JP3198828U - Microplate - Google Patents

Abstract

An object of the present invention is to provide a microplate in which an organic solvent does not volatilize during measurement, the amount of a measurement solution does not change, and there is no problem such as dropping of a lid in a microplate reader cabinet. A microplate comprising a horizontally long flat plate-like microplate body portion 1 having a plurality of wells 12 formed in a cylindrical shape by a partition wall 11 and a lid portion 2 placed on the microplate body portion 1. . The microplate body 1 is made of a material that is resistant to organic solvents and is not colorless and transparent, and has a partition wall 11 and a well 12, and a peripheral portion of the microplate member 1 </ b> A formed higher than the partition wall 11. Further, the bottom plate 1B made of a colorless and transparent material having organic solvent resistance is screwed. The lid 2 is made of a quartz glass plate, and when covered with the microplate main body 1, the microplate main body 1 covers the partition wall 11, the well 12, and the peripheral edge of the microplate main body 1 without any gaps. A fringe is formed at a position corresponding to the peripheral edge of the portion 1. [Selection] Figure 1

Description

The present invention relates to a microplate used for various experiments and inspections, and more particularly to a microplate suitable for measuring singlet oxygen scavenging ability, which is a kind of antioxidant ability of foods and the like.

In recent years, it has become clear that oxidative stress in the body is related to various diseases such as lifestyle-related diseases, and in addition to the antioxidant mechanism provided in the body, it is healthy to incorporate antioxidant components into the body from the outside through meals, etc. It is becoming important to maintain
Against this background, expectations are increasing for the display of measured antioxidant capacity as a measure of the intake of antioxidant ingredients, but little is known about how much antioxidants should be consumed. .
Since there are many types of antioxidants and it is impossible to measure them individually and display the total sum, including the verification that antioxidants taken from outside the body really help reduce disease risk, In order to clarify the effects of antioxidant components on health, it is necessary to establish an antioxidant capacity measurement method to measure the antioxidant capacity (total amount of antioxidants) of agricultural products, etc., which is the basic technology. .

In particular, carotenoids contained in agricultural products have an antioxidant ability called singlet oxygen scavenging ability, and the SOAC method has been developed by Mukai et al. (J. Agric. Food Chem. 58 (18 ): 9967-78).
Since this SOAC method uses a 6-cell spectrophotometer, only one type of sample can be measured at a time. For this reason, the SOAC method (microplate method), which measures singlet oxygen scavenging ability using a 24-well microplate based on the principle of this method, has been developed. Microplates are required.

Conventionally used 24-well glass microplates with organic solvent resistance are completely transparent made of borosilicate glass or black glass made by Nippon Sheet Glass Co., Ltd. (FU-24: currently discontinued) (Soda lime) is used and the light of the adjacent well is difficult to enter (for example, see Patent Document 1).

However, although the former has a lid, it is simply a cover-type lid, and the degree of sealing is low and loose, so the organic solvent put into the well as a sample volatilizes during measurement, and the amount of the measurement solution changes. The problem that it ends up occurs.

Moreover, since the latter does not have a dedicated lid, if a quartz glass plate is used as the lid, the lid is easily removed, and volatilization of the organic solvent put into the well as a sample or vibration of the microplate reader There are problems such as dropping the lid inside the microplate reader cabinet, which hinders measurement.
Further, in this microplate, the wall surface of the well has an angle and is not a right angle. Therefore, depending on the type of microplate reader, the measurement solution in the well may be scattered outside the well due to vibration during measurement.

JP 2007-292556 A

The present invention eliminates the above-mentioned conventional problems, and the organic solvent put into the well as a sample volatilizes during the measurement, and the amount of the measurement solution changes, and the inside of the microplate reader chamber is caused by the vibration of the microplate reader. An object of the present invention is to provide a microplate that does not have a problem such as dropping the lid.
Furthermore, an object of the present invention is to provide a microplate suitable for measurement of singlet oxygen scavenging ability, which is a kind of antioxidant ability particularly for foods.

That is, the present invention provides the following (1) to (3).
(1): A microplate comprising: a microplate body having a plurality of wells formed in a cylindrical shape by a partition; and a lid placed on the microplate body,
The microplate body is
A microplate member having an organic solvent resistance that is not colorless and transparent, having the partition and the well, and having a peripheral edge formed higher than the partition has an organic solvent resistance. Screw the bottom plate made of colorless and transparent material;
The lid portion is made of a quartz glass plate, and the microplate so as to cover the partition wall, the well, and the peripheral edge portion of the microplate body portion without any gap when the lid portion is covered with the microplate body portion. A fringe is formed at a position corresponding to the peripheral edge of the main body;
The present invention relates to a microplate.

