KR20240015326A - Device for Sample Pooling and Method of Pooling Test - Google Patents

Abstract

The sample pooling device according to the present invention includes a plurality of first coupling portions each coupled to a plurality of first storage containers capable of accommodating samples prepared in liquid form, and coupled to a second storage container capable of accommodating samples. It includes one or more second coupling units, and a plurality of metering units fluidly connected to each first coupling unit and metering a fixed amount of sample, wherein the number of first coupling units is greater than that of the second coupling units.

Description

{Device for Sample Pooling and Method of Pooling Test}

The present invention relates to a sample pooling device and sample pooling method that enable rapid pooling inspection by combining an adapter between individual storage containers and mixed storage containers.

Molecular diagnostics is currently a rapidly growing field in the in vitro diagnostic market for early diagnosis of diseases. Among them, methods using nucleic acids are useful for diagnosing causative genetic factors due to infections by viruses and bacteria, etc., based on high specificity and sensitivity.

Polynucleotide chain reaction (PCR) is the most widely used nucleic acid amplification reaction, a repeated cycle process of denaturation of double-stranded DNA, annealing of oligonucleotide primers to a DNA template, and primer extension by DNA polymerase. Includes (Mullis et al., US Pat. Nos. 4,683,195, 4,683,202 and 4,800,159; Saiki et al., (1985) Science 230, 1350-1354). Denaturation of DNA occurs at about 95 degrees, and annealing and extension of primers occur at a temperature lower than 95 degrees, between 55 and 75 degrees.

Conventional diagnostic tests for infectious diseases are conducted by individually processing samples from each individual and detecting target analytes. However, in this method, one kit must be used for one sample, which requires a lot of cost and time. Moreover, when the rate of positive reactions in a test is very low, most tests result in a negative reaction, but a separate test must be performed for each sample, resulting in a waste of money and time.

To solve this problem, a pooling test method in which multiple samples are mixed and tested is used.

Collection testing is a method of mixing samples from multiple people to make one sample, and if positive, retesting individually with the remaining sample. It is used to screen for infection in groups at risk of infection, such as those in nursing homes who do not have symptoms but require periodic testing to prevent infection. It is being used usefully.

According to the collection test method known to date, it is known that even if 10 samples are mixed and tested, a sensitivity of more than 96% compared to individual samples can be maintained.

Currently, the combined testing method is being actively studied overseas because it allows for rapid and large-scale testing, and was even introduced in JAMA (The Journal of the American Medical Association), a world-renowned medical journal, as a method for efficient use of limited resources. It has been done.

The present invention simplifies the task of workers manually collecting a fixed amount of sample using a pipette from individual storage containers and transferring it to a mixed storage container, simply by combining an adapter between the individual storage containers and the mixed storage container. A sample pooling device and sample pooling method capable of quantitative pooling are provided.

In addition, it solves contamination problems that may occur when pipetting while the cap of each storage container is open, and provides a sample pooling device and sample pooling method that allows easy and accurate traceability of mixed samples.

A sample pulling device according to the present invention includes a plurality of first coupling parts each coupled to a plurality of first storage containers capable of accommodating samples prepared in a liquid state; One or more second coupling portions coupled to a second storage container capable of receiving a sample; and a plurality of metering units fluidly connected to each of the first coupling units and metering a fixed amount of sample, wherein the number of first coupling units may be greater than that of the second coupling units.

At this time, it may further include a mixing unit whose inlet is fluidly connected to the outlet of the metering unit and whose outlet is fluidly connected to the second coupling unit.

Additionally, the number of first coupling parts may be three times or more than the number of second coupling parts.

In addition, it may further include a first valve provided upstream of the metering unit and capable of opening and closing the flow path.

Here, it may further include a second valve provided downstream of the metering unit and capable of opening and closing the flow path, and the metering unit may be a metering chamber having a fixed volume between the first valve and the second valve.

Here, at least one of the first valve and the second valve may include a blocking portion capable of opening and closing the metering chamber and a bridge connecting each of the blocking portions corresponding to the plurality of metering chambers.

Here, the plurality of blocking units connected to the bridge can move together to simultaneously open and close the plurality of metering chambers.

Additionally, the plurality of metering units may be arranged in parallel in a straight line or curved direction.

Additionally, the blocking unit is provided to be movable in a direction that is different from the direction in which the plurality of metering chambers are arranged, so that the metering chamber can be opened and closed.

Alternatively, the blocking unit may be provided to be movable in one direction in which the plurality of metering chambers are disposed to open and close the metering chamber.

In addition, it further includes a first valve body located on an inlet side of the plurality of metering units, wherein the first valve body includes a plurality of blocking units that block the inlets of the plurality of metering units, and the plurality of first coupling units, respectively. A plurality of first valve passages communicating with the plurality of metering unit inlets may be provided.

Here, it further includes a second valve body located on the outlet side of the plurality of metering units, wherein the second valve body includes a plurality of blocking units that block the outlets of the plurality of metering units, the second coupling unit, and the plurality of It may be provided with a plurality of second valve passages each communicating with the outlet of the metering unit.

Alternatively, the plurality of metering units may be arranged in a circumferential direction.

