gel-like medium layers and liquid layers are provided in the container, the capacity of each layer may be the same or different. Although the thickness of each layer can also be set appropriately, the layer thickness is preferably about 2 mm to 20 mm, for example, in consideration of operability and the like.

  Examples of the nucleic acid extract 130 used for nucleic acid extraction include the aforementioned cell lysate (for example, a buffer containing a chaotropic substance, a chelating agent such as EDTA, Tris-HCl, etc.). In addition to the nucleic acid extract 130, magnetic particles 171 are preloaded at the top of the container 110. The magnetic particles 171 can selectively fix a nucleic acid. For example, magnetic particles coated with silica are used.

  A sample containing nucleic acid such as blood is added into the nucleic acid extract 130 from the opening at the top of the device 150 in which the liquid layer and the gel-like medium layer are alternately stacked. Thereby, a solution (liquid sample) 131 containing the nucleic acid extract and the nucleic acid is prepared. When the magnet 9 is brought close to the container side surface of the liquid sample 131, the magnetic particles 171 are attracted to the inner wall surface of the container around the magnet 9 (FIG. 3B). By reciprocating the magnet 9 along the outer wall surface of the container 110, the magnetic particles 171 are dispersed in the liquid sample 131 (FIG. 3-1 (C)). By this operation, the nucleic acid in the liquid sample is selectively fixed to the surface of the magnetic particle. When the concavo-convex structure 113 is formed on the outer wall surface of the container 110, the magnet is moved along the concavo-convex structure to vibrate the container 110 and to efficiently disperse the magnetic particles in the liquid sample. Can do.

  By moving the magnet 9 along the outer wall surface of the container, the magnetic particles 171 are moved into the gel-like medium layer 121 (FIG. 3-2 (D)). When the magnetic particles 171 enter the gel-like medium layer 121, most of the liquid physically attached as droplets around the magnetic particles 171 is detached from the surface of the particles and is liquid in the liquid layer 131. Remain in minutes. On the other hand, the magnetic particles 171 can easily move in the gel-like medium layer 121 while holding the target substance fixed to the particles.

  The gel-like medium is perforated by the entry and movement of the magnetic particles 171 into the gel-like medium layer 121, but the gel self-heals due to its thixotropic nature. When shearing force is applied when the magnetic particles move in the gel by the magnetic field operation, the gel is locally fluidized (viscous) due to thixotropic properties. Therefore, the magnetic particles can easily move in the gel while perforating the fluidized portion. After the magnetic particles pass, the gel released from the shearing force quickly recovers to its original elastic state. Therefore, a through hole is not formed in a portion through which the magnetic particles have passed, and the liquid hardly flows into the gel through the perforated portion of the magnetic particles. If the moving speed of the magnet 9 is excessively high, the gel may be physically destroyed and the restoring force may be lost. Therefore, the moving speed of the magnet is preferably about 0.1 to 5 mm / second.

  The restoring force due to the thixotropic property of the gel as described above exerts an action of squeezing out the liquid accompanying the magnetic particles 171. Therefore, even when the magnetic particles 171 become aggregates and move into the gel-like medium layer 121 in a state where the droplets are taken in, the magnetic particles and the droplets are separated by the restoring force of the gel. obtain.

  The magnetic particles 171 that have passed through the gel-like medium layer 121 are moved from the gel-like medium layer 121 to the liquid layer 132 by a magnetic field operation. As described above, since the through hole is not formed in the portion of the gel-like medium layer 121 through which the magnetic particles have passed, the liquid sample 131 hardly flows into the liquid layer 132.

  The liquid layer 132 is a cleaning liquid, for example. The washing solution is a component other than the nucleic acid (for example, protein, sugar, etc.) adhering to the magnetic particles, or a reagent used for nucleic acid extraction or the like while the nucleic acid is fixed on the surface of the magnetic particles. Etc. may be used as long as they can be released into the cleaning liquid. Examples of the cleaning liquid include high salt concentration aqueous solutions such as sodium chloride, potassium chloride, and ammonium sulfate, and aqueous alcohol solutions such as ethanol and isopropanol. The liquid layer 133 may also be a cleaning liquid. When the liquid layers 132 and 133 are both cleaning liquids, the compositions of these cleaning liquids may be the same or different.

