JP7076282B2 - Stirrer, analyzer, dispensing method - Google Patents

Description

The present invention relates to a technique for stirring a solution containing magnetic particles.

In the field of biochemical immunoassay equipment, a labeled luminescent substance is applied to a substance to be analyzed such as an antigen contained in a sample by using an antigen-antibody reaction, and the amount of luminescence of the luminescent substance is measured. Detect antigens and antibodies in the sample and quantify the concentration. The type of labeled luminescent substance differs depending on the luminescence method. A luminol derivative, a dioxetane compound, or the like is used in the chemiluminescence method, and a Ru complex or the like is used in the chemiluminescence method. A sandwich-type antigen-antibody complex is formed by binding the substance to be analyzed to which the labeled luminescent substance is applied to the surface of the magnetic particles. By attracting the magnetic particles to the magnet, the complex is placed near the magnet and the light emission measurement is performed.

The magnetic particles used at this time are generally stored in a solution in a reagent bottle. However, since the magnetic particles have a higher specific gravity than the solution, they settle due to gravity, resulting in non-uniformity of concentration. Therefore, when the magnetic particles are taken out, the solution is first stirred to homogenize the solution to a predetermined concentration. After that, a required amount of the magnetic particle-containing liquid is recovered by a dispensing mechanism such as a nozzle, and the magnetic particle-containing liquid is added to the sample or the like.

The following Patent Document 1 describes a stirring mechanism for dispersing magnetic particles in a solution. As described in the same document, as the stirring mechanism, a method (mixer stirring method) in which a stirring member having a paddle-like structure is put in a solution and the stirring member is rotated is often used. Not limited to the field of biochemical immunoassays, devices that automatically dispense magnetic particles require the above-mentioned stirring mechanism for magnetic particles.

Japanese Unexamined Patent Publication No. 2013-2538226

The mixer stirring method generally used as a stirring device for magnetic particles tends to have a high device manufacturing cost due to the inclusion of an ascending / descending mechanism and a rotating mechanism of the stirring rod. In addition, since magnetic particles generally settle in a solution within a few minutes, it is necessary to stir the magnetic particle-containing solution many times in a biochemical immunoanalyzer that analyzes a large number of samples a day. Further, in the mixer stirring method, since the manufacturing cost of the stirring rod to be inserted into the reagent bottle is high and it cannot be disposable, it is necessary to stir with the same stirring rod. Since magnetic particles adhere to the stirring rod each time it is stirred, a mechanism for cleaning the stirring rod is required to prevent fluctuations in the magnetic particle concentration due to carryover. In an analyzer having a cleaning mechanism, it is necessary to prepare an equipment introduction environment for arranging pure water equipment for cleaning when the analyzer is introduced, and the running cost of the apparatus increases.

As another method of stirring magnetic particles, a method of vibrating the entire container (vibration stirring method) can be considered. However, when vibration stirring is applied, the magnetic particle-containing solution in the container may scatter out of the container. Especially in a biochemical immunoassay device, since a large number of reagent bottles containing magnetic particles are generally stored in a storage in a state of being arranged adjacent to each other, a mechanism for taking out a specific reagent bottle with a robot arm or the like and vibrating and stirring it. The equipment cost tends to be high. It is conceivable to vibrate and stir the entire storage, but since the weight of the storage is relatively large, the equipment cost becomes high.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique capable of stirring a solution containing magnetic particles with a simple structure. It should be noted that the above-mentioned problem is not a problem that occurs only in the biochemical immunoassay device, but a problem that is shared by all the devices having a magnetic particle stirring device.

In the stirring device according to the present invention, the magnetic stirring device is placed in a container containing a solution containing magnetic particles having normal magnetism, and the magnetic stirring device is rotated by applying a fluctuating magnetic field from outside the container to rotate the magnetic stirring device. Stir the solution in the container.

According to the stirring device according to the present invention, the magnetic particles contained in the solution can be dispersed to a predetermined concentration without agglomeration by using a simple structure. Issues, configurations and effects other than those described above will be clarified by the following description of the embodiments.

It is a side view of the stirring apparatus 100. It is a top view of the stirring device 100. This is a configuration example in which the fluctuating magnetic field generator 4 uses a permanent magnet. This is a configuration example in which the fluctuating magnetic field generator 4 uses an electromagnet. This is a configuration example of the dispensing mechanism. This is another configuration example of the dispensing mechanism. It is a schematic diagram of the magnetic field generated in the container 2 by the magnetic stirrer 3. This is an example of the shape of the magnetic stirrer 3. It is a figure explaining the size of a magnetic stirrer 3. This is an example of an observation unit for observing the behavior of the magnetic stirrer 3. This is a specific example of the stirrer observation unit 14. This is an example in which the stirrer observation unit 14 is arranged below the container 2. This is an example of a mechanism for driving the dispensing nozzle 12. It is a top view of the analyzer. It is a side sectional schematic diagram of the container disk 19. It is a side sectional schematic diagram which shows another structural example of a container disk 19. This is an example in which the solution suction position and the stirring position by the fluctuating magnetic field generator 4 are separated from each other. This is an example of having a plurality of stirring positions. This is an example showing how superparamagnetic magnetic particles aggregate. This is an example showing the behavior of magnetic particles when the external magnetic field applied to the magnetic particles is removed. This is an example of a histogram of the magnetic particle area by image analysis. It is a figure which shows the result of having verified the difference in the magnetic particle concentration by the stirring method. It is a graph which shows the result of having measured the magnetic flux density according to the distance from a magnetic stirrer 3. This is the result of calculating F _m (z) and F _g by linearly approximating the characteristics of the magnetic particles M-280. It is a graph which shows the result of having calculated the particle moving speed. It is a graph which shows the particle concentration ratio of the solution recovered from the vicinity of a liquid surface.

FIG. 1 is a side view of the stirring device 100 according to the present invention. The container 2 contains the solution 1 containing the magnetic particles and the magnetic stirrer 3. A fluctuating magnetic field generator 4 is arranged outside the container 2. The magnetic agitator 3 is rotationally driven by the magnetic attraction of the magnetic field generated by the fluctuating magnetic field generator 4. The magnetic agitator 3 may exhibit properties as a magnet (ferrous magnetism or the like) by itself, or has a property of being magnetized by a magnetic field generated by a fluctuating magnetic field generator 4 (for example, normal magnetism). It may be shown.