Alternatively, the plurality of blocking portions and the plurality of first valve passages or the plurality of blocking portions and the plurality of second valve passages may be provided alternately in the circumferential direction.

Additionally, a main body provided with the plurality of metering units arranged in the circumferential direction on one plane; a first valve body provided to be relatively rotatable on one side of the main body; And it may include a second valve body rotatably provided on the other side of the main body.

Here, at least one of the first valve body and the second valve body includes a plurality of blocking units that block passages communicating with the plurality of metering units and a plurality of blocking units that connect the passages communicating with the plurality of metering units. A valve flow path may be provided.

A sample pulling device according to another aspect of the present invention includes a first coupling hole coupled to a first storage container capable of accommodating a sample prepared in a liquid state; a plurality of first flow paths each fluidly connected to the plurality of first coupling holes; a plurality of second flow paths fluidly connecting each of the first flow paths; a single second coupling hole fluidly connected to the plurality of second flow paths and coupled to a single second storage container capable of accommodating a sample; and a plurality of metering chambers provided between each of the first flow paths and each of the second flow paths and having a volume capable of accommodating a fixed amount of sample.

At this time, the plurality of metering chambers may all have the same volume.

Additionally, the number of first coupling holes may be set in a range between 3 and 5.

In addition, it may further include a mixing chamber that fluidly connects the plurality of second flow paths and the single second coupling hole and mixes the plurality of samples contained in the plurality of first storage containers.

Here, a flow meter provided behind the outlet of the mixing chamber may be further included.

Additionally, a main body including the plurality of metering chambers; A plurality of blocking units movably coupled to one side of the main body and capable of opening and closing the entrances of the plurality of metering chambers, respectively, connect the entrances of the plurality of metering chambers and the plurality of first flow paths, respectively. A first valve body having one valve passage; And it may further include a second valve body movably coupled to the other side of the main body and having a plurality of blocking portions that can respectively open and close the outlets of the plurality of metering chambers.

Here, the plurality of metering chambers are arranged in parallel in a straight line or curved direction, and at least one of the first valve body and the second valve body may be provided to slide relative to the main body.

Alternatively, the plurality of metering units may be arranged in a circumferential direction, and at least one of the first valve body and the second valve body may be provided to be rotatably movable relative to the main body.

Alternatively, in the first valve body, the plurality of blocking portions and the plurality of first valve passages may be provided alternately.

Additionally, the blocking unit may include a sealing member.

A method of pooling a sample using a sample pulling device according to another embodiment of the present invention, comprising: (a) coupling the first storage container to two or more of the plurality of first coupling parts; (b) opening the first valve while the second valve is closed; (c) closing the first valve when a fixed amount of sample is received in the metering chamber; and (d) opening the second valve. A pulling inspection method may be provided.

At this time, the volume of the sample accommodated in the first storage container may be larger than the volume of the metering chamber.

Additionally, in step (c), the first valve may be closed after the metering chamber is full.

In addition, the sample pooling device further includes a flow sensor provided in the first flow path, and in step (c), if it is determined that a predetermined volume is accommodated in the metering chamber through the flow rate information obtained from the flow sensor, The first valve can be closed.

In addition, after the second valve opening step, the step of providing negative pressure to the second coupling hole may be further included.

In an embodiment of the present invention, rapid sample pooling is possible by simply connecting the container containing the sample to the adapter and then adjusting the valve without quantitative collection using a pipette during the pulling operation.

Additionally, in the embodiment of the present invention, when mixing multiple samples, they can be stored combined in a storage container pooled on an adapter, eliminating the risk of incorrectly recording the pooled data.

Additionally, embodiments of the present invention can prevent sample contamination problems that may occur by working with the stopper open when pooling a large number of samples.

1 is a perspective view showing a sample pooling device according to a first embodiment of the present invention.
Figure 2 is a cross-sectional view showing the sample moving in the sample pulling device according to the first embodiment of the present invention, Figure 2(a) shows the first valve in an open state, and Figure 2(b) shows the first valve in an open state. shows a blocked state, and Figure 2(c) shows a state in which the second valve is open.
Figure 3 is a perspective view showing a sample pooling device according to a second embodiment of the present invention.
Figure 4 is a cross-sectional view showing the sample moving in the sample pulling device according to the second embodiment of the present invention, Figure 4(a) shows the first valve in an open state, and Figure 4(b) shows the first valve in an open state. shows a blocked state, and Figure 4(c) shows a state in which the second valve is open.
Figure 5 is a perspective view showing a sample pooling device according to a third embodiment of the present invention.
Figure 6 is an exploded perspective view of Figure 5.
Figure 7 is a cross-sectional view showing the sample moving in the sample pulling device according to the third embodiment of the present invention, Figure 7(a) shows the first and second valves in a blocked state, and Figure 7(b) shows the state in which the first and second valves are blocked. Indicates that the first and second valves are open.

Hereinafter, the present invention will be described in detail through examples and illustrative drawings. These examples are only for illustrating the present invention in more detail, and it will be apparent to those skilled in the art that the scope of the present invention is not limited by these examples according to the gist of the present invention. .

