JP2007252338A - Compression device of extraction cartridge - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent remaining compressed air from blowing vigorously from an air nozzle in a compression device of the extraction cartridge of a nucleic acid extraction device. <P>SOLUTION: This air-feeding unit 30A is constituted by an air pump 31A, a check valve 32A and an air nozzle 15A. A filter for resistance 93 is installed at the air nozzle 15A. Although, when the filter of an extraction cartridge 2 is clogged, the air nozzle 15A has to be retreated once, at that time, remaining compressed air in a tubular passage 91 of a check valve 32A passes through the filter 93 for resistance so that the flow rate of the compressed air is suppressed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a pressure device for an extraction cartridge in which a liquid containing a specific substance is injected into an extraction cartridge having a filter member, and the specific substance is adhered to the filter member by pressurized air.

  Known nucleic acid extraction methods for extracting nucleic acids include those using magnetic beads and those using filters. The nucleic acid extraction method using a filter has an advantage that the nucleic acid can be extracted with high purity and high yield compared to the nucleic acid extraction method using magnetic beads.

  In the nucleic acid extraction method using a filter, a sample solution containing nucleic acid is injected and allowed to pass through the filter to adsorb the nucleic acid, and then the recovered solution is injected and passed through the filter to separate the nucleic acid and the filter. The nucleic acid is recovered together with the recovery liquid. Known methods for applying pressure to the liquid and passing through the filter include a method using a centrifuge, a method using reduced pressure, and a method using pressurization.

  In the system using a centrifuge, there is a problem that the apparatus becomes very large and the operation of the apparatus becomes complicated. Further, in the method using the reduced pressure, only a pressure of 1 atm can be applied at the maximum, and there is a problem that it takes time for the extraction process. On the other hand, in the method using pressurization, the apparatus is not as large as the apparatus using the centrifuge described above, and the pressure can be applied arbitrarily, so that the extraction process can be completed in a relatively short time. For this reason, the present applicant has proposed a nucleic acid extraction method in which pressure is applied to the liquid using pressure to pass through the filter. The applicant of the present invention has proposed to use a porous membrane filter that is extremely thin as compared with a conventional glass fiber filter and that has high nucleic acid adsorption and easy desorption.

Patent Document 1 describes a pressure device (nucleic acid extraction device) for an extraction cartridge. The pressure device includes an air nozzle that is in close contact with the extraction cartridge and supplies pressurized air, a pressure head that holds the air nozzle, and a head moving unit that moves the pressure head up and down. When the pressure head is lowered, the air nozzle comes into close contact with the extraction cartridge, and the sample liquid passes through the filter by the pressurized air supplied from the air nozzle, and the nucleic acid in the sample liquid adheres to the filter. When the pressure head rises, the air nozzle moves away from the extraction cartridge.
JP 2005-328730 A

  In the pressure extraction process using such a pressure device, the sample liquid may be clogged when passing through the filter, and the sample liquid may not pass through the filter due to the clogging. When clogging occurs, it is common practice to raise the pressure head once to retract the air nozzle, and then lower the pressure head again to bring the air nozzle into close contact and supply pressurized air. ing. However, when the pressure head is raised and the air nozzle is withdrawn, the pressure air remaining in the air flow channel upstream of the air nozzle is blown out vigorously, and this pressure air is blown against the liquid surface of the sample liquid. The sample liquid sometimes splattered. If the sample liquid scatters and adheres to an air nozzle or the like, this causes contamination.

  In particular, the applicant has developed an inexpensive extraction cartridge pressurizing device in which the pressurizing head is manually moved, and the moving speed of the pressurizing head varies depending on the operator. When the moving speed of the pressurizing head is fast, the pressure in the extraction cartridge rapidly decreases, so that the pressurized air is blown out more vigorously and the sample liquid is likely to be scattered.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a pressure device for an extraction cartridge that prevents pressurized air from being blown out from an air nozzle.

