JP2020204509A - Detection device and container - Google Patents

Abstract

To provide a detection device and a container capable of preventing bumping.SOLUTION: According to an embodiment, a detection device 20 includes: a container 25; an irradiation device; and a detection sensor 22. The container includes: an outer layer and an inner layer having a void which prevents an object to be detected contained in a sample and an antibody for fixing the object to be detected to a carrier from entering. The irradiation device irradiates a first suspension containing the medium, the antibody, the carrier and the sample with a microwave. The detection sensor detects the object to be detected to which the carrier is fixed from the first suspension.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to detection devices and containers.

Some detection devices that detect organic substances such as microorganisms put a suspension containing the object to be detected and the beads in a container in order to fix the beads to the object to be detected. The detector heats the suspension by irradiating the inside of the container with microwaves.

Such detectors can rapidly raise the temperature of the suspension by heating with microwaves.
As a result, the detector may cause bumping.

Japanese Unexamined Patent Publication No. 2015-14542

In order to solve the above problems, a detection device and a container capable of preventing bumping are provided.

According to the embodiment, the detection device includes a container, an irradiation device, and a detection sensor. The container comprises an outer layer and an inner layer having voids through which the object to be detected contained in the sample and the antibody fixing the object to be detected to the carrier do not enter. The irradiation device irradiates a first suspension containing the medium, the antibody, the carrier, and the sample with microwaves. The detection sensor detects the object to be detected on which the carrier is immobilized from the first suspension.

FIG. 1 is a diagram showing a configuration example of a detection system according to an embodiment. FIG. 2 is a block diagram showing a configuration example of the information processing apparatus according to the embodiment. FIG. 3 is a diagram showing a structural example of the container according to the embodiment. FIG. 4 is a diagram showing an operation example of the detection system according to the embodiment. FIG. 5 is a diagram showing an operation example of the detection system according to the embodiment.

Hereinafter, embodiments will be described with reference to the drawings. It should be noted that each figure is a schematic view for facilitating the understanding of the embodiment, and its shape, dimensions, ratio, and the like can be appropriately changed in design.

The detection system according to the embodiment detects organic substances (objects to be detected) such as bacteria contained in the sample. The detection system irradiates a detection sensor having a predetermined structure with an electromagnetic wave having a predetermined frequency and detects a transmitted wave transmitted through the detection sensor. In addition, the detection system uses an antibody to fix beads (carrier) that affect the electrical characteristics of the detection sensor and organic substances (detection object) such as bacteria supported by the carrier to the object to be detected in a predetermined container. To do.

The detection system measures the transmittance of the detection sensor before depositing the sample and the transmittance of the detection sensor after depositing the sample. The detection system determines that the sample contains an object to be detected if the two transmittances do not match.

FIG. 1 shows a configuration example of the detection system 1. As shown in FIG. 1, the detection system 1 includes an information processing device 10 and a detection device 20. The information processing device 10 and the detection device 20 are connected to each other so as to be able to communicate with each other.

The information processing device 10 controls the entire detection system 1. That is, the information processing device 10 controls the detection device 20. The information processing device 10 transmits a control signal to the detection device 20 to control each unit. Further, the information processing device 10 receives various signals from each part of the detection device 20. The information processing device 10 determines whether or not the sample contains an object to be detected based on signals from each unit and the like.
The information processing device 10 will be described in detail later.

The detection device 20 fixes the beads 32 to the object to be detected 34 included in the sample under the control of the information processing device 10. Further, the detection device 20 provides the information processing device 10 with information necessary for detecting the object to be detected 34 according to the control from the information processing device 10.

As shown in FIG. 1, the detection device 20 includes a light source 21, a detection sensor 22, a sensor holder 23, an optical sensor 24, a container 25, a charging device 26, a microwave generator 27, a sampling device 28, and the like. In addition to the configuration shown in FIG. 1, the detection device 20 may further include a configuration as required, or a specific configuration may be excluded from the detection device 20.

The light source 21 irradiates the detection sensor 22 with an electromagnetic wave having a predetermined frequency based on the control from the information processing device 10. Further, the light source 21 may irradiate the detection sensor 22 with electromagnetic waves having a plurality of frequencies.

