KR20060089668A - Apparatus for processing biological sample - Google Patents

Abstract

The present invention relates to an apparatus for treating biological samples used for washing, separating and purifying biochemical molecules such as DNA, RNA and proteins. The apparatus comprises at least one liquid semipermeable membrane column, at least one column connection vacuum and a vacuum manifold, both loosely fitted to each other. An airtight material, such as an airtight plastic band, is positioned where the liquid semipermeable membrane column, column connection vacuum and vacuum manifold engage each other, such that when the atmospheric pressure in the liquid semipermeable membrane column is greater than the atmospheric pressure in the vacuum manifold, The device is maintained to form an airtight condition. If the liquid sample is placed inside the liquid semipermeable membrane column, atmospheric pressure can push the liquid out of the column through the liquid semipermeable membrane. Therefore, the apparatus can be assembled and disassembled more easily and conveniently than the conventional apparatus.

Biological sample, liquid semipermeable membrane column, vacuum manifold, air tightness, atmospheric pressure

Description

[0001] APPARATUS FOR PROCESSING BIOLOGICAL SAMPLE [0002]

1 is a perspective view of a conventional apparatus for treating biological samples;

Figure 2 is a perspective view of a conventional liquid semipermeable membrane column used in connection with column connection vacuuming in accordance with the present invention;

3 is a perspective view of an apparatus for treating a biological sample according to the present invention.

Fig. 4 is a sectional view of Fig. 3; Fig.

5 is a perspective view of an alternate embodiment of the device according to the invention;

Fig. 6 is a sectional view of Fig. 5; Fig.

7 is a perspective view of another alternative embodiment of the device according to the invention;

8 is a cross-sectional view of Fig.

Figure 9 is a perspective view of another alternate embodiment of the device according to the present invention;

10 is a sectional view of Fig.

The present invention relates to an apparatus for treating a biological sample, and in particular to an apparatus used for washing, separating and purifying biochemical molecules such as DNA, RNA and proteins.

In biological laboratories, liquid semi-permeable membrane columns, generally cylindrical, are commonly used to wash, separate and purify biochemical molecules such as DNA, RNA and proteins. One or more specific purpose liquid semi-permeable membranes are disposed at the bottom of the column and a liquid is poured into the column. A suitable force is then applied to the liquid in the column to pass the liquid through the liquid semi-permeable membranes through the column.

Generally, the applied force is centrifugal force or atmospheric pressure. When the centrifugal force is applied through the liquid semipermeable membrane column, the column is usually placed in a liquid collecting tube and then put into a centrifuge and rotated at high speed to produce high centrifugal force, Permeable membranes and recovered in the liquid recovery tube. However, it is the high frequency that the operator repeats this process several times during the continuous washing of the liquid semipermeable membrane column. When atmospheric pressure is applied, several liquid semi-permeable membrane columns are inserted into the vacuum manifold. Applying positive or negative atmospheric pressure, liquid is passed through the liquid semipermeable membranes from the column and is recovered to the vacuum manifold. The process by atmospheric pressure is much more convenient to perform a plurality of samples or continuous operations.

(See Fig. 1) of the liquid semi-permeable membrane column and has a geometric design consisting of three parts, an upper neck part 311, an intermediate tubular part 312 and a lower inclined part 313. The diameter of the upper neck portion 311 is greater than the diameter of the intermediate tubular portion 312. Some columns include leads 314. The intermediate tubular portion 312 is filled with a liquid sample and the bottom portion of the interior includes one or more specific purpose liquid semipermeable membranes (not shown in the figure). Some of them have the design of the lower sloping portion 313, but some of them do not.