Although the magnetic stirrer 3 is arranged at the bottom of the container 2 in FIG. 1, it may be arranged near the liquid surface. The fluctuating magnetic field generator 4 does not necessarily have to be arranged below the container 2, and may be arranged at the upper part or the side portion of the container 2. However, typically, since the magnetic stirrer 3 sinks in the solution and is arranged at the bottom of the container 2, the fluctuating magnetic field generator 4 is provided with a magnetic attraction force of a sufficient magnitude to the magnetic stirrer 3. As described above, it is preferable to arrange the fluctuating magnetic field generator 4 below the container 2. Unless otherwise specified in the following description, it is assumed that the magnetic stirrer 3 is arranged at the bottom of the container 2 and the fluctuating magnetic field generator 4 is arranged at the lower part of the container 2.

The magnetic particles generally have a size of about 1 nm to 100 μm. Since the magnetic particles gradually settle due to gravity, the magnetic particles left for a long time sink to the bottom of the container 2. Therefore, in order to recover the magnetic particles having a predetermined concentration, it is necessary to stir the solution once to disperse the magnetic particles in the solution.

FIG. 2 is a top view of the stirring device 100. When the fluctuating magnetic field generator 4 generates a rotating magnetic field, the magnetic stirrer 3 rotates so as to rotate. As a result, a swirling flow is generated in the solution 1 to stir the solution 1. The rotation direction may be either clockwise or counterclockwise, or may be a combination of both. However, since it is necessary to make the movement of the magnetic stirrer 3 follow the magnetic field generated by the fluctuating magnetic field generator 4, a magnetic field that rotates at a constant cycle is preferable to an irregular magnetic field. Therefore, unless otherwise specified in the following description, the magnetic stirrer 3 rotates in a certain direction as shown in FIG. 2, and the fluctuating magnetic field generator 4 rotates in the same direction as the rotation direction of the magnetic stirrer 3. A magnetic field shall be generated.

A magnetic material of a permanent magnet or an electromagnet is arranged inside the fluctuating magnetic field generator 4. The magnetic field generated by the fluctuating magnetic field generator 4 can be changed by driving a permanent magnet or controlling the strength of the magnetic field of the electromagnet.

FIG. 3 is a configuration example in which the fluctuating magnetic field generator 4 uses a permanent magnet. When driving a permanent magnet, a rotating magnetic field can be generated by rotating a rotating disk 5 on which a magnet 7 is placed by a motor 6.

FIG. 4 is a configuration example in which the fluctuating magnetic field generator 4 uses an electromagnet. When driven by an electromagnet, an alternating current is generated by applying alternating current to the coil 9 wound around the electromagnet 8 through a power source 10. In order to rotate the magnetic stirrer 3 at a constant speed, it is preferable to arrange a plurality of electromagnets 8, and it is desirable that four or more electromagnets 8 are arranged. A rotating magnetic field is generated by controlling the phase difference of the AC magnetic field given from each electromagnet 8, and the magnetic stirrer 3 is rotated in one direction.

Both the configuration of FIG. 3 and the configuration of FIG. 4 can generate a rotating magnetic field. However, it is easier to use the electromagnet 8 because the thickness of the fluctuating magnetic field generator 4 is thin. When the thickness of the device is thin, there is an advantage that the fluctuating magnetic field generator 4 can be easily incorporated into an analyzer or the like as described later. Further, in the configuration using the electromagnet 8, the magnitude of the magnetic field generated from the fluctuating magnetic field generator 4 can be reduced by cutting off the current flowing through the coil 9 after stirring. This makes it possible to reduce the influence of the magnetic field on the magnetic particles as described later.

In order to apply a sufficient magnetic field to the magnetic stirrer 3 by the magnetic field from the magnetic material arranged inside the fluctuating magnetic field generator 4 and rotate it by the magnetic attraction force, the magnetic material and magnetism inside the fluctuating magnetic field generator 4 It is preferable that the distance between the stirrer 3 and the stirrer 3 is as close as possible. Since the range in which the magnetic field of a general magnet is sufficient is about 2 cm, the distance between the magnetic material inside the fluctuating magnetic field generator 4 and the magnetic stirrer 3 is preferably 2 cm or less, preferably 1 cm or less. Is more preferable.

When a magnet such as a magnetic stirrer 3 is arranged in the vicinity of the magnetic particles, the magnetic particles are attracted to the magnet by the magnetic attraction force of the magnetic field generated by the magnet. When the magnetic agitator 3 is a ferromagnetic material, the magnetic particles are aggregated toward the magnetic agitator 3 by the magnetic attraction of the magnetic agitator 3. Therefore, the force that separates the magnetic particles due to the swirling flow generated by the magnetic stirrer 3 from the magnetic stirrer needs to be larger than the magnetic attraction force of the magnetic stirrer 3. In order to realize this, the rotation speed of the magnetic stirrer 3 (that is, the frequency of the rotating magnetic field generated by the fluctuating magnetic field generator 4) is preferably 100 rpm or more, preferably 500 rpm or more, as in the commercially available stirrer device. More preferred. The larger the frequency of the rotating magnetic field, the greater the force that separates the magnetic particles from the magnetic stirrer, and the time for equalizing the concentration of the magnetic particles can be shortened. However, if the frequency of the rotating magnetic field is extremely high, the movement of the magnetic stirrer 3 will not follow the rotating magnetic field, so it is preferably 10,000 rpm or less, and typically 3000 rpm or less as used in a commercially available stirrer. Is. By rotating the magnetic stirrer 3 within this range, the magnetic particles are separated from the magnetic stirrer and dispersed in the solution at a uniform concentration.