(2): The microplate according to (1), wherein the bottom plate is made of float plate glass or quartz glass.

(3): The microplate member according to (1) or (2), wherein the microplate member is made of polytetrafluoroethylene resin.

According to the present invention, there is no problem that the organic solvent put into the well as a sample is volatilized during the measurement and the amount of the measurement solution is changed, and there is no problem such as dropping of the lid in the microplate reader chamber. A plate is provided.
That is, when the lid is placed on the microplate main body of the microplate, the microplate main body and the lid are in close contact with each other, so that the organic solvent introduced into the well as a sample is volatilized during the measurement. The problem that the amount of the measurement solution is changed and the problem that the lid is dropped in the microplate reader chamber due to the vibration of the microplate reader are solved.
Moreover, since the bottom plate is formed of a colorless and transparent material having organic solvent resistance, the microplate of the present invention can measure visible light not only from the top surface but also from the bottom surface.
Furthermore, since the microplate of the present invention is made of a material having organic solvent resistance in the microplate main body and the lid, according to the present invention, it is a kind of antioxidant ability especially for foods. A microplate suitable for a singlet oxygen scavenging ability measurement is provided.

It is a perspective view which shows 1st Embodiment of the microplate of this invention. It is sectional drawing which looked at 1st Embodiment of the microplate of this invention from the front side. It is explanatory drawing which looked at 1st Embodiment of the microplate of this invention from the plane side. It is explanatory drawing which looked at 1st Embodiment of the microplate of this invention from the bottom face side. It is explanatory drawing which looked at 1st Embodiment of the microplate of this invention from the side surface side.

Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing a first embodiment of a microplate of the present invention, FIG. 2 is an explanatory view of the first embodiment viewed from the front side, and FIG. 3 is an explanatory view of the first embodiment viewed from the plane side. 4 is an explanatory view of the first embodiment as viewed from the bottom surface side, and FIG. 5 is an explanatory view of the first embodiment as viewed from the side surface side.

As shown in FIGS. 1 to 5, the microplate of the present embodiment includes a microplate body 1 and a lid 2.

The microplate main body 1 has a horizontally long flat plate shape as a whole, and generally has a vertical / horizontal ratio of about 2 to 3 for horizontal. In the figure, those having a width of 128 mm and a length of 85 mm are shown.
The microplate main body 1 has a plurality of wells (recesses / holes into which a sample is placed) 12 formed in a cylindrical shape by partition walls 11. In the figure, 24 wells having 24 wells 12 (vertical 4 rows, horizontal 6 rows) are shown, but for example, 12 wells, 48 wells, 96 wells, 384 wells, etc. may be used. .
The well 12 is formed in a cylindrical shape by the partition wall 11, and an organic solvent is put therein as a sample.
Here, as shown in the figure, the wall surface 121 of the well 12 is formed at a right angle to the partition wall 11 and the bottom plate 1B described later, so that the measurement solution in the well 12 can be vibrated even when measuring with a microplate reader. Is difficult to scatter.

The microplate body 1 basically includes a microplate member 1A and a bottom plate 1B, and is formed by screwing the bottom plate 1B to the microplate member 1A. Since the bottom plate 1B is fixed by screwing, the bottom plate 1B can be appropriately replaced. If there is no need to replace the bottom plate 1B, it may be integrated by fixing it with an adhesive or by heat sealing.

Also, as shown in the figure, usually, an O-ring 14 is sandwiched between the microplate member 1A and the bottom plate 1B to prevent the sample in the well 12 from leaking between the microplate member 1A and the bottom plate 1B. However, since the bottom plate 1B is screwed, the O-ring 14 can be replaced as appropriate in consideration of the application and the like.

As a material for the O-ring 14, a material excellent in organic solvent resistance, for example, various fluoro rubbers may be used. Specific examples of the various fluororubbers include fluororubbers such as boronidene fluoride (FKM), tetrafluoroethylene-propylene (FEPM), and tetrafluoroethylene-perfluorovinylether (FFKM).