1, the conventional coupling of the liquid semipermeable membrane column 31 and the vacuum manifold 32 is of an airtight insertion type, that is, a lower inclined portion (not shown) of the liquid semipermeable membrane column 31 313 are inserted into the hole 34 of the vacuum manifold 32 either directly or through an insertable vacuum that is connected to the column 33. The insertable vacuum portion connected to the column 33 is designed so that when the hole 34 of the vacuum manifold 32 makes contact with other samples and some liquid semipermeable membrane column 31 to cause cross contamination of other samples Is used to avoid direct insertion of the liquid semi-permeable membrane column 31 into the hole 34 of the vacuum manifold 32. The insertable vacuum portion connected to the column 33 can be of the disposable type or can simply be cleaned for repeated use. Using the insertable vacuum that is connected to the column 33, the lower sloping portion 313 of the liquid semipermeable membrane column 31 is inserted into the insertable vacuum that is connected to the column 33. This ensemble is then inserted into the hole 34 of the vacuum manifold 32 and in turn forms the following structure: liquid semipermeable membrane column 31 - insertable vacuum chamber (not shown) connected to the column 33 33) - Vacuum manifold (32). Many applications utilize an insertable vacuum 33 connected to column 33 and are used in experiments that require no cross-contamination of the sample, particularly using purified nucleic acids for PCR reactions. Therefore, it is very important that this coupling should be airtightly secured without any gas leakage. Often, the operator must hold the insertable vacuum 33 connected to the liquid semi-permeable membrane column 31 and column 33 by hand to ensure tight coupling. Similarly, the operator may experience the discomfort of the finger due to such manipulation. On the other hand, coupling too tightly is sometimes difficult to unbond, and multiple bonds can sometimes make the operation difficult, making it inconvenient to use a liquid semipermeable membrane column for multiple samples.

For the reasons stated above, the applicant can use the device in a fast and comfortable manner, while providing a device comprising a vacuum manifold and a vacuum connected to a loosely coupled liquid semi-permeable membrane column, for treating the biological sample have.

It is an object of the present invention to provide an apparatus for treating a biological sample that is easier and more convenient to assemble and disassemble.

The apparatus comprises at least one liquid semipermeable membrane column, at least one column connection vacuum and a vacuum manifold, both loosely fitted to each other. An airtight material, such as an airtight plastic band, is positioned where the liquid semipermeable membrane column, column connection vacuum and vacuum manifold engage each other, such that when the atmospheric pressure in the liquid semipermeable membrane column is greater than the atmospheric pressure in the vacuum manifold, The device is maintained to form an airtight condition. If the liquid sample is placed inside the liquid semipermeable membrane column, atmospheric pressure can push the liquid out of the column through the liquid semipermeable membrane.

The liquid semipermeable membrane column includes an inner portion and an upper portion and a bottom portion. The inner portion together with the at least one liquid semipermeable membrane placed on the bottom forms a first receiving space. The upper portion defines a first aperture and has a first projection extending outwardly from the upper portion. The bottom portion forms a first through hole.

The column-connected vacuum portion includes an inner portion and an upper portion and a bottom portion. The inner portion forms a second receiving space. The upper portion defines a second aperture and has a second projection extending outwardly from the upper portion. And the bottom portion forms a second through hole. The vacuum manifold includes a base defining a receiving space and a lid having at least one slot extending downwardly to receive at least one column connection vacuum. The slot defines a third through-hole communicating with the receiving space of the base.

The liquid semipermeable membrane column is loosely received in the second receiving space of the column connecting vacuum, so that the first projection of the liquid semipermeable membrane column is adjacent to the second projection of the column connecting vacuum. Air-tight elastic bands, such as air-tight plastic bands, are located around the periphery of the second projection. Since the column connecting vacuum portion is loosely received in the slot, the second projection is adjacent to the upper surface of the lid about the edge of the slot, and the first, second and third through holes communicate with each other, The airtight condition occurs between the first protrusion of the liquid semipermeable membrane column and the second protrusion of the column connection vacuum and between the second protrusion of the column connection vacuum and the edge of the slot when the atmospheric pressure in the vacuum manifold is greater than the atmospheric pressure in the slot of the vacuum manifold. Lt; RTI ID = 0.0 > lid. ≪ / RTI >

According to another embodiment of the present invention, since the airtight element is sandwiched between the bottom portion of the column connecting vacuum and the bottom of the slot, the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is atmospheric pressure within the slot of the vacuum manifold The airtight condition is formed and maintained between the first projection of the liquid semipermeable membrane column and the second projection of the column connection vacuum and between the bottom of the column connection vacuum and the bottom of the slot. In addition, the liquid semipermeable membrane column can also be directly bonded to the vacuum manifold and the air tight element can be placed around the periphery of the first projection or sandwiched between the bottom of the liquid semipermeable membrane column and the bottom of the slot The same confidential effect can be obtained.