In addition, when adding reference numerals to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Additionally, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), (i), (ii), etc. may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected," "coupled," or "connected" to another component, that component may be directly connected or connected to the other component, but there is another component between each component. can be understood as being able to be “connected,” “coupled,” or “connected.”

Samples collected by the sample pooling device and sample pooling method according to an embodiment of the present invention can be used in various diagnostic systems such as molecular diagnosis and immunodiagnostics. Alternatively, it may be used for experiments or data analysis rather than diagnosis.

As an example, samples collected by the sample pooling device and sample pooling method according to an embodiment of the present invention can be used in a nucleic acid amplification device. A nucleic acid amplification device refers to a device that performs a nucleic acid amplification reaction to amplify a nucleic acid having a specific nucleotide sequence. In particular, it refers to a device that performs a nucleic acid amplification reaction through temperature control.

As used herein, “sample” may include biological samples (e.g., cells, tissues, and fluids from biological sources) and non-biological samples (e.g., food, water, and soil). The biological samples include viruses, bacteria, tissues, cells, blood (e.g. whole blood, plasma and serum), lymph, bone marrow fluid, saliva, sputum, swabs, aspiration, milk and urine. , feces, ocular fluid, semen, brain extract, spinal fluid, joint fluid, thymic fluid, bronchial lavage fluid, ascites, and amniotic fluid. Additionally, the sample may include natural and synthetic nucleic acid molecules isolated from biological sources. According to one embodiment of the present invention, the sample may include additional substances such as water, deionized water, saline solution, pH buffer, acidic solution, and basic solution.

And in this specification, “sample” may include a specimen collected from a patient. And in this specification, “pooled sample” may mean a state in which samples collected from different patients are mixed.

Additionally, in this specification, “sample” may refer to a primary collection sample in which samples collected from different patients are mixed. In this case, the “collected sample” may mean a secondary collected sample that is a mixture of different primary collected samples.

And the sample container is used to accommodate the sample to be analyzed, and can be of various types, such as a tube, a vial, a strip with multiple single tubes connected, and a multiple tubes connected with each other. Includes plate, microcard, chip, cuvette or cartridge.

The pooling test is a method of mixing samples from several people to make one sample, and if positive, retesting individually with the remaining samples. According to the collection test method known to date, it is known that even if 10 samples are mixed and tested, a sensitivity of more than 96% compared to individual samples can be maintained.

Sample pooling refers to the process of mixing multiple samples for combined testing. The automatic sample pooling system according to an embodiment of the present invention mixes several samples in one receiver using a sample transport means, and matches the samples with the receiver to enable tracking of individual specimens when confirmed positive.

In this specification, specimen and sample may be used with different meanings depending on the case, or may be used with the same meaning. A sample may refer to a specimen sample collected from a patient, or, in the case of secondary pooling, may include a pooled sample obtained by pooling specimen samples. That is, in this specification, a sample is used in a broad sense as an object of pooling, and may be a specimen sample or the result of primary pooling for secondary pooling.

Additionally, in this specification, sample and sample container may be used with distinct meanings or may be used with the same meaning.

Figure 1 is a perspective view showing a sample pooling device 10 according to a first embodiment of the present invention. And Figure 2 is a cross-sectional view showing the sample moving in the sample pulling device according to the first embodiment of the present invention, Figure 2(a) shows the first valve in an open state, and Figure 2(b) shows the first valve in the open state. Figure 2(c) shows a state in which the valve is blocked, and Figure 2(c) shows a state in which the second valve is open.

Referring to Figures 1 and 2, the sample pooling device 10 according to the first embodiment of the present invention includes a first coupling portion 100 and a second storage container 52 that are coupled to the first storage container 51. It may include a second coupling portion 400 coupled to and a connecting portion 200 connecting the first coupling portion 100 and the second coupling portion 400. In addition, the sample pulling device 10 may further include a first valve 310 capable of opening and closing the inlet side of the connection portion 200 and a second valve 320 capable of opening and closing the outlet side of the connection portion 200. there is.

The first storage container 51 can accommodate a sample from each individual or a sample containing the sample, and the number of first storage containers 51 can be multiple. Hereinafter, sample will be used to include all specimens or samples containing specimens.

And the second storage container 52 can accommodate a mixture of samples from the plurality of first storage containers 51. The second storage container 52 may be one or multiple, and may be provided in fewer numbers than the first storage container 51.

For example, samples in three first storage containers 51 may be mixed and accommodated in one second storage container 52. Alternatively, the samples in five first storage containers 51 may be mixed and accommodated in one second storage container 52. Alternatively, 10 samples in the first storage container 51 may be mixed and accommodated in one second storage container 52. In addition, samples in a plurality of first storage containers 51 may be mixed and accommodated in one second storage container 52.

Alternatively, the samples in the six first storage containers 51 may be mixed and accommodated in the two second storage containers 52. Alternatively, the samples in the 10 first storage containers 51 may be mixed and accommodated in the 2 second storage containers 52 . Alternatively, the 20 samples in the first storage container 51 may be mixed and accommodated in the two second storage containers 52. In addition, the plurality of samples in the first storage container 51 may be mixed and accommodated in the second storage container 52, which is two or more but less than the number of the first storage container 51.