The microplate member 1A is made of a material that is resistant to organic solvents and is not colorless and transparent, specifically, for example, white polytetrafluoroethylene (PTFE) resin, black glass (soda lime), or the like. In particular, those made of PTFE resin are most preferred because they have chloroform resistance and are excellent in processability and moldability.
Since the microplate member 1A is made of a material that is not colorless and transparent while having resistance to organic solvents as described above, it is difficult for light in adjacent wells to enter while having resistance to organic solvents, and antioxidants such as foods. It is a microplate suitable for measuring singlet oxygen scavenging ability, which is a kind of ability.

1 A of microplate members are formed higher than the partition 11 so that the peripheral part 13 can prevent the outflow of the organic solvent thrown into the well 12 as a sample.

The bottom plate 1B is made of a colorless and transparent material having organic solvent resistance, specifically, for example, float plate glass or quartz glass. In particular, those made of float glass are preferable because of excellent smoothness and transparency.
In the microplate of this embodiment, since the bottom plate 1B is formed of a colorless and transparent material having organic solvent resistance, visible light can be measured not only from the top surface but also from the bottom surface.

The microplate of this embodiment includes the microplate main body 1 and the lid 2 as described above.

The lid 2 is plate-shaped (plate-shaped) made of a quartz glass plate. Since it is made of quartz glass, it has resistance to organic solvents, is colorless and transparent, and has excellent workability and moldability.
The lid portion 2 corresponds to the peripheral portion 13 in the microplate main body portion 1 so as to cover the partition wall 11 and the peripheral edge portion 13 in the microplate main body portion 1 without any gap when covered with the microplate main body portion 1. A fringe (edge) 21 is formed at the position to be. For this reason, the gap between the lid 2 and the microplate body 1 is substantially eliminated.
As shown in the figure, the fringe 21 is formed over the peripheral edge of the lid portion 2 so as to form a horizontally long convex shape when the lid portion 2 is viewed from the side.
Since the fringe 21 is formed on the lid portion 2, when the lid portion 2 is placed on the microplate body portion 1, the microplate body portion 1 and the lid portion 2 are in close contact with each other. The problem is that the organic solvent introduced as a sample in the well 12 during measurement is volatilized and the amount of the measurement solution changes, and the lid is dropped in the microplate reader chamber due to vibration of the microplate reader. It will be resolved.
According to the microplate of the present embodiment, measurement can be performed without dropping the lid even in the case of the microplate reader model in which the lid has been dropped.

As shown in FIG. 1, a pressing plate 1 </ b> C made of aluminum or the like may be present below the bottom plate 1 </ b> B in the microplate main body 1, or may not be so.
The presser plate 1 </ b> C is provided with a cavity having a size (diameter) comparable to that of the well 12 at a position corresponding to the position of the well 12.
The presence of the presser plate 1C prevents the bottom plate 1B from coming into contact with the installation surface and being damaged, and prevents the screwed head from being damaged.

As mentioned above, although embodiment of this invention was described with reference to drawings, a specific structure is not restricted to this embodiment unless it deviates from the summary of this invention.

Since the microplate of the present invention is resistant to organic solvents, and can measure visible light from the top and bottom surfaces, the lid does not fall even when subjected to vibration of the microplate reader. In particular, it is effectively used for the evaluation of antioxidant capacity of agricultural products and foods containing carotenoid antioxidants.

1: Microplate body 1A: Microplate member 1B: Bottom plate 1C: Presser plate 11: Partition 12: Well 121: Wall surface of well 13: Peripheral portion 14: O-ring 2: Lid portion 21: Fringe

Claims (3)

A microplate body having a horizontally long flat plate shape having a plurality of wells formed in a cylindrical shape by a partition; and a lid portion placed on the microplate body,
The microplate body is
A microplate member having an organic solvent resistance that is not colorless and transparent, having the partition and the well, and having a peripheral edge formed higher than the partition has an organic solvent resistance. Screw the bottom plate made of colorless and transparent material;
The lid portion is made of a quartz glass plate, and when the microplate body portion is covered, the microplate so as to cover the partition wall, the well, and the peripheral edge portion of the microplate body portion without any gap. A fringe is formed at a position corresponding to the peripheral edge of the main body;
A microplate characterized by that.
The microplate according to claim 1, wherein the bottom plate is made of float plate glass or quartz glass.
  The microplate according to claim 1 or 2, wherein the microplate member is made of polytetrafluoroethylene resin.

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