  The present invention relates to a pressurizing device for an extraction cartridge that supplies pressurized air to an extraction cartridge that attaches a specific substance contained in a liquid injected from an inlet to a filter member, and is applied in close contact with the inlet of the extraction cartridge. The air nozzle for supplying pressurized air, the air nozzle and the extraction cartridge are relatively displaced so as to be in a close contact state where the air nozzle is in close contact with the inlet of the extraction cartridge and a retracted state where the air nozzle is separated from the inlet of the extraction cartridge Displacement means, an air pump for generating pressurized air, an air flow path for feeding the pressurized air of the air pump to the air nozzle, and an air flow path resistance provided in the air flow path for reducing the flow rate of the pressurized air Means. The present invention is preferably used when the liquid containing the specific substance is a sample liquid containing nucleic acid.

  The displacement means is a head that displaces the pressure head between a pressure head that holds the air nozzle, an air supply position where the air nozzle is in the close contact state, and a retreat position where the air nozzle is in the retracted state. It is preferable to have a displacement mechanism. The head displacement mechanism preferably includes a cam that selectively positions the pressure head at the air supply position or the retracted position, and an operation unit that rotates the cam.

  The air flow path resistance means is preferably provided in the air flow path of the air nozzle. By providing the air flow path resistance means as downstream as possible, the effect of the air flow path resistance means is increased. The air flow path resistance means is preferably a resistance filter member. This resistance filter is a biofilter and preferably has a large number of minute holes. The hole diameter is preferably 0.22 μm or less. If the hole diameter is 0.22 μm or less, the flow rate of the pressurized air can be effectively suppressed. The air flow path resistance means may be an orifice.

  According to the pressurizing device for the extraction cartridge of the present invention, it is possible to prevent the sample liquid from being scattered by the remaining pressurized air. For this reason, there is no problem even if the pressure head is displaced manually.

  Before describing the pressurizing device for the extraction cartridge of the present invention, the nucleic acid extraction process will be described. The nucleic acid extraction process is performed according to the procedure shown in FIGS. First, as shown in FIG. 1A, a sample solution S containing a nucleic acid is injected into the extraction cartridge 2. Next, as shown in (B), pressurized air is introduced into the extraction cartridge 2 on the waste liquid container 3 for pressurization, the sample solution S is passed through the filter 2a, and the nucleic acid is adsorbed on the filter 2a. The liquid component that has passed through the filter 2 a is discharged to the waste liquid container 3.

  Next, as shown in (C), the cleaning liquid W is injected into the extraction cartridge 2. Next, as shown in (D), pressurized air is introduced into the extraction cartridge 2 to pressurize it, and other impurities are washed away while holding the nucleic acid in the filter 2a. The cleaning liquid W that has passed through the filter 2 a is discharged to the waste liquid container 3. The cleaning liquid injection operation and the cleaning operation may be repeated a plurality of times.

  Next, as shown in (E), the waste liquid container 3 below the extraction cartridge 2 is replaced with a collection container 4. Next, as shown in (F), the recovery liquid R is injected into the extraction cartridge 2. Finally, as shown in (G), the extraction cartridge 2 is pressurized by introducing pressurized air, weakens the binding force between the filter 2a and the nucleic acid, releases the adsorbed nucleic acid, and contains the nucleic acid-containing recovery solution R is collected in the collection container 4.

  The filter 2a of the extraction cartridge 2 is basically porous so that the nucleic acid can pass through, and its surface has a characteristic of adsorbing the nucleic acid in the sample solution S with a chemical binding force. The adsorption is held, and the nucleic acid adsorption force is weakened and separated during collection by the collection liquid R. For example, the filter 2a is composed of an organic polymer having a hydroxyl group on the surface, as described in detail in the method for separating and purifying nucleic acid described in JP-A-2003-128691. The organic polymer having a hydroxyl group on the surface is preferably a surface saponified product of acetylcellulose. As acetyl cellulose, any of monoacetyl cellulose, diacetyl cellulose, and triacetyl cellulose may be used, and triacetyl cellulose is particularly preferable.