The detection sensor 22 detects the object to be detected 34 contained in the sample. Here, the detection sensor 22 detects the object 34 to which the beads 32 are fixed from the suspension 40 containing the sample. The detection sensor 22 has a predetermined frequency characteristic with respect to transmittance. The detection sensor 22 transmits the electromagnetic wave from the light source 21 to the optical sensor 24 with a predetermined transmittance. Further, the transmittance of the detection sensor 22 changes when the object to be detected 34 and the beads 32 fixed to the object to be detected 34 adhere to the surface of the detection sensor 22. For example, the detection sensor 22 is composed of a base material, a structure, and the like.

The base material is formed, for example, into a rectangle having a predetermined size. The base material is preferably made of a material that does not change with respect to the electromagnetic waves emitted by the light source 21. That is, it is desirable that the base material is made of a material having transparency in the frequency band of the electromagnetic wave emitted by the light source 21. For example, the base material is composed of a silicon wafer or the like. Further, the base material may be composed of an organic material such as polyethylene.

For example, the thickness of the substrate is in the range of 100-800 μm. For example, the thickness of the base material is 525 μm.
The material and outer dimensions of the base material are not limited to a specific configuration.

The structure transmits the electromagnetic waves emitted by the light source 21. The structure has frequency characteristics with respect to transmittance.

For example, the structure is made of a conductor such as gold or aluminum. The structure may be a structure including a plurality of layers. For example, the structure may include a layer such as chromium or titanium as an adhesive layer to the substrate.
For example, the thickness of the structure is in the range of 0.1 μm to 50 μm. For example, the thickness of the structure is 0.2 μm.

For example, the structure has a predetermined shape and a predetermined size of voids.
The structure forms a complementary split ring resonator by means of voids. The structure forms an LCR (inductance, conductance, resistance) circuit by voids. The structure has resonance characteristics at a predetermined resonance frequency by the LCR circuit.

Further, the structure may have a plurality of types of voids having different predetermined shapes or sizes.
The structure forms a plurality of LCR circuits having different characteristics (mainly LCR circuits having different inductances) by a plurality of types of voids. The structure has a peak in frequency characteristics with respect to transmittance by each LCR circuit.

The structure can have different frequency characteristics (different peaks) by adjusting the size or shape of the voids.
For example, the detection sensor 22 is set by an operator from the outside.

Further, the frequency of the electromagnetic wave emitted by the light source 21 may be a frequency corresponding to the frequency of the peak of the transmittance of the detection sensor 22. For example, the frequency of the electromagnetic wave emitted by the light source 21 is a frequency near the peak frequency. For example, the frequency of the electromagnetic wave emitted by the light source 21 may be selected from the frequency range in which the transmittance is below or above a predetermined threshold value.

The sensor holder 23 moves the detection sensor 22 according to the control from the information processing device 10. For example, the sensor holder 23 moves the detection sensor 22 to a position where the electromagnetic wave from the light source 21 is irradiated. That is, the sensor holder 23 moves the electromagnetic wave to the detection sensor 22 so that the focus of the electromagnetic wave is aligned with the detection sensor 22.

Further, the sensor holder 23 moves the detection sensor 22 to a position where the sample from the container 25 can be received. For example, the sensor holder 23 moves the detection sensor 22 to a position adjacent to the container 25.

For example, the sensor holder 23 is composed of a motor, a drive belt, and the like. The sensor holder 23 moves the detection sensor 22 by driving a drive belt or the like with a driving force of a motor or the like. The configuration of the sensor holder 23 is not limited to a specific configuration.

The optical sensor 24 detects the transmitted wave from the detection sensor 22. The optical sensor 24 detects the intensity of the transmitted wave. For example, the optical sensor 24 outputs electric power according to the intensity of the transmitted wave. The optical sensor 24 transmits a sensor signal indicating the intensity of the transmitted wave to the information processing device 10.

The container 25 is a reaction container for storing a sample, beads 32, an antibody 33, a medium 31, and the like. The container 25 stores the sample, beads 32, and antibody 33 in a dispersed state in the medium 31. The container 25 has an open portion at the upper end. The container 25 will be described in detail later.

The charging device 26 loads various components into the container 25 according to the control from the information processing device 10. For example, the charging device 26 charges the sample, beads 32, antibody 33, medium 31, and the like into the container 25.

The charging device 26 may charge the beads 32, the antibody 33, and the medium 31 stored in advance into the container 25.
Further, the charging device 26 may load a sample set by the operator from the outside into the container 25.
For example, the loading device 26 may be composed of a pipette or the like.