Other objects, advantages and novel features of the present invention will become more apparent from the following detailed description of preferred embodiments of the invention with reference to the accompanying drawings.

 Figure 2 is a perspective view of a conventional liquid semipermeable membrane column used in connection with column connection vacuuming in accordance with the present invention. Typically, the liquid semi-permeable membrane column 11 is tubular in shape and includes an inner portion, an upper portion and a bottom portion. The inner portion forms a first receiving space (111) and at least one liquid semi-permeable membrane (112) placed on the bottom of the first receiving space (111). The upper portion forms a first hole (not shown) and has a first projection 113 extending outward from the upper portion, and the bottom portion forms a first through hole 114.

Generally, the column connection vacuum 12 can be made of any suitable material in a tubular shape. The column connection vacuum 12 includes an inner portion and an upper portion and a bottom portion. The inner portion forms the second accommodation space 121. The upper portion forms a second hole (not shown) and has a second projection 122 extending outward from the upper portion, and the bottom portion forms a second through hole 123. Permeable membrane column 11 is larger than the inner diameter of the intermediate tubular portion of the liquid semipermeable membrane column 11 but smaller than the inner diameter of the first projecting portion 113 of the liquid semipermeable membrane column 11, Permeable membrane column 11 is loosely received in the second receiving space 121 of the column connecting vacuum 12 through the second hole and the first projection 113 of the liquid semipermeable membrane column 11 is loosely received in the column connecting vacuum 12 The second protruding portion 122 of the second protruding portion 122 is adjacent to the second protruding portion 122 of the second protruding portion. Further, air-tightness elements, suitably air-tight elastic bands, can be placed around the circumference of the second projection 122 of the column connecting vacuum 12, so that the first projection 113 and the second projection 122 ). ≪ / RTI >

Referring to Figures 3 and 4, there is shown a perspective view and a cross-sectional view of an apparatus for treating a biological sample according to the present invention. The apparatus 10 comprises at least one liquid semi-permeable membrane column 11, at least one column connecting vacuum 12 and a vacuum manifold 14. The vacuum manifold 14 includes a lead 141 and a base 142. The base 142 forms a receiving space 145 (not shown). The lead 141 has at least one slot 143 extending downwardly to receive the upper surface and at least one column connection vacuum 12. The slot 143 has a bottom forming a third through-hole 144, the third through-hole in turn communicating with the receiving space 145 of the base 142.

Since the diameter of the slot 143 is somewhat larger than the diameter of the intermediate tubular portion of the column connection vacuum 12 but smaller than the diameter of the second projection of the column connection vacuum 12, Permeable membrane column 11 may be loosely received within the slot 143 when received in the column connection vacuum 12. The second projection 122 is then adjacent to the upper surface of the lead 141 around the edge of the slot 143 and the first, second and third through holes 114, 123 and 144 communicate . In addition, some of the slots 143 that have not received the column connection vacuum 12 should be airtight by other suitable means, for example by inserting a conventional return tube into the slot 143. Air tight components, suitably air tight elastic bands 13, may be placed around the perimeter of the second projection 122 of the column connecting vacuum 12. Permeable membrane column 11 is at a higher pressure than the atmospheric pressure in the slot 143 of the vacuum manifold 14 when the atmospheric pressure in the first receiving space 111 of the liquid semi- Between the first protrusion and the second protrusion 122 of the column connection vacuum 12 and between the second protrusion 122 of the column connection vacuum 12 and the top of the lead 141 around the edge of the slot 143 And is formed and held between the surfaces. The atmospheric pressure is then applied to the liquid in the liquid semipermeable membrane column 11 and at the same time the liquid is pushed out of the liquid semipermeable membrane column 11 through the liquid semipermeable membrane 112 (see FIG. 4). The purpose of the column connection vacuum 12 is to provide a loose fit and airtight effect as well as other liquid semi-permeable membranes (not shown) that each slot 143 of the vacuum manifold 14 can cause cross- It is possible to prevent contact between the column 11 and another sample.

