JPWO2005121745A1 - Biochemistry container - Google Patents

Abstract

A biochemical container having a large number of wells is formed of light-transmissive glass, and even if the biochemical container is extremely thin, the desired shape can be maintained, and Providing biochemical containers that are less likely to be easily damaged by a small external force.
1. A biochemical container, which is rectangular in a plan view and has a large number of wells 3 and which is made of a light-transmissive material, wherein the biochemical container is rectangular in a plan view and has a large number of wells 3. The glass plate 1 formed by 1. and the shape-retaining frame 2 that holds the shape of the glass plate 1, and the shape-retaining frame 2 is connected and arranged along at least two opposite sides of the glass plate 1. There is.

Description

The present invention relates to a biochemical container that is rectangular in a plan view and that is provided with a large number of wells and is made of a light transmissive material.

  As such a biochemical container, for example, there is a microplate, and conventionally, a container integrally formed of a synthetic resin such as polystyrene (for example, see Patent Document 1) is known. Further, the microplate is divided into a main body and a bottom plate, the main body is made of polystyrene, the bottom plate is made of synthetic quartz plate (quartz glass), and the polystyrene main body and the bottom plate made of synthetic quartz plate are bonded by an adhesive. There are known ones formed by adhering with each other (for example, see Patent Document 2).

By the way, recently, a gene analysis method for observing the hybridization behavior of DNA by ultraviolet spectroscopy in a specific environment of reverse micelles has been proposed and attracted attention. In the gene analysis method, an organic solvent such as isooctane is used as a sample.
However, when a synthetic resin such as polystyrene is integrally formed, or when a biochemical container having a polystyrene main body is used, the main body, adhesive, etc. may be dissolved by an organic solvent. .. Therefore, there has been an increasing need for a biochemical container having excellent organic solvent resistance.

Therefore, the applicant of the present invention heats a light-transmissive glass material to a softening point or higher, molds the light-transmissive glass material in a molten state or a softened state into a mold, and then performs spectroscopic measurement. As described above, a biochemical container made of light-transmissive glass manufactured by polishing the bottom surface of each well has been proposed (see, for example, Patent Document 3).
JP, 10-78388, A JP, 2002-125656, A JP 2004-109107 A

However, in the biochemical container described in Patent Document 3, since the entire container is formed of only one piece of glass, it is virtually impossible to make the container extremely thin.
That is, as the thickness of the container is reduced, the light transmittance is improved, and the influence of disturbance due to the emission of fluorescence is reduced, so that more strict measurement can be performed. However, for example, if the thickness of the container is set to the level of a conventional preparation, specifically, 1 mm or less, the shape retention of the biochemical container becomes a serious problem in actual handling. In addition, there is a problem that it is easily damaged by an extremely small external force.

The present invention focuses on such conventional problems.
The purpose is to form a biochemical container with a large number of wells from a light-transmissive glass, and to keep the desired shape even if the thickness of the biochemical container is extremely thin. In addition, it is to provide a biochemical container that is unlikely to be easily damaged by an extremely small external force.

  A first characteristic configuration of the present invention is a biochemical container that is rectangular in a plan view and is formed of a light transmissive material with a large number of wells, wherein the biochemical container is a rectangle in a plan view. A glass plate formed of glass with a large number of wells, and a shape retention frame for retaining the shape of the glass plate, the shape retention frame being provided along at least two opposite sides of the glass plate. It is in the place where it is connected and arranged.

According to the first characteristic configuration of the present invention, since the shape retention frames are connected and arranged along at least two opposite sides of the glass plate, the thickness of the glass plate is extremely thin, for example, 1.0 mm. Even in the following, the shape retaining frame holds the shape of the glass plate as desired.
In addition to that, the shape-retaining frame along the two sides of the glass plate also functions to protect the glass plate from external force, so that there is little risk of being easily broken by extremely small external force, and substantially one piece of light-transmissive glass. It is possible to provide a thin biochemical container consisting of the above in a state that can withstand actual use. Therefore, it is possible to perform more strict measurement by improving the light transmittance and suppressing the disturbance due to fluorescence or the like.

  A second characteristic configuration of the present invention is that the shape retention frames are connected and arranged along the four sides of the glass plate.