The microwave generator 27 (irradiation device) irradiates the contents stored in the container 25 with microwaves. The microwave generator 27 heats the beads 32, the medium 31, and the like in the container 25 by irradiating the microwave. For example, the microwave generator 27 irradiates an electromagnetic wave having a wavelength of 1 mm to 1 m.

For example, the microwave generator 27 is installed above the container 25. The microwave generator 27 irradiates the microwave downward. The microwave generator 27 irradiates the inside of the container 25 with microwaves.

The sampling device 28 collects the liquid (suspension 40, etc.) in the container 25 according to the control from the information processing device 10. The sampling device 28 drops the collected liquid onto the detection sensor 22.
For example, the sampling device 28 may be composed of a pipette or the like.

Next, the information processing device 10 will be described.
FIG. 2 shows a configuration example of the information processing device 10 according to the embodiment. FIG. 2 is a block diagram showing a configuration example of the information processing device 10. As shown in FIG. 2, the information processing device 10 includes a processor 11, a ROM 12, a RAM 13, an NVM 14, a communication unit 15, an operation unit 16, a display unit 17, and the like.

The processor 11, the ROM 12, the RAM 13, the NVM 14, the communication unit 15, the operation unit 16, and the display unit 17 are connected to each other via a data bus or the like.
In addition to the configuration shown in FIG. 2, the information processing device 10 may have a configuration as required, or a specific configuration may be excluded from the information processing device 10.

The processor 11 has a function of controlling the operation of the entire information processing device 10. The processor 11 may include an internal cache, various interfaces, and the like. The processor 11 realizes various processes by executing a program stored in advance in the internal memory, ROM 12 or NVM 14.

It should be noted that some of the various functions realized by the processor 11 executing the program may be realized by the hardware circuit. In this case, the processor 11 controls the function executed by the hardware circuit.

The ROM 12 is a non-volatile memory in which a control program, control data, and the like are stored in advance. The control program and control data stored in the ROM 12 are incorporated in advance according to the specifications of the information processing apparatus 10.

The RAM 13 is a volatile memory. The RAM 13 temporarily stores data and the like being processed by the processor 11. The RAM 13 stores various application programs based on instructions from the processor 11. Further, the RAM 13 may store data necessary for executing the application program, an execution result of the application program, and the like.

The NVM 14 is a non-volatile memory capable of writing and rewriting data. The NVM 14 is composed of, for example, an HDD (Hard Disk Drive), an SSD (Solid State Drive), a flash memory, or the like. The NVM 14 stores a control program, an application, various data, and the like according to the operational use of the information processing apparatus 10.

The communication unit 15 is an interface for communicating with the detection device 20. For example, the communication unit 15 is an interface that supports a wired or wireless LAN (Local Area Network) connection. Further, the communication unit 15 may be an interface that supports USB (Universal Serial Bus) connection.

The operation unit 16 receives inputs of various operations from the operator. The operation unit 16 transmits a signal indicating the input operation to the processor 11. The operation unit 16 may be composed of a touch panel.

The display unit 17 displays the image data from the processor 11. For example, the display unit 17 is composed of a liquid crystal monitor. When the operation unit 16 is composed of a touch panel, the display unit 17 may be formed integrally with the operation unit 16.
For example, the information processing device 10 is a desktop PC, a notebook PC, a tablet PC, or the like.

Next, the container 25 will be described.
FIG. 3 shows a structural example of the container 25 according to the embodiment. As shown in FIG. 3, the container 25 includes an outer layer 251 and a film 252 and the like.

The outer layer 251 constitutes the outer layer of the container 25. The outer layer 251 is provided with an open portion at the upper portion. For example, the outer layer 251 has a bottle-shaped or tray-shaped structure. For example, the outer layer 251 is made of glass, metal, resin, plastic, or the like.

The outer layer 251 may have a structure in which the bottom is V-shaped.
The structure and material of the outer layer 251 are not limited to a specific configuration.

A film 252 (inner layer) is formed on the inner wall of the outer layer 251.
The film 252 is formed on the side surface of the inner wall of the outer layer 251. For example, the film 252 is formed in a ring shape. That is, the film 252 is formed so as to orbit the side surface.

The film 252 may be formed on a part of the side surface. Further, the film 252 may be formed on the bottom surface of the inner wall of the outer layer 251. Further, the film 252 may be formed in a plurality of regions of the inner wall.

For example, the film 252 is made of glass, metal, resin, plastic, or the like.
The region where the film 252 is formed and the material of the film 252 are not limited to a specific configuration.