  The “sample solution S containing nucleic acid” is a state in which a sample containing cells or viruses is pretreated. The pretreatment is a treatment in which a water-soluble organic solvent is added to a solution in which a nucleic acid is dispersed in a solution by dissolving the sample. For example, in the diagnostic field, whole blood collected as a sample, plasma, serum, urine, feces, semen, saliva and other body fluids, plants (or parts thereof), animals (or parts thereof), etc. Of interest are solutions prepared from biological materials such as lysates and homogenates. The “lysis treatment” is a treatment with an aqueous solution containing a reagent (eg, guanidine salt, surfactant, or proteolytic enzyme) that dissolves cell membranes and nuclear membranes to solubilize nucleic acids. In the case of whole blood, red blood cells and various proteins are decomposed and depolymerized to prevent non-specific adsorption and clogging to the filter 2a, and leukocytes and nuclear membranes are lysed to solubilize nucleic acids to be extracted. Examples of the “water-soluble organic solvent” include ethanol, isopropanol, propanol and the like, and ethanol is particularly preferable. The concentration of the water-soluble organic solvent is preferably 5 to 90% by weight, more preferably 15 to 50% by weight. The concentration of ethanol added is particularly preferably as high as possible without causing aggregates.

  The “washing liquid W” has a function of washing out impurities in the sample liquid S adhering to the filter 2a together with the nucleic acid, that is, a function of releasing impurities while leaving the nucleic acid adsorbed as it is. Accordingly, it comprises an aqueous solution containing a surfactant. Examples of the main agent include about 10 to 100% by weight (preferably 10 to 90% by weight, more preferably 30 to 80% by weight) of an aqueous solution of methanol, ethanol, isopropanol, n-isopropanol, butanol, acetone and the like.

  The “recovered liquid R” preferably has a low salt concentration, and in particular, a solution having a salt concentration of 0.5 M or less, such as purified distilled water or TE buffer, is used.

  As shown in FIG. 2, the pressurizing device 10 includes a base 11, a mounting tray (rack insertion base) 12 that can be detached from the base 11, and side plates attached to both side surfaces of the base 11. 13, a pressure head 16 that can swing about a shaft 14 provided on the side plate 13 and holds eight air nozzles 15 </ b> A to 15 </ b> H, and a head that is manually operated to displace the pressure head 16. And a displacement mechanism 17. A rack 18 that holds the extraction cartridge 2, the waste liquid container 3, and the recovery container 4 is detachable from the pressurizing device 10. In the following, the description will be made using the XYZ coordinate system, but the description may be made using the front-rear direction, the horizontal direction, and the vertical direction, respectively, instead of the X-axis direction, the Y-axis direction, and the Z-axis direction.

  In the following, first, the extraction cartridge 2 will be described. As shown in FIG. 3, the extraction cartridge 2 has a cylindrical main body 2b, a filter 2a held at the bottom of the cylindrical main body 2b, and a thin tube nozzle protruding at the center of the lower end of the cylindrical main body 2b. It is comprised from the discharge part 2c and the two protrusions 2d provided in the side part of the cylindrical main body 2b. An inlet 2e for each liquid is formed on the upper surface of the cylindrical main body 2b, and a discharge port 2f is formed on the lower surface of the discharge part 2c.

  Next, the rack 18 will be described. As shown in FIG. 4, the rack 18 includes a cartridge holder 19 that holds the extraction cartridge 2, and a container holder 20 that holds the waste liquid container 3 and the recovery container 4.

  The cartridge holder 19 has a two-part structure in which plate materials are joined, is formed in a columnar shape, and extends in the Y-axis direction. Two support legs 25 extending in the negative Z-axis direction are provided at both ends of the cartridge holder 19. On the upper surface of the cartridge holder 19, cartridge holding holes 19a for holding the extraction cartridge 2 are formed side by side in the Y-axis direction. Eight cartridge holding holes 19a extend in the Z-axis direction and are formed at a predetermined pitch. A groove 19b is formed in the cartridge holding hole 19a, and the extraction cartridge 2 is inserted by engaging the protrusion 2d of the extraction cartridge 2 with the groove 19b.

