JP4459172B2 - Apparatus for processing biological samples - Google Patents

Description

(1. Field of the Invention)
The present invention relates to an apparatus for processing biological samples, and in particular, an apparatus used for washing, separating and purifying biological molecules (eg, DNA, RNA and proteins). About.

(2. Explanation of related technology)
In biological laboratories, liquid semipermeable membrane columns that are generally cylindrical are typically used to wash, separate, and purify biological molecules (eg, DNA, RNA, and proteins). One or more special purpose liquid semipermeable membranes are placed at the bottom of the column and liquid is injected into the column. Sufficient force is then applied to the liquid in the column to push the liquid out of the column through the liquid semipermeable membrane.

  Usually, the applied force is either centrifugal force or atmospheric pressure. When centrifugal force is applied through the liquid semipermeable membrane column, the column is typically placed in a liquid collection tube and the liquid is then injected into the liquid semipermeable membrane column. The column and the liquid collection tube are then placed in a centrifuge and rotated at high speed to generate a high centrifugal force that in turn causes the liquid to pass through the liquid semipermeable membrane. And is collected in this liquid collection tube. However, it is troublesome for the operator to repeat the above procedure several times during the continuous washing of the liquid semipermeable membrane column. When atmospheric pressure is applied, some liquid semipermeable membrane columns are inserted into a vacuum manifold. By applying a positive or negative atmospheric pressure, the liquid is forced out of the column through the liquid semipermeable membrane and collected in a vacuum manifold. This atmospheric pressure procedure is more convenient for operating multiple samples or for continuous operation.

  A closer examination of a liquid semipermeable membrane column (see FIG. 1) shows that the column is composed of three parts: an upper neck section 311, a central tubular section 312, and a lower tapered section 313. Indicates that The diameter of the upper neck section 311 is larger than the diameter of the central tubular section 312. Some of these columns include a lid 314. The central tubular section 312 is filled with a liquid sample and the inner bottom portion thereof is provided with one or more special purpose form semipermeable membranes (not shown). Some of these columns have a lower tapered section 313 design, but some do not have this design.

  As shown in FIG. 1, the conventional engagement between the liquid semipermeable membrane column 31 and the vacuum manifold 32 is a close insertion manner of engagement. That is, the lower tapered section 313 of the liquid semipermeable membrane column 31 is inserted directly into the hole 34 of the vacuum manifold 32 or inserted through the insertable vacuum connection column 33. The insertable vacuum connection column 33 is used to avoid inserting the liquid semipermeable membrane column 31 directly into the hole 34 of the vacuum manifold 32. This is because the holes 34 in the vacuum manifold 32 can contact any liquid semipermeable membrane column with different samples, which in turn can result in cross-contamination of different samples. The insertable vacuum connection column 33 can be disposable or simply washed for repeated use. When using the insertable vacuum connection column 33, the lower tapered section 313 of the liquid semipermeable membrane column 31 is inserted into the insertable vacuum connection column 33. This assembly is then inserted into the bore 34 of the vacuum manifold 32 and then forms the following structure: liquid semipermeable membrane column 31 -insertable vacuum connection column 33 -vacuum manifold 32. In many applications, an insertable vacuum connection column 33 is utilized, and this method is particularly an experiment in which cross-contamination of the sample is not desired, such as in an experiment using purified nucleic acids for PCR reactions. is there. It is therefore very important that this engagement must be tightly fixed so as to avoid any gas leakage. Often, the operator must manually hold the liquid semipermeable membrane column 31 and the insertable vacuum connection column 33 to ensure intimate engagement. Due to operations that require this technique, the operator may experience finger discomfort. On the other hand, if this engagement is too close, sometimes it can be difficult to dismantle, and multiple engagements can be difficult to manipulate, making liquid semipermeable membrane columns numerous Use against a sample is inconvenient.

(Summary of the Invention)
It is an object of the present invention to provide an apparatus for processing biological samples that is easier and easier to assemble and disassemble.

  For the above reasons, Applicants provide an apparatus comprising a loosely engaging liquid semipermeable membrane column, a vacuum connection column and a vacuum manifold for processing biological samples. This allows the operator to use the device in a quick and comfortable manner.