In addition, the film 252 has a plurality of voids 253.
The void 253 is a recess in the medium 31 that can contain air due to surface tension or the like. That is, the void 253 holds air in the medium 31.

The void 253 has a size that prevents the antibody 33 and the object to be detected 34 from entering the inside. For example, the void 253 is smaller than the size of antibody 33 and object 34 to be detected.
For example, the void 253 has a size of several tens of μm or less.

It should be noted that at least a part of the plurality of voids 253 may have a size that prevents the antibody 33 and the object to be detected 34 from entering the inside.
Further, the container 25 may be charged into the detection device 20 by an operator from the outside. The container 25 may be a disposable container.

Next, an operation example of the information processing device 10 will be described. The operation realized by the information processing device 10 is realized by the processor 11 executing a program stored in the ROM 12 or the NVM 14.

First, the processor 11 performs an operation of fixing (modifying) the antibody 33 to the beads 32 in the container 25.

FIG. 4 shows an operation example of fixing the antibody 33 to the beads 32. Here, it is assumed that the container 25 is set in the detection device 20 by an operator or the like.

The processor 11 controls the charging device 26 and the like to charge the medium 31, beads 32, antibody 33, and the like into the container 25.

The medium 31 is a liquid that disperses beads 32, an antibody 33, a substance to be detected 34, and the like as a dispersoid. For example, the medium 31 is water, saline solution, or the like. The configuration of the medium 31 is not limited to a specific configuration.

The beads 32 are beads made of a magnetic material. For example, the beads 32 are beads made of a ferromagnetic material.

For example, the beads 32 have a structure in which iron oxide particles having a diameter of several nm are dispersed or contained in a polymer such as polystyrene, silica, or agarose. For example, the beads 32 are formed to have a size of several tens of nm to several μm.

The antibody 33 is an antibody that fixes the object to be detected 34 to the beads 32. The antibody 33 has a binding site that binds to the beads 32. In addition, antibody 33 has a binding site that binds to the object to be detected 34.
The medium 31, beads 32 and antibody 33 make up suspension 40 (second suspension).

When the medium 31, beads 32, antibody 33, and the like are charged into the container 25, the processor 11 irradiates the microwave from the microwave generator 27. That is, the microwave generator 27 irradiates the suspension 40 with microwaves.
The processor 11 may stir the suspension 40 using a stirrer or the like while irradiating with microwaves.

When the microwave generator 27 irradiates the suspension 40 with microwaves, the medium 31 constituting the suspension 40 is heated. For example, a dielectric such as water constituting the medium 31 is vibrated and heated by microwaves.

Further, the beads 32 are heated by the microwaves irradiated by the microwave generator 27. For example, the magnetic material that makes up the beads 32 is heated by the non-resonant response of electron spins to microwaves.

By the above operation, the processor 11 heats the medium 31 and the beads 32 by irradiating the suspension 40 with microwaves. The processor 11 heats the suspension 40 by heating the medium 31 and the beads 32. By heating the suspension 40, the antibody 33 is rapidly immobilized on the beads 32.

Further, by heating the beads 32 and the medium 31, the air contained in the voids 253 of the membrane 252 is heated. The air in the void 253 expands by heating and is discharged from the void 253. As a result, bubbles 50 are generated in the suspension 40.

By generating bubbles 50 from each void 253 of the membrane 252, a large amount of bubbles 50 are generated in the suspension 40. The bubbles 50 suppress the bumping of the suspension 40.

When the operation of fixing the antibody 33 to the beads 32 is performed, the processor 11 performs the operation of fixing (modifying) the beads 32 to the object to be detected 34.

FIG. 5 shows an operation example of fixing the beads 32 to the object to be detected 34. Here, it is assumed that the sample including (possibly included) the object to be detected 34 is set in the detection device 20 by an operator or the like.

The processor 11 controls the charging device 26 and the like to charge the sample into the container 25. That is, the processor 11 produces a suspension 40 (first suspension) in which the sample is charged.

The substance to be detected 34 is a substance immobilized on the antibody 33. For example, the object to be detected 34 is an antigen, an organic substance such as a bacterium (lactic acid bacterium, Escherichia coli, etc.) or the like. The configuration of the object to be detected 34 is not limited to a specific configuration.

When the sample is charged into the container 25, the processor 11 irradiates the microwave from the microwave generator 27. That is, the microwave generator 27 irradiates the suspension 40 with microwaves.
The processor 11 may stir the suspension 40 using a stirrer or the like while irradiating with microwaves.