When a magnet such as a magnetic stirrer 3 is arranged in the vicinity of the magnetic particles, the magnetic particles aggregate with each other due to the influence of the magnetic field generated by the magnet. When the magnetic particles aggregate, in addition to changing the kinetic characteristics of the particles, the surface area of the magnetic particles decreases, and the reaction efficiency when reacting the magnetic particles with the reagent decreases. Further, in the biochemical immunoassay device, the number of antigens and antibodies that can be adsorbed on the surface of magnetic particles is reduced. However, as a result of the study by the inventor of the present application, when the magnetic particles have normal magnetism or supernormal magnetism, even if the magnetic particles are once magnetized and aggregated, the magnetic particles are separated to a place where the magnetic field of the magnetic stirrer 3 does not sufficiently reach. As a result, it was found that the residual magnetization of the magnetic particles became close to zero, the properties as a magnet were lost, and the aggregation of the magnetic particles could be eliminated. Typically, the magnitude of the magnetic flux density on the surface of the magnetic stirrer 3 is about 10 to 100 mT. When the distance from the surface of the magnetic stirrer 3 is 1 cm or more, the magnetic flux density is reduced to about 10% or less of the size on the surface, and when the distance is 3 cm or more, the magnetic flux density is reduced to about 0.1 mT or less. Therefore, if the magnetic particles are separated from the surface of the magnetic stirrer 3 by 3 cm or more, the aggregation of the magnetic particles can be sufficiently reduced. In particular, by recovering the magnetic particles dispersed in the solution by the dispensing mechanism, the magnetic particles can be moved out of the range of the magnetic field exerted by the magnetic stirrer 3 and the aggregation of the magnetic particles can be prevented.

FIG. 5 is a configuration example of the dispensing mechanism. Here, an example in which the dispensing nozzle 12 is used as the dispensing mechanism is shown. The dispensing nozzle 12 is arranged on the upper part of the container 2. The solution 1 is sucked in by lowering the dispensing nozzle 12 and inserting it into the solution 1 to create a negative pressure inside the dispensing nozzle 12. The dispensing nozzle 12 is raised together with the collected solution, moved horizontally, and the solution is discharged into another reagent or sample.

FIG. 6 is another configuration example of the dispensing mechanism. A solution recovery flow path is connected to the lower part of the container 2. The valve 13 allows the solution to flow into the flow path. However, in the biochemical immunoassay device, a plurality of reagent containers for magnetic particles are arranged, and if a dispensing mechanism using a valve 13 is arranged for each container, a complicated structure tends to occur. A dispensing mechanism using the injection nozzle 12 is preferable. Unless otherwise specified in the following description, the dispensing mechanism shall use the dispensing nozzle 12 of FIG. The recovery amount and the discharge amount of the solution may be freely set for each application, and in the biochemical immunoassay device, about 10 to 100 μL of the solution is dispensed.

The procedure for recovering the solution by a dispensing mechanism using a nozzle will be described below. Since the recovery of the solution is typically carried out after the rotation of the magnetic stirrer 3 is stopped, the behavior of the magnetic particles when the rotation of the magnetic stirrer 3 is stopped will be described first.

FIG. 7 is a schematic diagram of a magnetic field generated inside the container 2 by the magnetic stirrer 3. Of the magnetic particles once dispersed in the solution by the rotation of the magnetic stirrer 3, the magnetic particles 11 existing within the reach of the magnetic field of the magnetic stirrer 3 are the magnetic stirrer 3 due to the magnetic attraction generated by the magnetic stirrer 3. Attracted to and settles. The shading inside the container 2 in FIG. 7 schematically shows the strength of the magnetic flux density (the dark place has a strong magnetic flux density). Since the magnetic flux density is large in the vicinity of the magnetic stirrer 3, the settling speed of the magnetic particles is also high. At a place sufficiently distant from the magnetic stirrer 3, the magnetic flux density becomes as small as about 0.1 mT or less, and the magnetic attraction force is smaller than the gravity in this region, so that the settling speed of the magnetic particles is sufficiently slow. Therefore, when recovering the magnetic particles by the dispensing mechanism, it is preferable to recover the magnetic particles from a place 10 mm or more away from the surface of the magnetic stirrer 3 so that the amount of change in the magnetic particle concentration is relatively small. More preferably, the solution near the liquid surface may be recovered, and specifically, the solution having a height of 3 mm or less from the liquid surface may be recovered.

However, if the solution recovery from the same container is repeated, the liquid level position gradually lowers, so it is necessary to recover the solution in the vicinity of the magnetic stirrer 3 when the residual liquid amount is small. In order to reduce the dead volume of the solution in the container 2, it is preferable to recover the liquid amount so that the liquid level position is sufficiently close to the magnetic stirrer 3 and the distance between the two is 2 mm or less. In such a case, if the rotation of the magnetic stirrer 3 is stopped, the magnetic particles will largely settle in a short time and the concentration of the magnetic particles will fluctuate. It is preferable to recover the magnetic particles within 1 second so that the amount of movement of the magnetic particles is further 20% or less. The calculation method of the time until recovery will be described in detail in the experimental results described later.

In order to dispense without causing the fluctuation of the magnetic particle concentration as described above, it is preferable to insert the dispensing nozzle 12 in a state where the magnetic stirrer 3 is rotated to recover the solution. However, if the magnetic stirrer 3 is recovered in a rotated state, pressure fluctuations may occur and bubbles may enter the solution, making it impossible to recover an accurate amount. Therefore, more preferably, the nozzle tip is kept in the vicinity of the liquid surface during the three rotations of the magnetic stirrer, and the nozzle tip is in the solution immediately after the magnetic stir bar 3 is stopped (within 5 seconds, preferably within 1 second). It is better to insert it in and collect the solution.

The magnetic agitator 3 is configured by using a magnetic material driven by the magnetic attraction force of the magnetic field generated by the fluctuating magnetic field generator 4. Typically, a permanent magnet such as a neodymium magnet, a samarium-cobalt magnet, or an alnico magnet is used so that a strong magnetic attraction is generated by the magnetic field generated by the fluctuating magnetic field generator 4. However, when a permanent magnet is used as the material of the magnetic stirrer 3, the magnetic particles aggregate on the magnetic stirrer 3 as described above. It is better to use what you have. Alternatively, a soft magnetic material such as soft ferrite is also desirable because the hysteresis of the magnetization curve is small and the magnetic flux density due to residual magnetization is also small. When a permanent magnet is used as the material of the magnetic stirrer 3, the magnitude of the magnetic flux density on the surface of the magnetic stirrer 3 is 10 mT or more. When the magnetic stirrer 3 having a small residual magnetization and a magnetic flux density on the surface of about 1 mT or less is used, the influence of the magnetic attraction force on the magnetic particles is greatly affected by stopping the magnetic field of the fluctuating magnetic field generator 4. Can be reduced. Unless otherwise specified in the following description, the magnetic stirrer 3 shall be composed of a permanent magnet having a surface magnetic flux density of 10 mT or more.