  According to the second characteristic configuration of the present invention, since the shape retention frame is connected and arranged along the four sides of the glass plate, the shape retention frame is connected by the shape retention frame as compared with the case where the shape retention frames are connected and arranged along the two sides. The shape retention function of the glass plate and the protection function from external force are further improved, and it becomes possible to provide a more practical biochemical container.

  According to a third characteristic configuration of the present invention, the shape retention frame includes an upper shape retention frame that contacts the upper surface of the glass plate and a lower shape retention frame that contacts the lower surface thereof. The shape-retaining frame is arranged so as to be connected to the glass plate while sandwiching the edge portion of the glass plate from above and below.

  According to the third characteristic configuration of the present invention, the shape retention frame includes an upper shape retention frame that abuts on the upper surface of the glass plate and a lower side shape retention frame that abuts on the lower surface of the glass plate. Since the shape frame is connected to the glass plate while sandwiching the edge of the glass plate from above and below, the shape retention frame is reliably connected to the glass plate. Moreover, even if the biochemical container is placed on a flat mounting surface, the lower surface of the glass plate can be prevented from directly contacting the mounting surface. Therefore, the biochemical container can be easily handled, and the biochemical containers can be stacked one above the other as they are.

  According to a fourth characteristic configuration of the present invention, one of the upper shape retaining frame and the lower shape retaining frame includes an engaging portion and the other includes an engaged portion, and the engaging portion and the engaged portion. The upper shape-retaining frame and the lower shape-retaining frame are connected to each other by sandwiching the glass plate by the engagement.

  According to the fourth characteristic configuration of the present invention, one of the upper shape retaining frame and the lower shape retaining frame has an engaging portion and the other has an engaged portion, and the engaging portion and the engaged portion are engaged with each other. Since the upper shape retaining frame and the lower shape retaining frame are connected to each other by sandwiching the glass plate by the engagement of the parts, the upper shape retaining frame and the lower shape retaining frame are provided at the time of manufacturing the biochemical container. By using the engaging portion and the engaged portion, both holding frames can be easily connected to the glass plate. Further, when the biochemical container is used, the holding frame can be removed as necessary, and the glass plate can be used alone.

An embodiment of a biochemical container according to the present invention will be described with reference to the drawings.
As shown in FIGS. 1 to 3, the biochemical container of the present invention includes a glass plate 1 formed of light-transmissive glass, and a shape-retaining frame made of a synthetic resin that holds the shape of the glass plate 1. 2 and.
The glass plate 1 is formed of, for example, a very thin quartz glass plate having a thickness t of about 1 mm to 0.3 mm, and has a large number of wells 3 formed by etching, for example, on its upper surface side. The glass plate 1 is formed in a rectangular shape in plan view, specifically, in a rectangular shape having a long side of about 128 mm and a short side of about 86 mm, for example, so that an existing microplate reader can be used. Has been done.
However, the dimensions of the glass plate 1 can be freely set according to the purpose of use. For example, a rectangle having a long side of 3 inches (about 76.2 mm) and a short side of 1 inch (about 25.4 mm) can be formed so as to correspond to a slide.

As shown in detail in FIG. 3, the shape-retaining frame 2 includes a frame-shaped upper shape-retaining frame 2 a that abuts the upper surface of the glass plate 1 along the four sides of the glass plate 1, and also along the four sides of the glass plate 1. The lower shape-maintaining frame 2b is in the form of a frame and contacts the lower surface of the glass plate 1.
The lower shape retention frame 2b includes a plurality of engagement protrusions 4 that function as an engagement portion, and the engagement protrusions 4 are integrally formed with the lower shape retention frame 2b and protrude toward the side. It is set up.
On the other hand, the upper shape-retaining frame 2a has an L-shaped end portion, and functions as an engaged portion in a state corresponding to the engaging protrusion 4 of the lower shape-retaining frame 2b inside the L-shape. A plurality of engaging holes 5 are provided.