As described above, the processor 11 heats the medium 31 and the beads 32 by irradiating the suspension 40 with microwaves. The processor 11 heats the suspension 40 by heating the medium 31 and the beads 32.
By heating the suspension 40, the object to be detected 34 is rapidly immobilized on the antibody 33. That is, the object to be detected 34 is quickly fixed to the beads 32.

Further, as described above, the beads 32 and the medium 31 are heated to generate bubbles 50 in the suspension 40. The bubbles 50 suppress the bumping of the suspension 40.

When the operation of fixing the beads 32 to the object to be detected 34 is performed, the processor 11 performs an operation of measuring the transmittance (reference transmittance) of the detection sensor 22 in which no sample is deposited.
Here, it is assumed that the detection sensor 22 is set in the sensor holder 23 by an operator or the like.

For example, the processor 11 uses the sensor holder 23 to move the detection sensor 22 to a position where the electromagnetic wave from the light source 21 is irradiated. When the detection sensor 22 is moved to a position where the electromagnetic wave from the light source 21 is irradiated, the processor 11 irradiates the detection sensor 22 with the electromagnetic wave using the light source 21.

When the detection sensor 22 is irradiated with an electromagnetic wave using the light source 21, the processor 11 acquires the intensity of the transmitted wave from the detection sensor 22 by using the optical sensor 24. When the intensity of the transmitted wave is acquired, the processor 11 calculates the transmittance (reference transmittance) from the intensity of the transmitted wave and the intensity of the electromagnetic wave emitted by the light source 21.

When the operation of measuring the transmittance (reference transmittance) of the detection sensor 22 on which the sample is not deposited is performed, the processor 11 performs the operation of depositing the sample on the detection sensor 22.

The processor 11 uses the sensor holder 23 to move the detection sensor 22 to a position where the suspension 40 from the container 25 can be received. When the detection sensor 22 is moved to a position where the suspension 40 from the container 25 can be received, the processor 11 uses the sampling device 28 to collect the suspension 40 stored in the container 25 on the detection sensor 22. Drop into.

When the suspension 40 is dropped onto the detection sensor 22, the processor 11 waits until the dropped suspension 40 dries. The processor 11 may heat the dropped suspension 40 to accelerate drying. Further, the processor 11 may perform a process of excluding unnecessary components from the dropped suspension 40. Further, the processor 11 may perform a process of excluding unnecessary components from the suspension 40 before dropping the suspension.

The processor 11 drops the suspension 40 onto the detection sensor and dries it to deposit a sample containing (possibly contained) the object 34 to which the beads 32 are fixed on the detection sensor 22.

When the sample is deposited on the detection sensor 22, the processor 11 performs an operation of measuring the transmittance (detection transmittance) of the detection sensor 22 on which the sample is deposited.

The processor 11 uses the sensor holder 23 to move the detection sensor 22 to a position where the electromagnetic wave from the light source 21 is irradiated. When the detection sensor 22 is moved to a position where the electromagnetic wave from the light source 21 is irradiated, the processor 11 irradiates the detection sensor 22 with the electromagnetic wave using the light source 21.

When the detection sensor 22 is irradiated with an electromagnetic wave using the light source 21, the processor 11 acquires the intensity of the transmitted wave from the detection sensor 22 by using the optical sensor 24. When the intensity of the transmitted wave is acquired, the processor 11 calculates the transmittance (detected transmittance) from the intensity of the transmitted wave and the intensity of the electromagnetic wave emitted by the light source 21.

When the operation of measuring the transmittance of the detection sensor 22 on which the sample is deposited is performed, the processor 11 determines whether or not the sample contains the object to be detected 34 based on the measured reference transmittance and the detected transmittance.

When the object to be detected 34 is present on the detection sensor 22, the detection sensor 22 also has beads 32 fixed to the object to be detected 34. Therefore, the transmittance of the detection sensor 22 changes depending on the magnetic material constituting the object to be detected 34 and the beads 32.

Therefore, the processor 11 determines whether the reference transmittance and the detected transmittance match in order to determine whether the sample contains the object to be detected 34. For example, the processor 11 determines that if the difference between the reference transmittance and the detected transmittance is equal to or less than a predetermined threshold value, they match.