Further, by coating the periphery of the magnetic material with a resin such as PTFE (polytetrafluoroethylene), PEEK (polyetheretherketone), PVDF (polyvinylidene fluoride), contamination in the solution can be prevented.

FIG. 8 is an example of the shape of the magnetic stirrer 3. The magnetic stirrer 3 may have an ellipsoidal spherical shape as shown in FIG. 8 (a), which is relatively easy to manufacture, and is shown in FIG. 8 (b) having a plurality of blades so as to have more excellent stirring efficiency. The shape may be as shown in FIG. 8 (c), which has a hollow portion in the center so that the magnetic stirrer 3 and the dispensing nozzle 12 do not interfere with each other when the dispensing nozzle 12 descends from the upper part. It may be in shape. In this case, the diameter of the cavity is larger than the diameter of the tip of the dispensing nozzle 12.

FIG. 9 is a diagram illustrating the size of the magnetic stirrer 3. FIG. 9A is a top view of the magnetic stirrer 3 rotating in the container 2. When the magnetic stirrer 3 rotates in the direction shown in FIG. 9A, the locus through which the magnetic stirrer 3 passes is a circle 201. In the present invention, the diameter of the circle 201 is defined as the length of the magnetic stirrer 3. In order to show the definition of the length and the thickness of the magnetic stirrer 3, FIG. 9B shows a top view and a cross-sectional view of the ellipsoidal spherical magnetic stirrer 3 as an example. The circle 202 in FIG. 9A is the largest circle that can be arranged inside the container 2. In the present invention, the diameter of the circle 202 is defined as the inner diameter of the container 2.

Since the magnetic stirrer 3 passes through the inside of the circle 201, if another member is arranged inside the circle 201, the member interferes with the magnetic stirrer 3 and cannot be rotated as designed. Therefore, the length of the magnetic stirrer 3 needs to be smaller than the inner diameter of the container 2. It is preferable to use a magnetic stirrer 3 having an appropriate size according to the size of the container 2. The container used for the biochemical immunoassay device or the like has an inner diameter of about 10 to 30 mm and a height of about 30 to 100 mm. Therefore, the magnetic stirrer 3 has a length of about 5 to 25 mm and a thickness of about 1 to 10 mm.

In order to obtain a strong stirring force by the rotation of the magnetic stirrer 3, it is preferable to use the magnetic stirrer 3 as long as possible, but on the other hand, the magnetic stirrer 3 rotates without interfering with the wall surface of the container 2. Must be smaller than the inner diameter of the container 2. Therefore, the length of the magnetic stirrer 3 is preferably 30 to 80% of the inner diameter of the container 2. In order to obtain a strong stirring force, it is desirable that the magnetic stirrer 3 has a structure as thick as possible, but the thickness of the magnetic stirrer 3 does not have a great influence on the stirring force as compared with the length. Further, when the thickness of the magnetic stirrer 3 becomes thicker, the magnetic stirrer 3 interferes with the nozzle when the nozzle descends from the upper part in the structure shown in FIGS. 8 (a) and 8 (b). In order to reduce the dead volume of the solution, it is preferable to recover from the bottom of the container 2 to about 5 mm or less. Therefore, when the structure of FIGS. 8A and 8B is used, the thickness of the magnetic stirrer 3 is also 1 to 5 mm. Is preferable. However, when the vicinity of the magnetic stirrer 3 is close to 2 mm or less, the rate at which the magnetic particles aggregate on the magnetic stirrer 3 becomes very high, so that the thickness of the magnetic stirrer 3 is more preferably 1 to 3 mm.

Hereinafter, the detection mechanism when an error occurs in the stirring device 100 will be described. In an automated device such as a biochemical immunoanalyzer, a magnetic stirrer 3 that should have been originally placed in the container 2 is placed in the container 2 due to a human error of the device user, a trouble of the stirring device 100, or the like. It is possible that no error will occur. If the magnetic stirrer 3 is not placed in the container 2, the solution 1 will not be agitated. When the magnetic stirrer 3 is arranged so as to lean against the wall surface of the container 2, or when the positional relationship between the magnetic stirrer 3 and the fluctuating magnetic field generator 4 is not appropriate, the magnetic stirrer 3 rotates as desired. It may not be an exercise, but an aperiodic exercise. In the present invention, the state of such movement is called a violent state, and the solution 1 is not efficiently agitated in the violent state. When in a violent state, it is preferable to move the container 2 and the fluctuating magnetic field generator 4 in order to shift the position of the magnetic stirrer 3 and arrange it at an appropriate position. Alternatively, the position of the magnetic stirrer 3 may be changed by modulating the magnetic field of the fluctuating magnetic field generator 4, stopping the magnetic field once, and generating the magnetic field again.

FIG. 10 is an example of an observation unit for observing the behavior of the magnetic stirrer 3. In an analyzer automated to stir a large number of containers a day, it is preferable to have a mechanism for automatically detecting the presence / absence of the magnetic stirrer 3 and the violent state as described above. The stirrer observation unit 14 observes the behavior of the magnetic stirrer 3 from the outside of the container 2 and transmits the data obtained by the observation to the arithmetic unit 15 (for example, a computer). The arithmetic unit 15 can determine the rotational state of the magnetic stirrer 3 according to the received data.

FIG. 11 is a specific example of the stirrer observation unit 14. In FIG. 11A, the stirrer observation unit 14 includes an irradiation unit 16a that irradiates the magnetic stirrer 3 with light, and a light receiving unit 16b that receives the reflected light 17 reflected from the surface of the magnetic stirrer 3. .. The light receiving unit 16b outputs a detection signal corresponding to the received light intensity. When the magnetic stirrer 3 is rotating, the detection signal fluctuates according to its rotation frequency. FIG. 11B is an example of a detection signal. When the magnetic stirrer is rotating normally, a signal having a periodic waveform synchronized with the rotation frequency of the stirrer is obtained. When the stirrer is not placed in the container, the reflected wave of the stirrer cannot be obtained and shows a steady value. Further, when the stirrer is in a violent state, a signal having an irregular irregular waveform is obtained. The arithmetic unit 15 can determine the state of the magnetic stirrer 3 according to these time-varying waveforms. Alternatively, the state of the magnetic stirrer 3 is determined by converting the time-varying waveform into a graph of the power spectrum using FFT (Fast Fourier Transform) and examining the power at the frequency corresponding to the rotation speed of the rotating magnetic field. May be good.