  The apparatus of the present invention comprises at least one liquid semipermeable membrane column, at least one vacuum connection column and a vacuum manifold, all of which fit loosely together. An airtight material (eg, an airtight elastic band) is placed in a position where the liquid semipermeable membrane column, one vacuum connection column and the vacuum manifold engage each other, thereby reducing the atmospheric pressure in the liquid semipermeable membrane column. If higher than the pressure in the manifold, the device is airtight and maintained airtight. When a liquid sample is placed in a liquid semipermeable membrane column, the atmospheric pressure can push the liquid out of the column through the liquid semipermeable membrane.

  The liquid semipermeable membrane column comprises an inner section, a top section and a bottom section. This internal section, together with at least one liquid semipermeable membrane located at the bottom of the column, defines a first receiving space. The top section is formed with a first opening and has a first protrusion that extends outwardly from the top section. The bottom section is formed with a first through hole.

  The vacuum connection column comprises an inner section, a top section and a bottom section. This inner section defines a second receiving space. The top section is formed with a second opening and has a second protrusion that extends outwardly from the top section. The bottom section is formed with a second through hole. The vacuum manifold includes a base defining a receiving space and a lid having at least one slot. The slot extends downward from the lid to receive at least one vacuum connection column. The slot is formed with a third through hole that communicates with the receiving space of the base.

  The liquid semipermeable membrane column is loosely received in the second receiving space of the vacuum connection column so that the first protrusion of the liquid semipermeable membrane column is the second protrusion of the vacuum connection column. Abut. An airtight element (eg, an airtight elastic band) is disposed around the outer periphery of the second protrusion. The vacuum connection column is loosely received in the slot so that the second protrusion abuts the top surface of the lid around the edge of the slot and the first through hole, the second When the second through hole and the third through hole are in communication such that the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the atmospheric pressure in the slot of the vacuum manifold, the airtight state is Between the first protrusion of the liquid semipermeable membrane column and the second protrusion of the vacuum connection column and the second protrusion of the vacuum connection column and around the edge of the slot. Maintained between the top surface of the lid.

  In another embodiment according to the invention, the hermetic element is sandwiched between the bottom section of the vacuum connection column and the bottom of the slot, so that the atmospheric pressure in the first receiving space of this liquid semipermeable membrane column Is higher than the atmospheric pressure in the slot of the vacuum manifold, an airtight condition exists between the first protrusion of the liquid semipermeable membrane column and the second protrusion of the vacuum connection column and the vacuum. Maintained between the bottom section of the connecting column and the bottom of this slot. Furthermore, the liquid semipermeable membrane column can also be directly engaged with the vacuum manifold, and an airtight element can be disposed around the outer periphery of the first protrusion, or the bottom of the liquid semipermeable membrane column It can be sandwiched between the section and the bottom of this slot to achieve the same hermetic effect.