The first storage container 51 and the second storage container 52 may be provided in various forms such as tubes, test tubes, or vials. And the shape and capacity of the first storage container 51 and the second storage container 52 may be the same or different.

The first coupling portion 100 is connected to the first coupling hole 110 coupled to the inlet of the first storage container 51, and the first storage container 51 is coupled to the first coupling hole 110. It may include an inlet flow path 120 that provides a passage through which all or part of the sample in the first storage container 51 passes.

The first coupling hole 110 may be provided to surround the inlet portion of the first storage container 51 and may be provided in a shape corresponding to the inlet portion of the first storage container 51. For example, when the inlet portion of the first storage container 51 is provided in a cylindrical shape, the first coupling hole 110 is a cylinder having an inner diameter equal to or slightly larger than the outer diameter of the inlet portion of the first storage container 51. It may be a shape. Alternatively, the shape of the first coupling hole 110 may vary depending on the shape of the inlet portion of the first storage container 51.

The second coupling portion 400 is connected to the second coupling hole 430 coupled to the inlet of the second storage container 52, and the second storage container 52 is coupled to the second coupling hole 430. It may include an outlet passage 420 that provides a passage through which all or part of the sample passes into the second storage container 52. And the second coupling unit 400 may further include a mixing chamber 410 in which each sample delivered through the plurality of first coupling units 100 is mixed.

The mixing chamber 410 is provided with a plurality of inlet holes upstream, and each inlet hole is fluidly connected to the connection part 200. Additionally, an outlet hole fluidly connected to the outlet flow path 420 is provided downstream of the mixing chamber 410.

The second coupling hole 430 may be provided to surround the entrance of the second storage container 52 and may be provided in a shape corresponding to the entrance of the second storage container 52. For example, when the inlet portion of the second storage container 52 is provided in a cylindrical shape, the first coupling hole 110 is a cylinder having an inner diameter equal to or slightly larger than the outer diameter of the inlet portion of the second storage container 52. It may be a shape. Alternatively, the shape of the second coupling hole 430 may vary depending on the shape of the inlet portion of the second storage container 52.

One side of the connection part 200 may be connected to the first coupling part 100 and the other side may be connected to the second coupling part 400. Additionally, the connection portion 200 may be fluidly connected to the inlet flow path 120 through the first valve 310 and may be fluidly connected to the mixing chamber 410 through the second valve 320. And the connection part 200 may include a metering chamber 210 provided in the volume between the first valve 310 and the second valve 320.

The sample pooling device 10 according to the embodiment is provided with a metering chamber 210 so that it can receive a predetermined amount of sample from the first storage container 51. For example, when the first valve 310 located upstream of the metering chamber 210 is opened while the second valve 320 located downstream of the metering chamber 210 is closed, gravity, centrifugal force, or pneumatic force The sample in the first storage container 51 moves into the metering chamber 210. And when sufficient time has passed and the metering chamber 210 is filled with samples, the first valve 310 can be closed to obtain a fixed amount of sample. And when the second valve 320 is opened, a fixed amount of sample can pass through the second coupling portion 400 and be stored in the second storage container 52.

When a plurality of first coupling parts 100 and a plurality of connection parts 200 connected thereto are provided, each metering chamber 210 may be provided to have the same volume. Therefore, samples of the same volume can be collected from a plurality of first storage containers 51 and mixed in the second storage container 52.

The second coupling part 400 may further include a mixing chamber 410 fluidly connected to each of the metering chambers 210 of the plurality of connecting parts 200 . The mixing chamber 410 may be understood as a space where a fixed amount of sample is received from the metering chamber 210 and different samples are received from each metering chamber 210 and mixed.

The mixing chamber 410 has a plurality of inlet holes fluidly connected to each metering chamber 210, and has one or more outlet holes fluidly connected to one or more outlet flow paths 420.

Additionally, the sample pulling device 10 may further include a first instrument (not shown) capable of measuring the volume of fluid flowing into the metering chamber 210. When filling the metering chamber 210, the sample can be filled to a predetermined volume without the need for a separate meter. However, if you want to measure a sample with a volume smaller than the volume of the metering chamber 210, a separate meter may be required. . For example, a first measuring instrument may be provided in the first valve 310 to measure the flow rate passing through the first valve 310. Alternatively, the first measuring instrument may be provided upstream or downstream of the first valve 310.

Additionally, the sample pulling device 10 may further include a second instrument (not shown) capable of measuring the volume of fluid flowing out of the metering chamber 210. If no sample remains in the metering chamber 210 and the mixing chamber 410, a predetermined volume of the sample mixture can be delivered to the second storage container 52 without a separate measuring instrument. However, when it is desired to shorten the pooling time by accurately knowing when the remaining sample disappears, or when it is desired to accurately measure the amount of mixed sample delivered to the second storage container 52, a separate measuring instrument can be used. For example, a second measuring instrument may be provided in the second valve 320 to measure the flow rate passing through the second valve 320. Alternatively, the second instrument may be provided upstream or downstream of the second valve 320.