The stirrer observation unit 14 may observe the rotational state by, for example, measuring a magnetic field. Since the magnetic field outside the container 2 fluctuates periodically due to the rotation of the magnetic stirrer 3, the motion of the magnetic stirrer 3 can be observed from the detection signal of the magnetic sensor 16c by arranging the magnetic sensor 16c outside the container 2. When light measurement is used, light is irradiated from the outside of the container 2 to measure the reflected wave of the stirrer. Therefore, it is preferable that the material of the container 2 is a translucent material, but when magnetic field measurement is used, it is preferable. There is an advantage that the container 2 does not have to be permeable.

The stirrer observation unit 14 may observe the rotational state by sound (vibration). When the magnetic stirrer 3 is in a violent state, the magnetic stirrer 3 collides with the side wall of the container 2 or the like, and a collision noise is generated. By observing this collision sound, it is possible to detect a rampage state or the like. As another configuration, the rotational state may be observed by irradiating light from the outside of the container 2 and measuring the absorption and scattering light of the solution. When the magnetic stirrer 3 rotates appropriately to stir the solution 1, a certain magnetic particle concentration is reached. Therefore, by measuring absorption and scattered light to check the magnetic particle concentration, it is indirectly magnetic. The movement of the stirrer 3 can be detected.

FIG. 12 is an example in which the stirrer observation unit 14 is arranged below the container 2. In FIG. 12, the fluctuating magnetic field generator 4 includes a plurality of electromagnets 8, and the stirrer observation unit 14 is arranged at the center of each electromagnet (lower part of the container). The light emitted vertically upward from the stirrer observation unit 14 is reflected from the magnetic stirrer 3 and is measured by the light receiving unit 16b. When the fluctuating magnetic field generator 4 uses a method in which the permanent magnet is rotated by a motor, it is difficult to arrange the stirrer observation unit 14 at the lower part of the container 2, but when the electromagnet 8 is used, the container 2 is used. It is relatively easy to place at the bottom. By arranging the electromagnet 8 around the stirrer observation unit 14 as shown in FIG. 12, a module in which the stirrer observation unit 14 and the fluctuating magnetic field generator 4 are integrated can be configured. It is easy to install and the device size can be made small. The stirrer observation unit 14 using optical measurement as described above has the advantages of being inexpensive and having high detection sensitivity.

FIG. 13 is an example of a mechanism for driving the dispensing nozzle 12. The dispensing nozzle 12 is attached by an arm, and can be rotationally driven around the support portion 18 and further vertically driven as needed.

FIG. 14 is a top view of the analyzer. The analyzer is equipped with a stirring device 100, and the solution 1 is stirred using the stirring device 100. In an automated device such as a biochemical immunoassay device, a reagent container in which two or more types of reagent containers are connected in series is used in order to mix and react a plurality of reagents. In FIG. 14, as an example, assuming that two types of containers are included in addition to the container containing magnetic particles, a total of three types of reagent containers are arranged so as to be connected in the radial direction of the container disk. The reagent container containing the magnetic particle-containing solution is arranged adjacent to each other in a ring shape on the container disk 19. The container disk 19 is rotationally driven by a drive device (not shown), whereby each container 2 on the container disk 19 rotates in the same direction. The solution 1 to be agitated is moved to the upper part of the fluctuating magnetic field generator 4 by the rotational drive of the container disk 19. After that, the fluctuating magnetic field generator 4 is operated to stir the solution 1.

The movement of the magnetic stirrer 3 during stirring is detected by the stirrer observation unit 14, and the solution 1 is stirred until the magnetic particles reach a predetermined concentration. The dispensing mechanism rotates and lowers the dispensing nozzle 12 on the upper part of the dispensing tip mounting position 20, and press-fits the dispensing tip into the tip of the dispensing nozzle 12 for mounting. The dispensing nozzle 12 equipped with the dispensing tip lowers the tip of the dispensing tip into the solution 1 by rotational driving and vertical driving of the dispensing mechanism, and sucks a predetermined amount. The timing of suction may be stirring or immediately after stirring as described above. The dispensing nozzle 12 that has collected the solution moves to the solution introduction position 21 again by rotational driving and vertical driving of the dispensing mechanism, and discharges the solution. When the ejection is completed, the dispensing nozzle 12 moves to the upper part of the dispensing tip disposal hole 22 and discards the used dispensing tip from the dispensing tip disposal hole 22. The series of operations shown here is an example, and does not necessarily have to be in the above order, and some operations may be omitted or added.

The magnetic stirrer 3 may be put in the magnetic particle-containing solution by the operator when the container 2 containing the magnetic particle-containing solution is erected on the container disk 19, or the magnetic particle-containing solution is shipped from a factory or the like. At that time, the magnetic stirrer 3 may be housed in the container 2 in advance. Alternatively, a charging mechanism 25 for charging the magnetic stirrer 3 may be arranged on the upper part of the container disk 19 or the like, and the magnetic stirrer 3 may be charged into the container 2 before stirring.

FIG. 15A is a schematic side sectional view of the container disk 19. The container disk 19 is supported by, for example, a rotating body 23. The fluctuating magnetic field generator 4 is arranged below the container disk 19. The position where the fluctuating magnetic field generator 4 is arranged needs to be a place where the container disk 19 and the rotating body 23 do not interfere with each other when they are being driven. Therefore, in order to easily incorporate the variable magnetic field generator 4 into the apparatus, the variable magnetic field generator 4 preferably has a small structure, and the variable magnetic field generator 4 using the electromagnet 8 is easy to incorporate because it is thin. In order to give sufficient magnetic attraction to the magnetic agitator 3, it is desirable that the distance between the fluctuating magnetic field generator 4 and the magnetic agitator 3 is as close as possible. The distance from the surface of the fluctuating magnetic field generator 4 to the surface of the magnetic stirrer 3 is preferably within 2 cm, more preferably within 1 cm.