Similarly, when the column connecting vacuum 12 'is loosely and partially received in the slot 143', the liquid semi-permeable membrane column 11 ', the column connecting vacuum 12' and the vacuum manifold 14 ' Are shown in Figs. 5 and 6. Fig. The airtight elastic band 125 'is sandwiched between the bottom of the column connection vacuum 12' and the bottom of the slot 143 '. Thereby, when the atmospheric pressure in the first receiving space 111 'of the liquid semipermeable membrane column 11' is greater than the atmospheric pressure in the slots 143 'of the vacuum manifold 14', the air- Between the first protrusion 113 'of the first column 11' and the second protrusion 122 'of the column connection vacuum 12' and the bottom part of the column connection vacuum 12 ' 12 '), the airtight elastic band 125' and the bottom of the slot 143 '. Air-tight components, suitably air-tight elastic bands 13 'can be additionally disposed around the circumference of the second protrusion 122' of the column connecting vacuum 12 'so that the first protrusion 113' Thereby enhancing the airtightness between the second projections 122 '.

Referring to Figs. 7-10, liquid semi-permeable membrane columns 11 ", 11 "'may be directly coupled to vacuum manifolds 14 ", 14"'. The airtight elastic bands 13 ", 125 "'can each be disposed around the periphery of the first projection 113" of the liquid semi-permeable membrane column 11' Can be sandwiched between the bottom of the liquid semi-permeable membrane column 11 '' 'and the bottom of the slot 143' ''. Thereby, when the atmospheric pressure in the first receiving space 111 " of the liquid semipermeable membrane column 11 "is greater than the atmospheric pressure in the slot 143" of the vacuum manifold 14 ", the air- Quot ;, or between the first projection 113 "of the liquid semi-permeable membrane column 11" and the top surface of the lid 141 "around the slot 143" Quot; 'is greater than the atmospheric pressure in the receiving space 145' '' of the base 142 '' ', the airtight condition is established between the bottom of the liquid semi-permeable membrane column 11' '' And is held between the bottoms.

From the above description, the present invention provides an apparatus that is easy to assemble and disassemble and can overcome the deficiencies of the prior art. Since the liquid semi-permeable membrane column can be easily inserted and removed, it can also be operated by a mechanical arm in an automated process. While the preferred embodiments of the invention have been described herein, those skilled in the art will readily appreciate that many modifications may be made without departing from the spirit and scope of the appended claims.

Claims (10)