When the processor 11 determines that the two do not match, the processor 11 determines that the object to be detected 34 exists on the detection sensor 22. That is, the processor 11 determines that the sample contains the object to be detected 34.

On the other hand, when the processor 11 determines that the two match, it determines that the object to be detected 34 does not exist on the detection sensor 22. That is, the processor 11 determines that the sample does not include the object to be detected 34.

The processor 11 may display the determination result of whether or not the sample includes the object to be detected 34 on the display unit 17. Further, the processor 11 may output the determination result to the external device.

The processor 11 may replace the container 25 after fixing the antibody 33 on the beads 32. That is, the processor 11 may transfer the suspension 40 from the container 25 to a new container 25 after fixing the antibody 33 on the beads 32.

Further, the outer layer 251 may have a gap 253 on the inner wall as the inner layer. In this case, the container 25 does not have to include the membrane 252.

Further, the processor 11 may measure the reference transmittance and the detected transmittance by using electromagnetic waves having a plurality of frequencies. In this case, the processor 11 may determine that the sample does not contain the object to be detected 34 when each reference transmittance and each detected transmittance match. On the other hand, the processor 11 may determine that the sample contains the object to be detected 34 when there is one or more combinations that do not match.

Further, the processor 11 does not have to perform the operation of fixing the antibody 33 to the beads 32. For example, the detection device 20 may be one in which beads 32 on which the antibody 33 is immobilized are preset.

Further, the operator may charge the medium 31, beads 32, antibody 33, sample, and the like into the container 25. Further, the operator may drop the suspension 40 onto the detection sensor 22.

Further, the optical sensor 24 may detect the reflected light from the detection sensor 22. In this case, the processor 11 measures the reflectance of the detection sensor 22.

The processor 11 may also measure the reference permeability before immobilizing the beads 32 on the antibody 33 or the object to be detected 34.
Further, the processor 11 may determine whether the sample contains the object to be detected 34 based on the intensity of the transmitted light of the detection sensor 22 before and after the sample is deposited.

In the detection system 1 configured as described above, the suspension 40 containing the beads 32 and the antibody 33 or the object to be detected 34 is irradiated with microwaves in the container 25 having the film in which the void 253 is formed. , The antibody 33 or the object to be detected 34 is immobilized on the beads 32. At that time, the medium 31 and the beads 32 are heated by the irradiation of microwaves, and the bubbles 50 to which the heat is transferred expand to generate bubbles in the suspension 40. The detection system 1 can prevent bumping by the bubbles 50.

Further, the detection system 1 uses a container 25 having a membrane on the inside in which a gap 253 having a size that prevents the antibody 33 and the object to be detected 34 from entering is formed. Therefore, the detection system 1 can prevent the object to be detected 34 from entering the gap 253 or the object to be detected 34 from adhering to the film and changing the concentration of the object to be detected 34.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Detection system, 10 ... Information processing device, 11 ... Processor, 12 ... ROM, 13 ... RAM, 14 ... NVM, 15 ... Communication unit, 16 ... Operation unit, 17 ... Display unit, 20 ... Detection device, 21 ... Light source , 22 ... detection sensor, 23 ... sensor holder, 24 ... optical sensor, 25 ... container, 26 ... loading device, 27 ... microwave generator, 28 ... sampling device, 31 ... medium, 32 ... beads, 33 ... antibody, 34. ... Detected object, 40 ... suspension, 50 ... air bubbles, 251 ... outer layer, 252 ... film, 253 ... voids.

Claims (5)

A container including an outer layer and an inner layer having voids for fixing the object to be detected contained in the sample and the antibody that fixes the object to be detected to the carrier.
An irradiation device that irradiates a first suspension containing a medium, the antibody, the carrier, and the sample with microwaves.
A detection sensor that detects the object to be detected to which the carrier is fixed from the first suspension,
A detection device comprising. The carrier is composed of a magnetic material.
The detection device according to claim 1. The irradiation device is
A second suspension containing the medium, the carrier and the antibody was irradiated with the microwave.
The first suspension produced by putting the sample into the second suspension is irradiated with the microwave.
The detection device according to claim 1 or 2. The container has a membrane having the voids on the inner wall.
The detection device according to any one of claims 1 to 3. A container used in a detection device having an irradiation device for irradiating a first suspension containing a medium, a carrier, and a sample containing an object to be detected with microwaves.
With the outer layer
An inner layer having voids through which the object to be detected and the antibody fixing the object to be detected to the carrier do not enter, and
A container equipped with.