Referring again to FIG. 1, the first valve 310 may include a first bridge 311 and a plurality of first blocking portions 312 connected to the first bridge 311. The first blocking portions 312 may be provided in a number corresponding to the first coupling portion 100 or the connecting portion 200, and may be movably provided on the upstream side of each metering chamber 210. And the first blocking part 312 may be movable through an opening (first valve hole) provided on the upstream side of the connecting part 200.

The first bridge 311 is provided to connect each of the first blocking units 312, and the plurality of first blocking units 312 simultaneously open the entrance to the metering chamber 210 and simultaneously open the entrance to the metering chamber 210. It can be arranged to block.

And the first valve 310 is provided on the inner wall of the inlet flow path 120 of the first coupling part 100 or the upstream flow path of the connection part 200, or is installed in the first blocking part 312 of the first valve 310. It may further include a first sealing member provided. The first sealing member can prevent fluid from leaking when the first valve 310 is closed.

Additionally, the second valve 320 may include a second bridge 321 and a plurality of second blocking units 322 connected to the second bridge 321. The second blocking portions 322 may be provided in a number corresponding to the first coupling portion 100 or the connecting portion 200, and may be movably provided on the downstream side of each metering chamber 210. And the second blocking part 322 may be movable through an opening (second valve hole) provided on the downstream side of the connecting part 200.

The second bridge 321 is provided to connect each of the second blocking units 322, and the plurality of second blocking units 322 simultaneously open the outlet of the metering chamber 210 and simultaneously open the outlet of the metering chamber 210. It can be arranged to block.

And the second valve 320 may further include a second sealing member provided on the inner wall of the downstream passage of the connection portion 200 or provided on the second blocking portion 322 of the second valve 320. The second sealing member can prevent fluid from leaking when the second valve 320 is closed.

Meanwhile, the plurality of metering chambers 210 may be arranged in parallel in a straight line. Alternatively, the plurality of metering chambers 210 may be arranged in parallel in a curved (eg, circular arc) direction.

Additionally, the first and second valves 310 and 320 may reciprocate in a direction that is different from one direction (straight or curved) in which the plurality of metering chambers 210 are arranged.

Referring to FIG. 1, the first and second valves 310 and 320 can open and close the inlet of the metering chamber 210 while reciprocating in a direction perpendicular to the straight direction in which the plurality of metering chambers 210 are arranged. there is. In this case, the valve hole through which the blocking portions 312 and 322 move may be formed on surfaces where the connecting portion 200 and the bridges 311 and 321 face each other.

Specifically, the bridges 311 and 321 of the valves 310 and 320 are located on one side (front) of the connection portion 200, and each blocking portion 312 and 322 is connected to the connection portion 200 from the bridges 311 and 321. ) may be arranged to protrude toward. And the connection part 200 has a valve hole formed on the side facing the bridge 311 and 321, and the blocking part 312 and 322 passes through the valve hole and closes the valve passage to the upstream or downstream side of the metering chamber 210. can be blocked.

And the user can open the valves 310 and 320 by pulling the bridges 311 and 321, and block the valves 310 and 320 by pressing the bridges 311 and 321.

Alternatively, unlike Figure 1, the first valve and the second valve 310, 320 may open and close the inlet of the metering chamber 210 while reciprocating in a direction parallel to the straight direction in which the plurality of metering chambers 210 are disposed. You can. In this case, the valve hole through which the blocking portions 312 and 322 move may be formed on surfaces where adjacent connecting portions 200 face each other. And the blocking portions 312 and 322 may be bent at 90 degrees and connected to the bridges 311 and 321.

Figure 3 is a perspective view showing a sample pooling device according to a second embodiment of the present invention. And Figure 4 is a cross-sectional view showing the sample moving in the sample pulling device according to the second embodiment of the present invention, Figure 4(a) shows the first valve in an open state, and Figure 4(b) shows the first valve in the open state. Figure 4(c) shows a state in which the valve is blocked, and Figure 4(c) shows a state in which the second valve is open.

Referring to Figures 3 and 4, the sample pulling device 20 according to the second embodiment of the present invention includes a main body 1200 in which a plurality of metering chambers 1210 are formed, and a It may include a first valve body 1310 that is movable and a second valve body 1320 that is relatively movably coupled to the main body 1200.

The main body 1200 may have a plurality of first coupling parts 1100 formed at the top and one or more first coupling parts 1400 formed at the bottom. And the main body 1200 may be formed by a plurality of metering chambers 1210 each connected to a plurality of first coupling parts 1100 extending in the vertical direction.

Alternatively, unlike the drawing, a plurality of first coupling parts 1100 may be formed in the first valve body 1310, and one or more first coupling parts 1400 may be formed in the second valve body 1320.

In addition, the main body 1200 may further include a mixing chamber 1410 provided on the downstream side of the plurality of metering chambers 1210 in which the plurality of samples are mixed. The mixing chamber 1410 may have a plurality of inlets each connected to a plurality of metering chambers 1210 and an outlet connected to the first coupling part 1400.

A plurality of metering chambers 1210 may be arranged in parallel on the main body 1200 and may be arranged in parallel in one direction. For example, a plurality of metering chambers 1210 may be arranged parallel to each other on one plane.