In the glass plate 1 and the shape-retaining frame 2 having such a configuration, as shown in FIG. 3A, the glass plate 1 is placed on the upper surface of the lower shape-retaining frame 2b, and the upper side of the upper surface of the glass plate 1 is placed. The shape retention frame 2a is arranged. Then, as shown in FIG. 3B, the engaging protrusions 4 projecting from the lower shape retaining frame 2b are engaged with the engaging holes 5 of the upper shape retaining frame 2a, whereby the upper shape retaining frame 2a. And the lower shape retention frame 2b are connected to each other.
By the above connection, the shape-retaining frame 2 composed of both the shape-retaining frames 2a and 2b is connected and arranged along the four sides of the glass plate 1 with the edges thereof sandwiched from above and below. Therefore, even if the thickness t of the glass plate 1 is very thin such as about 1 mm to 0.3 mm, the deformation and cracking of the glass plate 1 are suppressed. Further, the glass plates 1 can be stacked vertically as they are, which facilitates handling.

[Another embodiment]
(1) In addition to the above-described embodiment, a biochemical container can be configured by a plurality of glass plates 1 and a pair of shape retention frames 2.
That is, as shown in FIG. 4, for example, three glass plates 1 are placed in parallel on the upper surface of the lower shape retaining frame 2b, and the upper shape retaining frame 2a disposed on the upper surface of the glass plates 1 It is also possible to sandwich the three glass plates 1 together to form a biochemical container.
Further, as shown in FIG. 5, only one of the above-mentioned three glass plates 1 is placed on the upper surface of the lower shape retaining frame 2b, and is sandwiched by the upper shape retaining frame 2a to hold the biochemical container. Can also be configured. In this case, the shape-retaining frames 2 are connected and arranged along the two opposite sides of the glass plate 1.

(2) In the above embodiment, an example in which the glass plate 1 is made of quartz glass is shown, but other than quartz glass, for example, it is made of various glasses such as soda lime glass, alkali-free glass, and borosilicate glass. It is possible.
The well 3 formed on the upper surface of the glass plate 1 is not limited to the etching shown in the above embodiment, but may be formed by laser processing or press processing, for example. Further, the shape-retaining frame 2 is not limited to the synthetic resin described in the above embodiment, but may be formed of metal, wood, glass, or the like.

    INDUSTRIAL APPLICABILITY The present invention can be used as a biochemical container in the field of biochemistry. In particular, it can be used as a biochemical container used in the field of ultraviolet spectroscopy in the presence of an organic solvent, such as a gene analysis method of observing the hybridization behavior of DNA by ultraviolet spectroscopy in a specific environment of reverse micelles.

Exploded perspective view of biochemistry container Biochemical container perspective view Sectional view of essential parts of biochemistry container An exploded perspective view of a biochemical container according to another embodiment. A perspective view of a biochemical container according to another embodiment

Explanation of symbols

1 Glass Plate 2 Shape-Retaining Frame 2a Upper Shape-Retaining Frame 2b Lower Shape-Retaining Frame 3 Well 4 Engagement Part 5 Engaged Part

Claims (5)

A container for biochemistry, which is rectangular in a plan view and is formed of a light-transmitting material with a large number of wells,
The biochemical container is rectangular in a plan view, and is composed of a glass plate formed of glass with a large number of wells, and a shape-retaining frame that holds the shape of the glass plate, and the shape-retaining frame is A container for biochemistry, which is connected and arranged along at least two opposite sides of a glass plate.   The biochemical container according to claim 1, wherein the shape retention frames are connected and arranged along four sides of the glass plate.   The shape-retaining frame comprises an upper shape-retaining frame that abuts the upper surface of the glass plate and a lower shape-retaining frame that abuts the lower surface, and the upper shape-retaining frame and the lower shape-retaining frame are of the glass plate. The biochemical container according to claim 1, wherein the biochemical container is arranged so as to be connected to the glass plate while sandwiching the edge portion from above and below.   The shape-retaining frame includes an upper shape-retaining frame that contacts the upper surface of the glass plate and a lower shape-retaining frame that contacts the lower surface, and the upper shape-retaining frame and the lower shape-retaining frame are the glass plate. The biochemical container according to claim 2, wherein the biochemical container is arranged so as to be connected to the glass plate while sandwiching the edge portion from above and below.   One of the upper shape retaining frame and the lower shape retaining frame includes an engaging portion, and the other includes an engaged portion, and the upper portion is formed by engaging the engaging portion and the engaged portion. The biochemical container according to claim 3 or 4, wherein the shape-retaining frame and the lower shape-retaining frame are connected to each other with the glass plate interposed therebetween.

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