  A locking plate (not shown) is provided inside the cartridge holder 19 so as to be movable in the Y-axis direction. When the extraction cartridge 2 is inserted into the cartridge holding hole 19a, the protrusion 2d is caught by the locking plate, and the extraction cartridge 2 is held. When the button 22 provided on the front surface of the cartridge holder 19 is pressed, the locking plate slides and the groove formed in the locking plate overlaps the groove 19b, whereby the holding of the extraction cartridge 2 is released and the extraction cartridge 2 is Fall. The used cartridge can be discarded without dirtying hands. Further, since the extraction cartridge 2 is dropped and discarded without being taken out upward, the leading end portion of the extraction cartridge 2 does not come into contact with the cartridge holder 19, so that the cartridge holder 19 is not contaminated and contamination is prevented. be able to.

  The container holder 20 is formed in a rectangular parallelepiped shape, and a handle 21 is provided on the front surface. A waste liquid container holding groove 20 a for holding the waste liquid container 3 is formed in the front surface of the upper surface of the container holder 20 so as to be arranged in the Y-axis direction. In addition, a collection container holding groove 20b for holding the collection container 4 is formed in the rear portion of the upper surface of the container holder 20 so as to be arranged in the Y-axis direction. Eight waste liquid container holding grooves 20a and recovery container holding grooves 20b are formed at a predetermined pitch. A slit 20c that penetrates to the waste liquid container holding groove 20a is formed on the front surface of the container holder 20. The waste liquid container 3 is formed of a transparent resin, and by visually checking the waste liquid container 3 through the slit 20c, it is possible to confirm the amount of storage that the waste liquid container 3 stores at that time.

  A placement groove 28 on which the support leg 25 of the cartridge holder 19 is placed is formed on the front side of the container holder 20 in the Y-axis direction, and a placement groove 29 is formed on the rear side of the side. The cartridge holder 19 can be selectively attached to either the first attachment position where the support leg 25 is placed in the placement groove 28 or the second attachment position where the support leg 25 is placed in the placement groove 29. it can. When the cartridge holder 19 is attached to the first attachment position, the discharge part 2c of the extraction cartridge 2 is inserted into the waste container 3, while when the cartridge holder 19 is attached to the second attachment position, the discharge part 2c of the extraction cartridge 2 Is inserted into the collection container 4.

  As shown in FIG. 2, the rack 18 to which the cartridge holder 19 is attached is temporarily placed on the placement tray (rack insertion base) 12 and then slid in the negative direction of the X-axis, thereby causing the pressure device 10 to move. Installing. The width of the placement portion of the placement tray 12 in the Y-axis direction is approximately the same size as the width of the rack 18 in the Y-axis direction. The pressing device 10 is provided with an abutting block 26 extending in the Y-axis direction. When the rack 18 is slid in the X-axis minus direction, the abutment surface 27 of the rack 18 abuts against the abutment block 26 and the rack 18 is positioned. The rack 18 is positioned where the plurality of extraction cartridges 2 to be held are positioned directly below the air nozzles 15A to 15H, respectively.

  Here, since the abutting surface 27 of the rack 18 is the rear surface of the cartridge holder 19, the cartridge holder 19 can be held regardless of whether the cartridge holder 19 is attached to the first attachment position or the second attachment position. A plurality of extraction cartridges 2 can be positioned directly below the air nozzles 15A to 15H, respectively. The mounting tray 12 and the abutting block 26 constitute a rack holding unit. Further, “WASH” is marked on the upper surface of the loading tray 12. During the nucleic acid recovery operation, when the rack 18 is attached to the pressurizing device 10 with the cartridge holder 19 being attached to the first attachment position by mistake without being attached to the second attachment position, the characters “WASH” are exposed. This makes it possible for the operator to notice that an incorrect operation is being performed. A symbol or the like may be marked on the upper surface of the mounting tray 12 instead of characters.