  When the magnet 9 is moved along the side surface of the liquid layer 132, the magnetic particles 171 also move in the liquid layer as the magnet 9 moves. At this time, by reciprocating the magnet, the magnetic particles 171 forming the aggregates are dispersed in the liquid layer 132 (FIG. 2-2 (E)). The liquid sample 131 contains a large amount of contaminants such as denatured protein, while the liquid layer (cleaning solution) 132, 133 and the liquid layer (eluent) 134 contain a small amount of impurities (accompanying the magnetic particles). Only foreign materials brought in). Therefore, in these liquids, the dispersion of the magnetic particles is easier than in the case where the target substance is fixed on the surface of the magnetic particles. Even during washing and elution, the dispersion of the magnetic particles may be promoted by moving the magnet while vibrating the container.

  Thereafter, the magnet 9 is moved from the side surface of the liquid layer 132 to the side surface of the gel-like medium layer 122 (FIG. 3-2 (F)). Further, after moving the magnet 9 to the side surface of the liquid layer 133, the magnetic particles are sufficiently dispersed by reciprocating the magnet, and the magnetic particles are washed in the liquid layer 133 (FIG. 3). 2 (G)).

  In FIG. 3, an example in which two liquid layers 132 and 133 are loaded as cleaning liquids in the container 110 via the gel-like medium layer 122 is shown, but the cleaning liquid may be only one layer, Three or more types may be used. In addition, the washing can be omitted as long as the purpose of separation and undesired inhibition in use do not occur.

  The magnet 9 is moved from the side surface of the second cleaning liquid 133 to the side surface of the gel-like medium layer 123, and the magnetic particles 171 are moved into the gel-like medium layer 123 (FIG. 3-2 (H)). Furthermore, the magnet 9 is moved to the side surface of the nucleic acid eluate 134, and the magnetic particles 171 are moved into the nucleic acid eluate 134.

  As the nucleic acid eluate, water or a buffer containing a low-concentration salt can be used. Specifically, Tris buffer, phosphate buffer, distilled water, or the like can be used. Among them, it is common to use a 5-20 mM Tris buffer adjusted to pH 7-9. The nucleic acid fixed on the surface of the magnetic particle can be released by moving the particle with the nucleic acid fixed into the nucleic acid eluate. A specific method for releasing nucleic acid includes a method of dispersing particles in the eluate. For example, when the magnet 9 is moved along the side surface of the nucleic acid eluate 134, kinetic energy is given to the magnetic particles 171 and the magnetic particles 171 are dispersed in the nucleic acid eluate (FIG. 3-2 (I)). ). Thereby, the nucleic acid fixed on the surface of the magnetic particles 171 is efficiently desorbed and released into the nucleic acid eluate, so that the nucleic acid recovery rate is increased.

  Thereafter, as shown in FIG. 3-2 (J), the magnet 9 is moved along the outer wall surface of the container to the gel-like medium layer 123 side as necessary, and the magnetic particles 171 are moved into the gel-like medium layer 123. Enter again. By this operation, the magnetic particles 171 are removed from the nucleic acid eluate 134, so that the nucleic acid eluate can be easily collected.

  As described above, when using a device in which the liquid layer and the gel-like medium layer are alternately stacked, the liquid layer is held between the gel-like medium layer and between the gel-like medium layer and the container. Cannot be accessed from outside while keeping the system. In this embodiment, since the magnetic particles can be dispersed in the liquid layer while maintaining the sealed system, contamination from the outside can be suppressed as compared with the case where the magnetic particles are dispersed by pipetting.

  In this embodiment, solid-liquid separation is performed by moving magnetic particles in the gel-like medium layer. Therefore, the target substance can be efficiently separated and recovered with a smaller amount of magnetic particles and reagent than when solid-liquid separation of magnetic particles and reagents such as washing liquid and eluate is performed by pipetting. In addition, the amount of waste liquid can be significantly reduced. In addition, after adding a sample such as blood to the lysis / fixation solution (nucleic acid extract), simply move the magnet along the outer wall surface of the container to perform the steps from fixation to elution of the target substance. Therefore, the operation can be easily automated.