At least one liquid semipermeable membrane column, at least one column connecting vacuum and a vacuum manifold, Said liquid semi-permeable membrane column comprising an inner portion forming a first receiving space having at least one liquid semipermeable membrane on the bottom, An upper portion formed with a first projection extending outwardly from the first hole, And a bottom portion formed with a first through hole, Wherein the column-connected vacuum portion comprises an inner portion defining a second receiving space, An upper portion formed with a second projection and a second projection extending outwardly, And a bottom portion formed with a third through-hole, The vacuum manifold includes a base defining a receiving space, And a lid having at least one slot extending downwardly to receive said at least one column-connected vacuum chamber and having a third through-hole communicating with a receiving space of said base, said apparatus comprising: The liquid semipermeable membrane column is loosely received in a second receiving space of the column connecting vacuum, so that the first projection of the liquid semipermeable membrane column is adjacent to the second projection of the column connecting vacuum; An airtight element is positioned around the periphery of said second projection; The column connection vacuum portion is loosely received in the slot so that the second protrusion adjoins the top surface of the lid about the edge of the slot and the first, second and third through holes communicate with each other, When the atmospheric pressure in the first receiving space of the liquid semi-permeable membrane column is greater than the atmospheric pressure in the slot of the vacuum manifold, the airtight condition is established between the first protrusion of the liquid semipermeable membrane column and the second projection of the column connecting vacuum, Is held between the second protrusion of the stud and the upper surface of the lead around the edge of the slot. The biological specimen processing apparatus according to claim 1, wherein the airtight sealing element is an airtight elastic band. A column-connected vacuum chamber for an apparatus according to claim 1, An inner portion forming a receiving space, An upper portion formed with a hole and a protrusion extending outwardly, An airtight sealing element disposed around the periphery of the projection, And a bottom portion having a through-hole formed therein. At least one liquid semipermeable membrane column, at least one column connecting vacuum and a vacuum manifold, Said liquid semi-permeable membrane column comprising an inner portion forming a first receiving space having at least one liquid semipermeable membrane on the bottom, An upper portion formed with a first projection extending outwardly from the first hole, And a bottom portion formed with a first through hole, Wherein the column-connected vacuum portion comprises an inner portion defining a second receiving space, An upper portion formed with a second projection and a second projection extending outwardly, And a bottom portion formed with a third through-hole, The vacuum manifold includes a base defining a receiving space, And a lid having at least one slot extending downwardly to receive said at least one column-connected vacuum chamber and having a third through-hole communicating with a receiving space of said base, said apparatus comprising: The liquid semipermeable membrane column is loosely received in a second receiving space of the column connecting vacuum, so that the first projection of the liquid semipermeable membrane column is adjacent to the second projection of the column connecting vacuum; An airtight element is positioned around the periphery of said second projection; The column connecting vacuum portion is loosely and partially received in the slot, so that the first, second and third through holes communicate with each other; The airtight element being sandwiched between a bottom portion of the column connection vacuum and the bottom of the slot; Thus, when the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is greater than the atmospheric pressure in the slot of the vacuum manifold, the airtight condition is established between the first protrusion of the liquid semipermeable membrane column and the second protrusion of the column semi- And is held between the protrusions and between the bottom of the column connection pads and the bottom of the slot. The biological sample processing apparatus according to claim 4, wherein the airtightness element is an airtight elastic band. 5. A column-connected vacuum chamber for an apparatus according to claim 4, An inner portion forming a receiving space, An upper portion formed with a hole and a protrusion extending outwardly, An airtight sealing element disposed around the periphery of the projection, And a bottom portion having a through-hole formed therein. At least one liquid semipermeable membrane column and a vacuum manifold, Said liquid semi-permeable membrane column comprising an inner portion forming a first receiving space having at least one liquid semipermeable membrane on the bottom, An upper portion formed with a first projection extending outwardly from the first hole, And a bottom portion formed with a first through hole, The vacuum manifold includes a base defining a receiving space, And a lid having at least one slot extending downwardly to receive said at least one liquid semipermeable membrane column and having a second through hole communicating with a receiving space of said base, said apparatus comprising: Since the liquid semipermeable membrane column is loosely received in the slot, the first projection of the liquid semipermeable membrane column is adjacent to the upper surface of the lid about the edge of the slot; The first and second through holes communicate with each other; An airtight element is positioned around the periphery of said first projection; Thus, when the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is greater than the atmospheric pressure in the slot of the vacuum manifold, the airtight condition is such that the first protrusion of the liquid semipermeable membrane column and the lid And is formed and held between the upper surfaces. The biological sample processing apparatus according to claim 7, wherein the airtightness element is an airtight elastic band. At least one liquid semipermeable membrane column and a vacuum manifold, Said liquid semi-permeable membrane column comprising an inner portion forming a first receiving space having at least one liquid semipermeable membrane on the bottom, An upper portion formed with a first projection extending outwardly from the first hole, And a bottom portion formed with a first through hole, The vacuum manifold includes a base defining a receiving space, And a lid having at least one slot extending downwardly to receive said at least one liquid semipermeable membrane column and having a second through hole communicating with a receiving space of said base, said apparatus comprising: Said liquid semipermeable membrane column being loosely and partially received within said slot; The airtight element is sandwiched between the bottom of the liquid semipermeable membrane column and the bottom of the slot, so that the first and second through holes communicate; Thus, when the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is greater than the atmospheric pressure in the receiving space of the base, an airtight condition is formed and maintained between the bottom of the liquid semipermeable membrane column and the bottom of the slot Wherein the biological sample processing apparatus comprises: 10. The biological sample processing apparatus according to claim 9, wherein the airtight sealing element is an airtight elastic band.

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