The main body 1200 may have a first valve coupling portion formed on the upstream side of the metering chamber 1210 to which the first valve body 1310 is coupled. The first valve coupling portion extends in the direction of the plane where the metering chamber 1210 is disposed and may be formed as a groove passing through each of the plurality of metering chambers 1210. And the first valve coupling part may be provided to penetrate one side of the main body 1200.

The first valve body 1310 is inserted into the first valve coupling portion and may be provided to be movable relative to the main body 1200. Additionally, the first valve body 1310 may extend in the direction of the plane where the metering chamber 1210 is disposed and may be formed to pass through each of the plurality of metering chambers 1210 . And the first valve body 1310 may be provided to protrude past one side of the main body 1200. The first valve body 1310 protruding from one side of the main body 1200 may function as an operation unit that the user can press or pull.

The main body 1200 may have a second valve coupling portion formed on the downstream side of the metering chamber 1210 to which the second valve body 1410 is coupled. The second valve coupling portion extends in the direction of the plane where the metering chamber 1210 is disposed and may be formed as a groove passing through each of the plurality of metering chambers 1210. And the second valve coupling part may be provided to penetrate one side of the main body 1200.

The second valve body 1410 is inserted into the second valve coupling portion and may be provided to be movable relative to the main body 1200. Additionally, the second valve body 1410 may extend in the direction of the plane where the metering chamber 1210 is disposed and may be formed to pass through each of the plurality of metering chambers 1210 . And the second valve body 1410 may be provided to protrude past one side of the main body 1200. The second valve body 1410 protruding from one side of the main body 1200 may function as an operation unit that the user can press or pull.

The first valve body 1310 may include a plurality of first valve passages 1311 and a plurality of first blocking units. Additionally, the first valve passage 1311 and the first blocking portion may be arranged alternately.

The first valve passage 1311 is provided to penetrate the first valve body 1310 up and down, the upper side may be connected to the inlet passage 1120, and the lower side may be connected to the inlet of the metering chamber 1210.

And the first blocking unit may be provided to block the fluid flow between the inlet flow path 1120 and the metering chamber 1210. Additionally, the first blocking unit may include a sealing member (not shown) to prevent fluid from leaking through the gap between the main body 1200 and the first valve body 1310.

The second valve body 1320 may include a plurality of second valve passages 1321 and a plurality of second blocking units. Additionally, the second valve passage 1321 and the second blocking portion may be arranged alternately.

The second valve passage 1321 is provided to penetrate the second valve body 1320 up and down, the upper side may be connected to the outlet of the metering chamber 1210, and the lower side may be connected to the inlet of the outlet passage 1420.

And the second blocking unit may be provided to block the fluid flow between the metering chamber 1210 and the outlet flow path 1420. Additionally, the second blocking unit may include a sealing member (not shown) to prevent fluid from leaking through the gap between the main body 1200 and the second valve body 1320.

Figure 5 is a perspective view showing a sample pooling device according to a third embodiment of the present invention, and Figure 6 is an exploded perspective view of Figure 5. And Figure 7 is a cross-sectional view showing the sample moving in the sample pulling device according to the third embodiment of the present invention, Figure 7(a) shows the first and second valves in a blocked state, and Figure 7(b) shows the state in which the first and second valves are blocked. represents a state in which the first and second valves are open.

Referring to FIGS. 5 to 7, the sample pooling device 30 according to the third embodiment of the present invention includes a main body 2200 in which a plurality of metering chambers 2210 are formed, and a It may include a first valve body 2310 that is movably provided and a second valve body 2320 that is relatively movably coupled to the main body 2200.

The main body 2200 may be formed by having a plurality of metering chambers 2210 extending in the vertical direction. A plurality of metering chambers 2210 may be arranged in parallel on the main body 2200 and may be arranged in parallel in the circumferential direction. For example, the plurality of metering chambers 2210 may be arranged parallel to each other in the circumferential direction.

The first valve body 2310 is coupled to the upper part of the main body 2200, a plurality of first coupling parts 2100 are formed on the upper part, and a plurality of first coupling parts 2100 are each connected to the plurality of first coupling parts 2100. 1 valve passage 2311 may be formed. Each of the plurality of first valve passages 2311 may be connected to the metering chamber 2210.

The second valve body 2320 is coupled to the lower part of the main body 2200, one or more second coupling parts 2400 are formed at the lower part, and a plurality of second valve flow paths are connected to the second coupling parts 2400. (2321) can be formed. The plurality of second valve passages 2321 may each be connected to the metering chamber 2210.

In addition, the second valve body 2320 may further include a mixing chamber 2410 provided on the downstream side of the plurality of second valve passages 2321 and mixing a plurality of samples. The mixing chamber 2410 may include a plurality of inlets each connected to a plurality of second valve passages 2321 and an outlet connected to the second coupling portion 2400.