  As will be described in detail later, the shaft 14 is used as a drive shaft for driving the air pump of the pressure head 16 in addition to being used as a rotation shaft serving as a swing center of the pressure head 16. The shaft 14 has a regular octagonal cross section. The shaft 14 is rotated by a motor 82 (see FIG. 9) in principle, but can also be rotated by a manual handle (operation member) 23 detachably connected to the shaft 14. The handle 23 has a fitting groove 23 a that fits into the shaft 14. The handle 23 may be connected to the shaft 14 through a gear or the like. The motor 82 and the handle 23 serve as a driving source for rotating the shaft 14.

  Hereinafter, the pressure head 16 and the head displacement mechanism 17 will be described. The pressure head 16 has eight air supply units 30A to 30H shown in FIG. The air supply units 30 </ b> A to 30 </ b> H are arranged along the shaft 14, are not fixed to each other, and are connected via the shaft 14. Air supply units 30A to 30H include air pumps 31A to 31H, check valves 32A to 32H connected to the front portions of these air pumps 31A to 31H, and air nozzles connected to the lower portions of these check valves 32A to 32H, respectively. 15A to 15H.

  As illustrated in FIG. 6, the pressure head 16 includes air supply units 30 </ b> A to 30 </ b> H (see FIG. 5), a head base 66 that holds these air supply units 30 </ b> A to 30 </ b> H, and a shaft 14. Although not shown, the head base 66 is supported by the shaft 14 via a bearing, and is rotatable about the shaft 14.

  The head displacement mechanism 17 includes a tension spring 62, a rotary shaft 63 provided on the side plate 13 (see FIG. 2) of the pressure device 10, a cam 64 fixed to the rotary shaft 63, and both ends of the rotary shaft 63. It is comprised from the holding part (operation part) 65 (refer FIG. 2) fixed to the part.

  The upper end 62 a of the tension spring 62 is attached to the side plate 13, and the lower end 62 b is attached to the head base 66 of the pressure head 16. By this tension spring 62, the pressure head 16 is urged clockwise in FIG. 6 about the shaft 14 and pressed against the cam 64.

  A gripping portion 65 shown in FIG. 2 is a portion that is gripped and operated by an operator. By operating the gripping portion 65, the cam 64 rotates through the rotation shaft 63. As shown in FIG. 6, the cam 64 has a first contact surface 64a and a second contact surface 64b. The cam 64 has a first position indicated by a solid line in the drawing where the first contact surface 64a contacts the upper surface 66a of the head base 66, and a second position indicated by a two-dot chain line in the drawing where the second contact surface 64b contacts the upper surface 66a. Rotate between. The position of the pressure head 16 when the cam 64 is in the first position is referred to as a retracted position, and the position of the pressure head 16 when the cam 64 is in the second position is referred to as an air supply position. The rotation of the cam 64 causes the pressure head 16 to swing about the shaft 14. When the pressure head 16 moves to the air supply position, the air nozzles 15A to 15H come into close contact with the extraction cartridge 2, and when the pressure head 16 moves to the retreat position, the air nozzles 15A to 15H move away from the extraction cartridge 2. It becomes.

  Below, each part of an air supply unit is demonstrated in detail. The air supply unit 30A will be described as a representative of the air supply units 30A to 30H, but the other air supply units 30B to 30H have the same configuration. However, as will be described later, the phases of the air pumps 31A to 31H are different.

  The air pump 31 </ b> A includes a cylinder 33, a piston 34 that slides inside the cylinder 33, a rod 35 that holds the piston 34, a rod holding portion 36 that holds the rod 35, and an eccentric cam attached to the shaft 14. 37.