[Particle manipulation devices and kits]
A device for dissolution / fixation as shown in FIG. 1 or FIG. 2 can be created simply by loading magnetic particles and liquid in a container. The liquid loaded in the container is, for example, a liquid that can lyse cells, such as a nucleic acid extract. This liquid may be added with alcohol or the like for preventing aggregation of magnetic particles. In particular, when the enzyme treatment at the time of dissolution / fixation of the target substance is omitted, the device can be provided in a state where a liquid such as a nucleic acid extract and magnetic particles coexist in the device in advance. Manufacture is also easy.

  Apart from the container, the magnetic particles and the liquid may be provided independently. For example, the magnetic particles may be provided independently in a container or separately in a liquid state, separately from a device body in which a liquid capable of lysing cells is loaded. In this case, the magnetic particles may be provided as a component of a kit for producing a device. It can also be provided as a component of a kit in a state where magnetic particles coexist in a liquid.

  Further, a device in which a liquid layer and a gel-like medium layer are alternately stacked as shown in FIG. 3 can be easily manufactured. The loading of the gel-like medium and the liquid into the container may be performed immediately before the particle operation, or may be performed after a sufficient time before the particle operation. As described above, when the gel-like medium is insoluble or hardly soluble in the liquid, even when a long time elapses after loading, there is almost no reaction or absorption between the two.

  A device for manipulating magnetic particles in which a liquid layer and a gel-like medium layer are alternately layered is provided with magnetic particles 171 loaded in a container, as shown in FIG. You can also. The amount of the magnetic particles contained in the device or in the kit is appropriately determined according to the type of chemical operation to be performed, the capacity of each liquid layer, and the like. For example, when an elongated cylindrical capillary having an inner diameter of about 1 to 2 mm is used as the container, the amount of magnetic particles is usually preferably in the range of about 10 to 200 μg.

10, 11, 110 Container 13, 113 Uneven structure 20 Follow-up mechanism 25 Spring (elastic body)
71,171 Magnetic particles 31,131 Liquid sample 9 Magnet 150 Particle manipulation device for nucleic acid extraction 121-123 Gel medium 130 Liquid layer (nucleic acid extract)
132,133 Liquid layer (cleaning liquid)
134 Liquid layer (nucleic acid eluate)

Claims (8)

A method of operating magnetic particles for dispersing magnetic particles in a liquid charged in a container,
The container has an uneven structure on the outer wall surface,
A method for manipulating magnetic particles, in which a magnet is moved along the concavo-convex structure of the container to impart vibration to the container, thereby imparting kinetic energy to the magnetic particles and dispersing the magnetic particles in a liquid. By reciprocating with the concatenated magnet in the elastic body is brought into contact with the concavo-convex structure, the vibration is applied to the container, the operation method of the magnetic particles according to claim 1. It said magnetic particles are selectively fixable particles of the desired substance, the operation method of the magnetic particles according to claim 1 or 2. The target substance the magnetic particles can selectively fixed, nucleic acids, proteins, sugars, lipids, antibodies, receptors, antigens, is one or more selected from the group consisting of ligands and cells, to claim 3 The operation method of the magnetic substance particle as described. The target substance is contained in the liquid,
The method for operating magnetic particles according to claim 3 or 4 , wherein the target substance is fixed to the magnetic particles by dispersing the magnetic particles in the liquid. The method for manipulating magnetic particles according to claim 5 , wherein the liquid contains a component capable of lysing cells. After the target substance is selectively fixed on the surfaces of the magnetic particles by the method according to claim 5 or 6 ,
A method for manipulating magnetic particles, wherein the target particles are eluted in the eluate by bringing the magnetic particles fixed with the target substance into contact with the eluate. In the device in which the gel-like medium layer and the liquid layer are alternately arranged in the container,
After the target substance in the first liquid layer is selectively fixed to the surface of the magnetic particles by the method according to claim 5 or 6 ,
A step of moving magnetic particles in the first liquid layer into the gel-like medium by a magnetic field operation;
A step of moving the magnetic particles present in the gel-like medium layer into the second liquid layer by a magnetic field operation; and a step of dispersing the magnetic particles in the second liquid layer. A method for operating magnetic particles.

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