FIG. 15B is a schematic side sectional view showing another configuration example of the container disk 19. In order for the magnetic stirrer 3 and the fluctuating magnetic field generator 4 to be as close as possible to each other, it is preferable to provide a through hole in the container disk 19 and accommodate the container 2 in the through hole. In this case, for example, a mechanism for gripping the container 2 from the side of the container 2 may be provided.

The fluctuating magnetic field generator 4 preferably includes a drive mechanism that moves up and down. In this case, when the container 2 to be agitated is arranged on the upper part of the fluctuating magnetic field generator 4, the fluctuating magnetic field generator 4 rises by the drive mechanism to approach the magnetic stirrer, and after stirring, the fluctuating magnetic field generator 4 4 can be lowered and separated.

If a member having a relative magnetic permeability larger than 1 is arranged in the vicinity of the fluctuating magnetic field generator 4, the magnetic field generated by the fluctuating magnetic field generator 4 is distorted. It is preferably configured. More preferably, a member having a relative permeability of 1.02 or less that does not stick to a magnet may be used, and the container disk 19 may be made of a material such as aluminum or resin. It is not always necessary to keep the relative magnetic permeability of all the members of the container disk 19 within this range, and the relative magnetic permeability of the members arranged within about 3 cm around the fluctuating magnetic field generator 4 may be reduced.

FIG. 16 shows an example in which the solution suction position and the stirring position by the fluctuating magnetic field generator 4 are separated from each other. In FIG. 16, for convenience of explanation, only one container 2 is shown. As shown in FIG. 16 (a), after stirring the solution at a place where the fluctuating magnetic field generator 4 and the stirrer observation unit 14 are arranged in the vicinity, the rotation drive of the container disk 19 causes FIG. 16 (b). Move the reagent container set to the indicated solution suction position. Then, the dispensing nozzle 12 is lowered to suck the solution.

FIG. 17 is an example in which a plurality of stirring positions are provided. In the configuration of FIG. 17, the solution can be agitated at another place even while the solution is being sucked by the dispensing nozzle 12. Therefore, the agitated container 2 can be moved to the suction position immediately after suction, and the next solution can be sucked. Further, since the solution can be stirred at two or more stirring positions at the same time, the solution can be efficiently stirred and dispensed. In particular, when two or more stirring positions are provided, the smaller the amount of the solution, the faster the settling speed of the magnetic particles after stirring. Therefore, it is preferable to preferentially suck the magnetic particles from the container 2 having the smaller amount of solution.

Since each reagent arranged on the container disk 19 is generally stored at a low temperature, the entire container disk 19 is arranged in a constant temperature bath at a low temperature of about 4 ° C. The fluctuating magnetic field generator 4 dissipates heat by a built-in electromagnet or motor, but it is cooled by arranging it in a low-temperature constant temperature bath, so that deterioration can be prevented. It is preferable to dissipate heat efficiently by arranging a heat sink on the electromagnet 8 or the motor and bringing the heat sink into contact with the wall surface of the low temperature constant temperature bath.

The following shows an experimental example in which the effect of this embodiment is verified. It was verified that the variable magnetic field generator 4 in the present invention can recover a solution having a predetermined concentration without agglomeration of magnetic particles.

FIG. 18 is an example showing how superparamagnetic magnetic particles aggregate with each other. FIG. 18A is a photograph of an optical microscope when a solution containing magnetic particles is inverted and stirred and mixed, and the solution is dispensed and dropped onto a glass plate. FIG. 18B is a photograph when an external magnetic field of about 10 mT is applied in the horizontal direction to the dropped magnetic particles. As is clear when comparing FIGS. 18 (a) and 18 (b), the directions of magnetization of the magnetic particles are aligned by applying an external magnetic field, so that the magnetic particles aggregate with each other by magnetic attraction to form a rod-shaped cluster. There was found. In such an aggregated state, problems such as a decrease in reaction efficiency with the reagent occur.

FIG. 19 is an example showing the behavior of the magnetic particles when the external magnetic field applied to the magnetic particles is removed. 19 (a) shows a state in which an external magnetic field is applied, FIG. 19 (b) shows a state 3 seconds after the external magnetic field is removed, and FIG. 19 (c) shows a state 10 seconds after the external magnetic field is removed. The state is a photograph taken by an optical microscope. As is clear from the results of FIG. 19, when the external magnetic field applied to the superparamagnetic magnetic particles is removed, the residual magnetization quickly becomes close to zero, so that the formation of rod-shaped clusters between the magnetic particles is eliminated and the aggregated structure is formed. It turns out that it becomes impossible to maintain.

FIG. 20 is an example of a histogram of the magnetic particle area by image analysis. A state in which the particle area is large means that the particles are aggregated and the area is increased. In other words, the higher the proportion of monodisperse particles, the higher the proportion of particles with a small particle area. FIG. 20 (a) is a solution (corresponding to FIG. 18 (a)) that is stirred by overturning and mixing a container containing the solution (hereinafter referred to as overturned stirring), and FIG. 20 (b) is a solution after overturning stirring. (Corresponding to FIG. 18 (b)), in which an external magnetic field is applied to the agitator, and FIG. It is a solution. In FIG. 20 (b), since the rod-shaped cluster was formed, the peak derived from one particle was small, and the peak derived from two particles or three particles was remarkably observed. As shown in FIGS. 20 (a) and 20 (c), the particle area histogram during magnetic field stirring is equivalent to the result during inversion stirring, and there is no change in the single particle ratio, so that there is no adverse effect on aggregation due to magnetic field stirring. There was found.