Alternatively, a plurality of first coupling parts 2100 may be formed on the upper part of the main body 2200, and one or more second coupling parts 2400 may be formed on the lower part of the main body 2200. In this case, the main body 2200 may further include a mixing chamber 2410 provided downstream of the plurality of metering chambers 2210 and mixing a plurality of samples. The mixing chamber 2410 may include a plurality of inlets each connected to a plurality of second valve passages 2321 and an outlet connected to the second coupling portion 2400.

The main body 2200 and the first valve body 2310 may share the same central axis 2500. And the main body 2200 and the second valve body 2320 may share the same central axis 2500. For example, the main body 2200 may be formed integrally with the central axis 2500, and the central axis 2500 may be provided to protrude upward and downward. Additionally, the first valve body 2310 may be rotatably coupled to the upper central axis 2500, and the second valve body 2320 may be rotatably coupled to the lower central axis 2500.

The main body 2200, the first valve body 2310, and the second valve body 2320 may be provided in a disk shape. For example, the main body 2200 may include a plurality of metering chambers 2210 having the same radial distance arranged at equal intervals in the circumferential direction.

The first valve body 2310 may be provided to be movable relative to the main body 2200. In addition, the first valve body 2310 may extend in the circumferential direction where the metering chamber 2210 is disposed and may be formed to pass through each of the plurality of metering chambers 2210.

Additionally, the first valve body 2310 may be provided to protrude in the radial direction beyond the main body 2200. The portion of the first valve body 2310 that protrudes outward in the radial direction of the main body 2200 may function as a control unit that the user can press or pull.

Additionally, the second valve body 2320 may be provided to be movable relative to the main body 2200. Additionally, the second valve body 2320 may extend in the circumferential direction where the metering chamber 2210 is disposed and may be formed to pass through each of the plurality of metering chambers 2210.

Additionally, the second valve body 2320 may be provided to protrude in the radial direction beyond the main body 2200. The portion of the second valve body 2320 that protrudes outward in the radial direction of the main body 2200 may function as an operation unit that the user can press or pull.

The first valve body 2310 may include a plurality of first valve passages 2311 and a plurality of first blocking units. Additionally, the first valve passage 2311 and the first blocking portion may be arranged alternately.

The first valve flow path 2311 is provided to penetrate the first valve body 2310 up and down, the upper side may be connected to the first coupling portion 2100, and the lower side may be connected to the inlet of the metering chamber 2210.

And the first blocking part may be provided to block the fluid flow between the first coupling part 2100 and the metering chamber 2210. Additionally, the first blocking unit may include a sealing member to prevent fluid from leaking through the gap between the main body 2200 and the first valve body 2310.

The second valve body 2320 may include a plurality of second valve passages 2321 and a plurality of second blocking units. Additionally, the second valve passage 2321 and the second blocking portion may be arranged alternately.

The second valve passage 2321 is provided to penetrate the second valve body 2320 up and down, the upper side may be connected to the outlet of the metering chamber 2210, and the lower side may be connected to the inlet of the outlet passage 2420.

And the second blocking unit may be provided to block the fluid flow between the metering chamber 2210 and the outlet flow path 2420. Additionally, the second blocking unit may include a sealing member to prevent fluid from leaking through the gap between the main body 2200 and the second valve body 2320.

In addition, the second valve body 2320 may further include a mixing chamber 2410 provided on the downstream side of the plurality of second valve passages 2321 and mixing a plurality of samples. The mixing chamber 2410 may include a plurality of inlets each connected to a plurality of second valve passages 2321 and an outlet connected to the second coupling portion 2400.

As the specific parts of the present invention have been described in detail above, it is clear to those skilled in the art that these specific techniques are merely preferred implementation examples and do not limit the scope of the present invention. Accordingly, the substantial scope of the present invention will be defined by the appended claims and their equivalents.

10, 20, 30: sample pooling device;
51: first storage container, 52: second storage container,
100: first coupling portion, 110: first coupling hole,
120: entrance flow path,
200: connection, 210: metering chamber,
310: first valve, 311: first bridge,
312: first blocking portion,
320: second valve, 321: second bridge,
322: second blocking unit,
400: second coupling portion, 410: mixing chamber,
420: outlet flow path, 430: second coupling hole.

Claims (31)