  An intake port 33 a is formed in the upper portion of the cylinder 33, and new air is supplied into the cylinder 33 from the intake port 33 a. A piston packing 38 is attached to the piston 34. The rod holding portion 36 has a substrate 36a along the XZ plane, and a guide portion 36b that is an opening extending in the X-axis direction is formed on the substrate 36a. The shaft portion 37a of the eccentric cam 37 is engaged with the guide portion 36b. The shaft portion 37a slightly protrudes from the end surface of the eccentric cam 37 in the Y-axis direction, and the protruding portion is engaged with the guide portion 36b. A regular octagonal through hole 37b is formed in the shaft portion 37a. Further, a cylindrical portion 36c having an elliptical cross section extending in the Y-axis direction is formed on the substrate 36a, and the cam surface of the eccentric cam 37 is in contact with the inner surface of the cylindrical portion 36c. When the eccentric cam 37 rotates through the shaft 14, the piston 34 reciprocates in the X-axis direction. Although the pressure of the pressurized air produced | generated by an air pump is not specifically limited, Preferably it exists in the range of 80 kPa-200 kPa, More preferably, it exists in the range of 120 kPa-180 kPa.

  The check valve 32A is attached to the front surface of the cylinder 33. The check valve 32 </ b> A includes a ball 39 and a compression spring 40 that presses and closes the ball 39 against the air outlet 33 b of the cylinder 33. An O-ring is attached to a contact area where the ball 39 contacts. The check valve 32A can prevent backflow of pressurized air.

  At the front portion of the check valve 32A, a columnar first protrusion 41 protruding in the Z-axis plus direction and a prismatic second protrusion 42 protruding in the X-axis plus direction are formed. A first guide hole 43 penetrating in the Z-axis direction is formed on the upper surface of the head base portion 66. The first guide hole 43 has a width in the Y-axis direction that is substantially the same as the diameter of the first protrusion 41, and X The width in the direction is larger than the diameter of the first protrusion 41. Further, the front plate 46 fixed to the front portion of the head base 66 is formed with a second guide hole 44 penetrating in the X-axis direction, and the second guide hole 44 has a second width in the Y-axis direction. The width in the Z-axis direction is substantially the same as the width of the protrusion 42 and is larger than the width of the second protrusion 42.

  When the air supply unit 30 </ b> A is assembled to the head base 66, the first protrusion 41 is inserted into the first guide hole 43 and the second protrusion 42 is inserted into the second guide hole 44. A coil spring 45 is wound around the first protrusion 41, and the upper end of the coil spring 45 is fixed to the inner surface of the head base 66, and the lower end of the coil spring 45 is fixed to the upper surface of the check valve 32A. The air supply unit 30 </ b> A is urged downward with respect to the head base 66 and can be slightly moved with respect to the head base 66.

  An air nozzle 15A is attached to the lower surface of the check valve 32A. The air nozzle 15A is formed in a cylindrical shape. A groove 50 is formed on the outer peripheral surface of the air nozzle 15A so as to have a depth in the radial direction. An O-ring 51 is fitted in the groove 50. As the groove 50 becomes deeper, the groove width (width in the Z-axis direction) increases. Thereby, since the force which goes to a diameter inward acts on the O-ring 51 at the time of pressurization, the sealing property of the O-ring 51 can be kept high. The lower end of the air nozzle 15A is formed so that the outer diameter of the lower end is substantially the same as the inner diameter of the extraction cartridge 2, and the corners are chamfered.

  The pressurized air generated by the air pump 31A passes through the space 89 in the cylinder 33, the space 90 of the check valve 32A, the pipe 91 of the check valve 32A, and the pipe 92 of the air nozzle 15A in order. Supplied from the mouth to the outside. The air flow path is configured by the space 89, the space 90, the pipe 91, and the pipe 92.

  A groove is formed on the upper surface of the air nozzle 15A, and the resistance filter 93 is fitted into the groove, so that the resistance filter 93 is disposed in the duct 92 of the air nozzle 15A. In the resistance filter 93, when the pressure suddenly decreases downstream of the resistance filter 93, the pressurized air remaining upstream of the resistance filter 93 is rapidly sent to the air nozzle 15A. To be prevented. A large number of minute holes are formed in the resistance filter 93. The hole diameter of these holes is preferably 0.22 μm or less. The resistance filter is preferably a biofilter or a PTFE (polytetrafluoroethylene) filter, but is not limited thereto.