FIG. 21 is a diagram showing the results of verifying the difference in magnetic particle concentration depending on the stirring method. The measurement result of FIG. 21 is the particle concentration ratio after stirring with a pencil mixer (hereinafter referred to as mixer stirring), overturning stirring, and magnetic field stirring for sufficient time. For mixer stirring and overturning stirring, the solution was recovered within 5 seconds after stirring, and for magnetic field stirring, the solution being stirred was recovered. The collected solutions were all near the liquid level. The particle concentration ratio shown in FIG. 21 defines the value of the magnetic particle concentration obtained by stirring with a mixer as 100%, and by calculating the ratio with this magnetic particle concentration, the particle concentrations of each of the overturning stirring and the magnetic field stirring are obtained. The ratio was calculated. The magnetic particle concentration was measured using the absorbance, a calibration curve was prepared in advance for the relationship between the magnetic particle concentration and the absorbance, and the magnetic particle concentration was calculated from the value of the absorbance after stirring. As a result of the measurement, it was found that there was no difference in the concentration of the magnetic particles in any of the stirring methods, and it was confirmed that there was no adverse effect on the particle concentration due to the magnetic field stirring.

The magnetic field agitation in FIG. 21 is a recovery of the agitated solution. As mentioned above, if there is a time lag between stopping stirring and recovering the solution, the magnetic attraction force exerted by the magnetic stirrer may cause the magnetic particles to settle significantly, so it is necessary to examine the effect of this magnetic attraction force. be. The equation of motion of the force acting on the magnetic particles in the Z-axis direction (direction from the lower part of the container to the upper part of the container) in a state where the magnetic stirrer 3 is not rotated can be expressed as follows.

m _p α = F _g + F _m (z) + F _η ... (Equation 1)

m _p is the particle mass, α is the acceleration in the Z-axis direction, F _g is the gravity, F _m (z) is the magnetic attraction force to the magnetic particles existing at a point z away from the surface of the stirrer in the Z-axis direction, and F _η is. Shows viscous force. F _m (z) can be expressed as d / dz (MB (z)) by using the magnetic moment M of the magnetic particles and the magnetic flux density B (z) at the point z. In the case of mixer stirring or overturning stirring, the component of F _m (z) does not appear, and the component of the setting force is only F _g . In the magnetic field agitation, since the magnetic agitator 3 is contained in the solution, a component of _Fm (z) is present. Therefore, in order to calculate the time required to suck the solution after stirring, it is necessary to estimate the magnetic moment M and the magnetic flux density B (z) of the magnetic particles. M is derived from the characteristics of the magnetic particles, and B (z) is derived from the characteristics of the stirrer.

FIG. 22 is a graph showing the results of measuring the magnetic flux density according to the distance from the magnetic stirrer 3. Here, M-280 was used as a typical magnetic particle, and the magnetic stirrer 3 was verified using a typical one having a diameter of φ3 mm and a length of 8 mm. The surface magnetic field of the magnetic stirrer 3 used is about 30 mT, which is a general value. The black line in FIG. 22 shows the magnetic flux density at a point z away from the surface of the magnetic stirrer 3, and the magnetic flux density equation B (z) = at a point z away from the surface of a sphere having a radius _R which is a residual magnetic Br. It is a theoretical line fitted considering that it can be approximated to 2B _r R ^3/3 (R + Z) ³ . As shown in FIG. 22, it was found that it can be approximated well by setting Br = 50 mT and _R = 2.5 mm. Further, from the results of FIG. 22, when the distance from the stirrer surface is 10 mm or more, the magnetic flux density is sufficiently smaller than the magnetic flux density on the stirrer surface, and when the distance is 20 mm or more, the stirrer is sufficiently attenuated and the stirrer is driven by the fluctuating magnetic field generator 4. It turned out to be small enough to be difficult. Further, when the distance from the surface of the stirrer is 30 mm or more, the size is generally about 0.01 mT or less, which is about the same as the geomagnetism, and the influence of the magnetic field by the magnetic stirrer 3 can be almost ignored.

FIG. 23 shows the results of calculating F _m (z) and F _g by linearly approximating the characteristics of the magnetic particles M-280. According to the literature values (Geir Fonnum, et al. Characterisation of Dynabeads by magnetization measurements and Mossbauer spectroscopy, Journal of Magnetism and Magnetic Materials, vol. 293, 2005.), The characteristics of the magnetic particles M-280 are almost linear in the range of 100 mT or less. Since it changes to, it can be expressed as M = amp B ( _z ) using the proportionality constant a. When F _m (z) and F _g were calculated using the above equations, it was found that they could be expressed as shown in FIG. 23. Since the horizontal axis is z and F _g does not depend on z, it shows a constant value. The intersection of F _m (z) and F _g in FIG. 23 means that F _m (z) = F _g , and when z is larger than the intersection, gravity is superior to the magnetic attraction. ing. That is, it was found that when Z = 10 mm or more, the sedimentation force is mainly composed of gravity rather than the magnetic attraction force, and when Z = 30 mm or more, the influence of the magnetic attraction force is almost negligible.

FIG. 24 is a graph showing the result of calculating the particle moving speed. From Stokes' equation, it can be expressed as F _η = 6πηrv (z) using the viscosity η, the particle moving velocity v (z), the particle radius r, and the viscosity η. Since α = 0 can be approximated when the particle movement velocity v (z) is constant, the amount of particle movement in water is calculated by solving Equation 1 as shown in FIG. 24. The magnetic particles existing at a place sufficiently distant from the stirrer (z = 50 mm) have a small magnetic flux density acting on the magnetic particles, so that the amount of movement is small, but the magnetic particles near the stirrer (z = 2 mm) have a magnetic flux. Since the density is high, the amount of movement is also large. Generally, when a particle moves 100 μm or more, the particle concentration at the time of recovery may fluctuate greatly and may fluctuate by 1% or more. do. That is, it is preferable to recover within 60 seconds when the distance from the liquid surface to the surface of the stirrer is Z = 50 mm, and it is possible to recover within 5 seconds when the distance from the liquid surface to the surface of the stirrer is Z = 2 mm. preferable.

FIG. 25 is a graph showing the particle concentration ratio of the solution recovered from the vicinity of the liquid surface. At Z = 50 mm and Z = 2 mm, the particle concentration ratio decreased by 10% or more after 10 s and 60 s, respectively, and it was found that the particle concentration ratio was generally in agreement with the prediction of the theoretical formula. In order to maintain the performance in the analyzer, the magnetic particle concentration needs to be at least 90% or more, preferably 99% or more. Therefore, when the concentration is reduced as shown in FIG. 25, the desired characteristics cannot be obtained. From the above verification experiment, it was found that it is preferable to recover the solution within 5 seconds in order to recover the solution to the place where the liquid level is Z = 2 mm so that the residual liquid amount is sufficiently reduced.