A plurality of first coupling parts each coupled to a plurality of first storage containers capable of accommodating samples prepared in liquid form;
One or more second coupling portions coupled to a second storage container capable of receiving a sample; and
Comprising a plurality of metering units fluidly connected to each of the first coupling units and metering a fixed amount of sample,
The first coupling portion is provided in greater numbers than the second coupling portion,
Sample pooling device. According to claim 1,
Further comprising a mixing unit whose inlet is fluidly connected to the outlet of the metering unit and whose outlet is fluidly connected to the second coupling unit,
Sample pooling device. According to claim 1,
The number of first coupling parts is provided at least three times the number of second coupling parts,
Sample pooling device. According to claim 1,
Further comprising a first valve provided upstream of the metering unit and capable of opening and closing the flow path,
Sample pooling device. According to clause 4,
It further includes a second valve provided downstream of the metering unit and capable of opening and closing the flow path,
The metering unit is a metering chamber having a fixed volume between the first valve and the second valve,
Sample pooling device. According to clause 5,
At least one of the first valve and the second valve,
Comprising a blocking unit capable of opening and closing the metering chamber and a bridge connecting each blocking unit corresponding to the plurality of metering chambers,
Sample pooling device. According to clause 6,
The plurality of blocking units connected to the bridge move together to simultaneously open and close the plurality of metering chambers.
Sample pooling device. The method according to any one of claims 1 to 7,
The plurality of metering units are arranged in parallel in a straight line or curved direction,
Sample pooling device. According to clause 6,
The blocking unit is provided to be movable in a direction that is different from the direction in which the plurality of metering chambers are arranged to open and close the metering chamber.
Sample pooling device. According to clause 6,
The blocking unit is provided to be movable in one direction in which the plurality of metering chambers are arranged to open and close the metering chamber.
Sample pooling device. According to claim 1,
Further comprising a first valve body located on the inlet side of the plurality of metering units,
The first valve body is provided with a plurality of blocking parts that respectively block the plurality of metering unit inlets and a plurality of first valve passages that communicate with the plurality of first coupling parts and the plurality of metering part inlets, respectively.
Sample pooling device. According to claim 11,
Further comprising a second valve body located on the outlet side of the plurality of metering units,
The second valve body is provided with a plurality of blocking parts that respectively block the plurality of metering unit outlets, and a plurality of second valve passages that communicate with the second coupling part and the plurality of metering unit outlets, respectively.
Sample pooling device. The method of claim 11 or 12,
The plurality of metering units are arranged in a circumferential direction,
Sample pooling device. The method of claim 11 or 12,
The plurality of blocking portions and the plurality of first valve passages or the plurality of blocking portions and the plurality of second valve passages are provided alternately in the circumferential direction,
Sample pooling device. According to claim 1,
a main body provided with the plurality of metering units arranged in a circumferential direction on one plane;
a first valve body provided to be relatively rotatable on one side of the main body; and
Comprising a second valve body rotatably provided on the other side of the main body,
Sample pooling device. According to claim 15,
At least one of the first valve body and the second valve body includes a plurality of blocking units that block passages communicating with the plurality of metering units and a plurality of valve passages connecting the passages communicating with the plurality of metering units. Equipped with,
Sample pooling device. A first coupling hole coupled to a first storage container capable of accommodating a sample prepared in liquid form;
a plurality of first flow paths each fluidly connected to the plurality of first coupling holes;
a plurality of second flow paths fluidly connecting each of the first flow paths;
a single second coupling hole fluidly connected to the plurality of second flow paths and coupled to a single second storage container capable of accommodating a sample; and
A plurality of metering chambers are provided between each of the first flow paths and each of the second flow paths and have a volume capable of accommodating a fixed amount of sample.
Sample pooling device. According to claim 17,
The plurality of metering chambers all have the same volume,
Sample pooling device. According to claim 17,
The first coupling hole is determined in the range between 3 and 5,
Sample pooling device. The method according to any one of claims 17 to 19,
Further comprising a mixing chamber fluidly connecting the plurality of second flow paths and the single second coupling hole and mixing the plurality of samples contained in the plurality of first storage containers,
Sample pooling device. According to claim 20,
Further comprising a flow meter provided behind the outlet of the mixing chamber,
Sample pooling device. The method according to any one of claims 17 to 19,
a main body including the plurality of metering chambers;
A plurality of blocking units movably coupled to one side of the main body and capable of opening and closing the entrances of the plurality of metering chambers, respectively, connect the entrances of the plurality of metering chambers and the plurality of first flow paths, respectively. A first valve body having one valve passage; and
Further comprising a second valve body movably coupled to the other side of the main body and having a plurality of blocking units capable of opening and closing outlets of the plurality of metering chambers, respectively,
Sample pooling device. According to clause 22,
The plurality of metering chambers are arranged in parallel in a straight line or curved direction,
At least one of the first valve body and the second valve body is provided to be able to slide relative to the main body,
Sample pooling device. According to clause 22,
The plurality of metering units are arranged in a circumferential direction,
At least one of the first valve body and the second valve body is provided to be rotatably movable relative to the main body,
Sample pooling device. According to clause 22,
In the first valve body, the plurality of blocking portions and the plurality of first valve flow paths are provided alternately,
Sample pooling device. According to clause 22,
The blocking portion includes a sealing member,
Sample pooling device. In the method of pooling samples using the sample pooling device according to claim 4,
(a) coupling the first storage container to two or more of the plurality of first coupling parts;
(b) opening the first valve while the second valve is closed;
(c) closing the first valve when a fixed amount of sample is received in the metering chamber; and
(d) opening the second valve,
Pooling test method. According to clause 27,
The volume of the sample contained in the first storage container is provided to be larger than the volume of the metering chamber,
Pooling test method. According to clause 27,
In step (c), closing the first valve after the metering chamber is full,
Pooling test method. According to clause 27,
The sample pulling device further includes a flow sensor provided in the first flow path,
In step (c), closing the first valve when it is determined that a predetermined volume is accommodated in the metering chamber through flow rate information obtained from the flow sensor,
Pooling test method. According to clause 27,
After the second valve opening step, further comprising providing negative pressure to the second coupling hole,
Pooling test method.

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