The present invention provides the following:
(Item 1)
An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An inner section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed having a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column comprising:
At least one vacuum connection column, the vacuum connection column comprising:
An internal section defining a second receiving space;
A top section, the top section being formed with a second opening and a second protrusion, the second protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a second through-hole,
A vacuum connection column; and a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downwardly from the lid to receive at least one vacuum connection column, the at least one slot being A lid formed with a third through hole communicating with the receiving space of the base,
A vacuum manifold,
This device comprises the following:
The liquid semipermeable membrane column is loosely received in the second receiving space of the vacuum connection column so that the first protrusion of the liquid semipermeable membrane column is the second protrusion of the vacuum connection column. The airtight element is arranged around the outer periphery of the second protrusion; the vacuum connection column is loosely received in the slot, so that the second protrusion Abuts the top surface of the lid around the edge of the slot, and the first through hole, the second through hole, and the third through hole communicate with each other; If the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold, the first protrusion of the liquid semipermeable membrane column and the pressure of the vacuum connection column This vacuum connection column can be connected between the second protrusion and Between the second upper surface of the lid around the edge of the protrusion and the slot, the airtight state is formed and to be maintained,
A device characterized by.
(Item 2)
Item 2. The device of item 1, wherein the hermetic element is a hermetic elastic band.
(Item 3)
A vacuum connection column for a device according to item 1, wherein the vacuum connection column is:
An internal section that defines the receiving space;
A top section formed with an open portion and a protrusion, the protrusion extending outwardly from the top section;
An airtight element disposed around the perimeter of the protrusion; and a bottom section formed with a through hole,
A vacuum connection column comprising:
(Item 4)
An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An inner section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed having a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column comprising:
At least one vacuum connection column, the vacuum connection column comprising:
An internal section defining a second receiving space;
A top section, the top section being formed with a second opening and a second protrusion, the second protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a second through-hole,
A vacuum connection column; and a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downwardly from the lid to receive at least one vacuum connection column, the at least one slot being A lid formed with a third through hole communicating with the receiving space of the base,
A vacuum manifold,
This device comprises the following:
The liquid semipermeable membrane column is loosely received in the second receiving space of the vacuum connection column so that the first protrusion of the liquid semipermeable membrane column is the second of the vacuum connection column. Abutting the second protrusion; an airtight element is arranged around the outer periphery of the second protrusion; the vacuum connection column is loosely received partially in the slot, so that The first through hole, the second through hole, and the third through hole communicate with each other; an airtight element is sandwiched between the lower section of the vacuum connection column and the bottom of the slot So that if the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold, the first protrusion of the liquid semipermeable membrane column and the Between this second protrusion of the vacuum connection column And between the second protruding portion of the vacuum connection column with the upper surface of the lid around the edges of the slot, the airtight state is formed and to be maintained,
A device characterized by.
(Item 5)
Item 5. The apparatus of item 4, wherein the airtight element is an airtight elastic band.
(Item 6)
A vacuum connection column for an apparatus according to item 4, wherein the vacuum connection column is:
An internal section that defines the receiving space;
A top section formed with an open portion and a protrusion, the protrusion extending outwardly from the top section;
An airtight element disposed around the perimeter of the protrusion; and a bottom section formed with a through hole,
A vacuum connection column comprising:
(Item 7)
An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An inner section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed having a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column; and a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downward from the lid to receive at least one liquid semipermeable membrane column, the at least one slot The slot is formed to have a second through hole communicating with the receiving space of the base, a lid;
A vacuum manifold,
This device comprises the following:
The liquid semipermeable membrane column is loosely received in the slot so that the first protrusion of the liquid semipermeable membrane column is around the edge of the slot and the top surface of the lid And the first through hole, the second through hole, and the third through hole communicate with each other; an airtight element is disposed around the outer periphery of the first protrusion. Thereby, if the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold, the first protrusion and the slot of the liquid semipermeable membrane column; An airtight condition is formed and maintained between the lid upper surface around the edge of the
A device characterized by.
(Item 8)
8. A device according to item 7, wherein the airtight element is an airtight elastic band.
(Item 9)
An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An inner section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed having a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column; and a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downward from the lid to receive at least one liquid semipermeable membrane column, the at least one slot The slot is formed to have a second through hole communicating with the receiving space of the base, a lid;
A vacuum manifold,
This device comprises the following:
The liquid semipermeable membrane column is loosely partially received in the slot; an airtight element is sandwiched between the bottom section of the liquid semipermeable membrane column and the bottom of the slot; As a result, the first through hole communicates with the second through hole; thereby, the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold. An airtight condition is formed and maintained between the bottom section of the liquid semipermeable membrane column and the bottom of the slot;
A device characterized by.
(Item 10)
Item 10. The device according to Item 9, wherein the airtight element is an airtight elastic band.

  An apparatus for processing a biological sample, which is typically used to wash, separate and purify biological molecules (eg, DNA, RNA and proteins). The apparatus comprises at least one liquid semipermeable membrane column, at least one vacuum connection column and a vacuum manifold, all of which are loosely received from one another. An airtight material (e.g., an airtight elastic band) is disposed at a position where the liquid semipermeable membrane column, the one vacuum connection column, and the vacuum manifold engage each other, thereby providing the liquid semipermeable membrane. If the atmospheric pressure in the column is higher than the pressure in the vacuum manifold, the device becomes airtight and is kept airtight. When a liquid sample is placed inside a liquid semipermeable membrane column, atmospheric pressure can push the liquid out of the column through the liquid semipermeable membrane. Thus, this device is easier and more convenient to assemble and disassemble than conventional devices.

  Other objects, advantages and novel features of the invention will be taken from the following detailed description of preferred embodiments of the invention, along with the accompanying drawings.

  The present invention provides an apparatus for processing biological samples that is easier and easier to assemble and disassemble.