In FIGS. 24 and 25, the case where the liquid level height z is 2 mm and the case where the liquid level height z is 50 mm are compared. It is considered desirable to recover the solution 1 within a shorter time after the rotation of the solution is stopped.

<About a modification of the present invention>
The present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one including all the described configurations. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. Further, it is possible to add / delete / replace a part of the configuration of each embodiment with another configuration.

The position, size, shape, range, etc. of each configuration shown in the drawings and the like may not represent the actual position, size, shape, range, etc. in order to facilitate understanding of the invention. Therefore, the present invention is not necessarily limited to the position, size, shape, range and the like disclosed in the drawings and the like.

1: Solution 2: Container 3: Magnetic stirrer 4: Variable magnetic field generator 5: Rotating disk 6: Motor 7: Magnet 8: Electromagnet 9: Coil 10: Power supply 11: Magnetic particles 12: Dispensing nozzle 13: Valve 14: Stirrer observation unit 15: Arithmetic device 16a: Irradiation unit 16b: Light receiving unit 16c: Magnetic sensor 17: Reflected light 18: Support unit 19: Container disk 20: Dispensing chip mounting position 21: Solution introduction position 22: Dispensing chip disposal Hole 23: Rotating body 25: Input mechanism 100: Stirrer

Claims (23)

A stirring device that stirs a solution containing paramagnetic magnetic particles.
A container holder for holding a container containing a solution containing the magnetic particles and a magnetic stirrer,
A fluctuating magnetic field generator that applies the fluctuating magnetic field to the magnetic stirrer by generating a fluctuating magnetic field.
Equipped with
The magnetic stirrer is rotated by the fluctuating magnetic field to stir the solution in the container, thereby diffusing the magnetic particles in the solution .
The force that separates the magnetic particles from the magnetic stirrer by the swirling flow generated by the magnetic stirrer is greater than the magnetic attraction that the magnetic stirrer attracts the magnetic particles when the magnetic stirrer rotates. Is also big
A stirring device characterized by that. The stirring device according to claim 1, wherein the fluctuating magnetic field generator is arranged below the container holding portion. The stirring device according to claim 1, wherein the fluctuating magnetic field generator includes an electromagnet that generates the fluctuating magnetic field. The stirring device according to claim 1, wherein the magnetic stirrer has a magnetic material and a coat that coats the magnetic material. The stirring device according to claim 1, further comprising a stirring device observing unit for observing the rotational operation of the magnetic stirring device. The fluctuating magnetic field generator includes an electromagnet that generates the fluctuating magnetic field.
Both the fluctuating magnetic field generator and the stirrer observation unit are arranged below the container holding unit.
The stirring device according to claim 5, wherein the electromagnet is arranged along the outer periphery of the stirring bar observation unit. The stirrer observation unit is
Irradiation unit that irradiates the magnetic stirrer with detection light,
A light receiving unit that receives the detection light reflected from the magnetic stirrer and outputs a detection signal according to the intensity of the detection light.
Equipped with
The stirring device according to claim 5, further comprising a calculation unit for determining whether or not the magnetic stirring device is normally rotating according to a change in the detection signal over time. The stirrer observation unit includes a magnetic field measuring unit that detects a magnetic field generated from the magnetic stirrer and outputs a detection signal according to the intensity thereof.
The stirring device according to claim 5, further comprising a calculation unit for determining whether or not the magnetic stirring device is normally rotating according to a change in the detection signal over time. The container holding portion has a through hole penetrating the container holding portion.
The stirring device according to claim 1, wherein the through hole has a diameter capable of accommodating the container. The stirring device according to claim 1, wherein the magnetic stirrer has paramagnetism. The stirring device according to claim 1.
Dispensing nozzle for dispensing the solution,
An analyzer characterized by being equipped with. 11. The analyzer according to claim 11, wherein the magnetic stirrer includes a hole having a diameter larger than the tip diameter of the dispensing nozzle. The analyzer according to claim 11, further comprising a charging mechanism for charging the magnetic stirrer into the container. The analyzer further comprises a constant temperature bath for accommodating the container and adjusting the temperature of the container.
11. The analyzer according to claim 11, wherein the fluctuating magnetic field generator further includes a heat sink that dissipates heat generated from the fluctuating magnetic field generator by coming into contact with the constant temperature bath. It is a dispensing method for dispensing a solution containing paramagnetic magnetic particles.
The step of stirring the solution using the stirring device according to claim 1.
A suction step in which a dispensing nozzle is inserted into the solution and the solution is sucked into the dispensing nozzle.
A dispensing method characterized by having. The dispensing method comprises moving the dispensing nozzle above the container containing the solution to be dispensed while the magnetic stirrer is rotating.
15. The dispensing method according to claim 15, wherein the suction step is performed while the magnetic stirrer is rotating or after the magnetic stirrer has stopped rotating. When the liquid level height of the solution is the first height, the suction step is performed between the time when the fluctuating magnetic field generator stops the operation of generating the fluctuating magnetic field and the time when the first time elapses. Carry out,
When the liquid level height of the solution is a second height smaller than the first height, it is shorter than the first time after the operation of generating the fluctuating magnetic field is stopped by the fluctuating magnetic field generator. The dispensing method according to claim 15, wherein the suction step is performed until the second time elapses. The stirring device according to claim 1, wherein the length of the magnetic stirrer is between 30% and 80% of the inner diameter of the container. The stirring device according to claim 1, wherein the thickness of the magnetic stirrer is between 1 mm and 3 mm. The stirring device according to claim 1, wherein the magnetic stirring element has a magnetic characteristic that the magnetic flux density of the residual magnetization is 1 mT or less. The stirring device according to claim 1, wherein the fluctuating magnetic field generator is arranged at a position where the distance between the magnetic stirrer and the magnetic material of the fluctuating magnetic field generator is within 20 mm. .. The stirring device according to claim 1, wherein the fluctuating magnetic field generator generates a rotating magnetic field having a rotation speed of 500 rpm or more and 3000 rpm or less. The stirring device according to claim 1, wherein the container holding portion is configured by using a member having a relative magnetic permeability of 1.02 or less.

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