(Detailed description of the invention)
FIG. 2 illustrates a schematic diagram of a conventional liquid semipermeable membrane column used in combination with a vacuum connection column according to the present invention. In general, the liquid semipermeable membrane column 11 is of a tubular shape and comprises an inner section, a top section and a bottom section. The inner section defines a first receiving space 111 and at least one liquid semipermeable membrane 112 is disposed at the bottom of the first receiving space 111. The top section is formed with a first opening (not shown) and a first protrusion 113 extends outwardly from the top section, while the bottom section is One through hole 114 is formed.

  In general, the vacuum connection column 12 is of a tubular shape and can be made from any suitable material. The vacuum connection column 12 comprises an inner section, a top section and a bottom section. This inner section defines a second receiving space 121. The top section is formed to have a second opening (not shown) and the second protrusion 122 extends outward from the top section, while the bottom section is The second through hole 123 is formed. The inner diameter of the vacuum connection column 12 is larger than the outer diameter of the central tubular section of the liquid semipermeable membrane column 11, but smaller than the outer diameter of the first protrusion 113 of the liquid semipermeable membrane column 11. When the membrane column 11 is loosely received in the second receiving space 121 of the vacuum connection column 12 through the second opening, the first protrusion 113 of the liquid semipermeable membrane column 11 It is adapted to abut against the second protrusion 122. Further, an airtight element (preferably, an airtight elastic band 13) is disposed around the outer periphery of the second protrusion 122 of the vacuum connection column 12, and the first protrusion 113 and the second protrusion 122 are The airtightness between them can be increased.

  Referring to FIGS. 3 and 4, these figures illustrate perspective and cross-sectional views of an apparatus 10 for processing biological samples according to the present invention. The apparatus 10 comprises at least one liquid semipermeable membrane column 11, at least one vacuum connection column 12 and a vacuum manifold 14. The decompression manifold 14 includes a lid 141 and a base 142. Base 142 defines a receiving space 145 (see FIG. 4). The lid 141 includes an upper surface and at least one slot 143 that extends downwardly from the lid to receive at least one vacuum connection column 12. The slot 143 has a bottom that is formed to have a third through hole 144 that in turn communicates with the receiving space 145 of the base 142.

  The diameter of the slot 143 is slightly larger than the diameter of the central tubular section of the vacuum connection column 12, but smaller than the diameter of the second protrusion 122 of the vacuum connection column 12, so that the liquid semipermeable membrane column 11 is vacuum connected. When received in the column 12, the vacuum connection column 12 can be loosely received in the slot 143. The second protrusion 122 is then adapted to abut the upper surface of the lid 141 around the edge of the slot 143, and the first through hole 114, the second through hole 123, and the third The through hole 144 communicates. Further, all slots 143 that do not receive the vacuum connection column 12 should be airtight by other suitable means (eg, by inserting a conventional collection tube into the slot 143). An airtight element (preferably an airtight elastic band 13) may be arranged around the outer periphery of the second protrusion 122 of the vacuum connection column 12. As a result, when the atmospheric pressure in the first receiving space 111 of the liquid semipermeable membrane column 11 is higher than the atmospheric pressure in the slot 143 of the decompression manifold 14, the airtight state becomes the first in the liquid semipermeable membrane column 11. Between the protrusion 113 and the second protrusion 122 of the vacuum connection column 12 and between the second protrusion 122 of the vacuum connection column 12 and the upper surface of the lid 141 around the edge of the slot 143, Formed and maintained. Next, atmospheric pressure is applied to the liquid in the liquid semipermeable membrane column 11, and at the same time, the liquid is pushed out from the liquid semipermeable membrane column 11 through the liquid semipermeable membrane 112 (see FIG. 4). The purpose of the vacuum connection column 12 is not only to provide a loose fit and hermetic effect, but in the case of repeated operations, each slot 143 of the vacuum manifold 14 contacts a different liquid semipermeable membrane column 11 with a different sample. (This can lead to cross-contamination).

  Similarly, the airtightness between the liquid semipermeable membrane column 11 ′, the vacuum connection column 12 ′, and the vacuum manifold 14 ′ when the vacuum connection column 12 ′ is loosely received partially in the slot 143 ′. Engagement is illustrated in FIGS. A hermetic elastic band 125 'is sandwiched between the bottom section of the vacuum connection column 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 higher than the atmospheric pressure in the slot 143 ′ of the decompression manifold 14 ′, the airtight state is changed to the liquid semipermeable membrane column 11. Between the 'first projection 113' of the first and the second projection 122 'of the vacuum connection column 12' and the bottom section of the vacuum connection column 12 ', the liquid-tight elastic band 125' and the bottom of the slot 143 '. Maintained during. An airtight element (preferably an airtight elastic band 13 ') is further arranged around the outer periphery of the second protrusion 122' of the vacuum connection column 12 'to provide a first protrusion 113' and a second protrusion. Airtightness between 122 'can be enhanced.

  With reference to FIGS. 7 to 10, the liquid semipermeable membrane columns 11 ", 11" "can directly engage the vacuum manifolds 14", 14 "", respectively. The hermetic elastic bands 13 ″, 125 ′ ″ can be respectively arranged on the outer periphery of the first protrusion 113 ″ of the liquid semipermeable membrane column 11 ″ or around the outer periphery of the first through-hole 144 ″. It can be sandwiched between the bottom section of the liquid semipermeable 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 higher than the atmospheric pressure in the slot 143 ″ of the decompression manifold 14 ″, the airtight state is changed to the liquid semipermeable membrane column 11. Is maintained between the first projection of "and the upper surface of the lid 141" around the edge of the slot 143 ". Alternatively, the first receiving space 111 'of the liquid semipermeable membrane column 11'" If the atmospheric pressure in 'is higher than the atmospheric pressure in the receiving space 145' 'of the base 142' '', an airtight state is established between the bottom section of the liquid semipermeable membrane 11 '' 'and the bottom of the slot 143' ''. Maintained during.

  From the above description, it is clear that the present invention provides an apparatus that can be easily assembled and disassembled and overcomes the drawbacks in drilling techniques. Since this liquid semipermeable membrane column can be easily inserted and withdrawn, it can also be operated in automatic processing with a mechanical arm. While the invention has been described in terms of several preferred embodiments, those skilled in the art will recognize that the invention can still be practiced with modification within the spirit and scope of the appended claims. recognize.

FIG. 1 illustrates a schematic diagram of a conventional apparatus for processing biological samples. FIG. 2 illustrates a schematic diagram of a conventional liquid semipermeable membrane column used in combination with a vacuum connection column according to the present invention. FIG. 3 illustrates a perspective view of an apparatus for processing biological samples according to the present invention. FIG. 4 illustrates a cross-sectional view of the apparatus of FIG. FIG. 5 illustrates a perspective view of an alternative embodiment of an apparatus according to the present invention. FIG. 6 illustrates a cross-sectional view of the apparatus of FIG. FIG. 7 illustrates a perspective view of an alternative embodiment of the device according to the invention. FIG. 8 illustrates a cross-sectional view of the apparatus of FIG. FIG. 9 illustrates a perspective view of an alternative embodiment of an apparatus according to the present invention. FIG. 10 illustrates a cross-sectional view of the apparatus of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Apparatus 11 Liquid semipermeable membrane column 12 Vacuum connection column 13 Airtight material 14 Vacuum manifold

Claims (10)

An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An internal section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed with a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column comprising:
At least one vacuum connection column, the vacuum connection column comprising:
An internal section defining a second receiving space;
A top section, the top section being formed with a second opening and a second protrusion, the second protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a second through-hole,
A vacuum connection column comprising: a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downwardly from the lid to receive at least one vacuum connection column, the at least one slot being A lid formed to have a third through hole communicating with the receiving space of the base,
A vacuum manifold,
The apparatus comprises:
The liquid semipermeable membrane column is loosely received in the second receiving space of the vacuum connection column so that the first protrusion of the liquid semipermeable membrane column is the second of the vacuum connection column. An airtight element is disposed around the outer periphery of the second protrusion; the vacuum connection column is loosely received in the slot, so that the second protrusion A portion abuts the top surface of the lid around the edge of the slot, and the first through hole, the second through hole, and the third through hole are in communication; When the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold, the first protrusion of the liquid semipermeable membrane column and the vacuum connecting column Between the second protrusion and around the edge of the second protrusion and the slot of the vacuum connection column. Between the upper surface of the lid, the airtight state is formed and to be maintained,
A device characterized by.   The apparatus of claim 1, wherein the hermetic element is a hermetic elastic band. A vacuum connection column for the apparatus of claim 1, wherein the vacuum connection column is:
An internal section that defines the receiving space;
A top section formed with an open portion and a protrusion, the protrusion extending outwardly from the top section;
An airtight element disposed around the perimeter of the protrusion; and a bottom section formed to have a through hole;
A vacuum connection column comprising: An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An internal section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed with a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column comprising:
At least one vacuum connection column, the vacuum connection column comprising:
An internal section defining a second receiving space;
A top section, the top section being formed with a second opening and a second protrusion, the second protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a second through-hole,
A vacuum connection column comprising: a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downwardly from the lid to receive at least one vacuum connection column, the at least one slot being A lid formed to have a third through hole communicating with the receiving space of the base,
A vacuum manifold,
The apparatus comprises:
The liquid semipermeable membrane column is loosely received in the second receiving space of the vacuum connection column so that the first protrusion of the liquid semipermeable membrane column is the second of the vacuum connection column. Abutment of the second protrusion; an airtight element is arranged around the outer periphery of the second protrusion; the vacuum connection column is loosely partially received in the slot, so that The first through-hole, the second through-hole, and the third through-hole communicate; an airtight element is sandwiched between the lower section of the vacuum connection column and the bottom of the slot Thereby, when the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold, the first protrusion of the liquid semipermeable membrane column and the Between the second protrusion of the vacuum connection column and the second protrusion of the vacuum connection column. Between the parts and the lid of the upper surface around the edge of the slot, the airtight state is formed and to be maintained,
A device characterized by.   The apparatus of claim 4, wherein the hermetic element is a hermetic elastic band. 5. A vacuum connection column for the apparatus of claim 4, wherein the vacuum connection column is:
An internal section that defines the receiving space;
A top section formed with an open portion and a protrusion, the protrusion extending outwardly from the top section;
An airtight element disposed around the perimeter of the protrusion; and a bottom section formed to have a through hole;
A vacuum connection column comprising: An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An internal section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed with a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column; and a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downwardly from the lid to receive at least one liquid semipermeable membrane column, the at least one slot A slot formed with a second through hole communicating with the receiving space of the base;
A vacuum manifold,
The apparatus comprises:
The liquid semipermeable membrane column is loosely received in the slot so that the first protrusion of the liquid semipermeable membrane column is around the edge of the slot and the top surface of the lid And the first through hole and the second through hole communicate with each other; an airtight element is disposed around the outer periphery of the first protrusion; When the atmospheric pressure in the first receiving space of the permeable column is higher than the pressure in the slot of the vacuum manifold, the liquid around the first protrusion and the edge of the slot of the liquid semipermeable membrane column An airtight state is formed and maintained between the top surface of the lid,
A device characterized by.   The apparatus of claim 7, wherein the hermetic element is a hermetic elastic band. An apparatus for processing a biological sample, the apparatus comprising:
At least one liquid semipermeable membrane column, the liquid semipermeable membrane column comprising:
An internal section defining a first receiving space, the first receiving space having at least one liquid semipermeable membrane at the bottom of the space;
A top section, the top section being formed with a first opening and a first protrusion, the first protrusion extending outwardly from the top section; A top section; and a bottom section formed to have a first through hole;
A liquid semipermeable membrane column; and a vacuum manifold, the vacuum manifold comprising:
A base defining a receiving space; and a lid having at least one slot, the slot extending downwardly from the lid to receive at least one liquid semipermeable membrane column, the at least one slot A slot formed with a second through hole communicating with the receiving space of the base;
A vacuum manifold,
The apparatus comprises:
The liquid semipermeable membrane column is loosely partially received in the slot; an airtight element is sandwiched between the bottom section of the liquid semipermeable membrane column and the bottom of the slot; As a result, the first through hole and the second through hole communicate with each other; thereby, the atmospheric pressure in the first receiving space of the liquid semipermeable membrane column is higher than the pressure in the slot of the vacuum manifold. An airtight condition is formed and maintained between the bottom section of the liquid semipermeable membrane column and the bottom of the slot;
A device characterized by.   The apparatus of claim 9, wherein the hermetic element is a hermetic elastic band.

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