  Hereinafter, the phase difference of the air pump (phase difference of the eccentric cam) will be described. When setting the phase of the air pump, the phase of the air pump is dispersed at a predetermined angle (in this embodiment, set to “360 degrees / number of air pumps”), and the positions of the air pumps adjacent in the column direction are dispersed. The setting is performed so that the phase difference is an integral multiple of 2 or more of the predetermined angle, that is, an integral multiple of 2 or more of “360 degrees / the number of air pumps”.

  In the eight air pumps 31A to 31H shown in FIG. 5, the phase of the air pump is dispersed in increments of 45 degrees, and the phase difference between adjacent air pumps is three times 45 degrees, that is, 135 degrees. Set the phase of the air pump. As shown in FIG. 6, the eccentric cam 37 can be assembled by fitting the shaft portion 37 a of the eccentric cam 37 to the shaft 14. At this time, the posture of each eccentric cam 37 around the Y axis is changed. Thus, the phases of the air pumps 31A to 31H can be shifted by 45 degrees.

    As shown in FIG. 7, when the phase of each air pump is dispersed in increments of 45 degrees, the phase of each air pump is 0 degree, 45 degrees, 90 degrees, 135 degrees, 180 degrees, 225 degrees, 270 degrees, 315, respectively. Degree. The air pump 31A is set to 0 degrees as a reference, and the air pumps arranged on the Y axis plus side are sequentially set so that the phase of the air pump advances by 135 degrees. Below, it demonstrates using the expression form of "air pump [phase]". When the air pump 31A is [0 degrees], the air pump 31B [135 degrees], the air pump 31C [270 degrees], the air pump 31D [45 degrees], the air pump 31E [180 degrees], the air pump 31F [315 degrees], and the air pump 31G [90 degrees]. ], Air pump 31H [225 degrees]. Here, in the phase of the air pump, 360 degrees and 0 degrees have the same meaning. Therefore, when 360 degrees (one round) is exceeded during the calculation, the calculation is performed by subtracting 360 degrees from the calculated value. continue. FIG. 8 is a cross-sectional view of the main part of the air pump 31B, and the phase of the eccentric cam of the air pump 31B indicated by the solid line in the drawing is advanced by 135 degrees with respect to the eccentric cam of the air pump 31A indicated by the two-dot chain line in the drawing. Counterclockwise is positive).

  By setting the phases of the air pumps 31A to 31H as described above, even if only a part of the extraction cartridge 2 is set (generally, the extraction cartridge 2 is set in order from the Y axis minus side) The load applied to the motor 82 that rotates the common shaft 14 is distributed over time. For example, when three extraction cartridges 2 are set in order from the Y-axis minus side, the air pumps 31A to 31C are loaded, while the air pumps 31D to 31H are hardly loaded. However, even when a load is applied only to some of the continuous air pumps 31A to 31C, the phases of the air pumps 31A to 31C to which the load is applied are appropriately distributed (when the air pump 31A is used as a reference). The air pump 31B advances 135 degrees, and the air pump 31C advances 270 degrees), and the load applied to the motor 82 is dispersed in time.

  FIG. 9 is a block diagram showing an electrical configuration of the pressurizing device 10, and the pressurizing device 10 is provided with a system control unit 80. A position sensor (detector) 81, a motor 82, and a timer 83 are connected to the system control unit 80, and the system control unit 80 controls each unit.

  The position sensor 81 outputs an ON signal when the pressure head 16 is at the air supply position, and outputs an OFF signal when it is at the retracted position. The position sensor 81 is, for example, a limit switch, and this limit switch contacts the pressure head 16 and outputs an ON signal as the pressure head 16 moves to the air supply position. The system control unit 80 monitors the output signal of the position sensor 81. When the output signal is switched to the on signal, the system controller 80 starts driving the motor 82 and starts measuring time by the timer 83. The system control unit 80 stops the driving of the motor 82 when the time measured by the timer 83 exceeds the set time. This set time is set in consideration of the time required for the pressurizing process. This set time is preferably configured to be changeable based on the type and amount of liquid to be injected into the extraction cartridge 2.

    A power source 84 is connected to the pressure device 10. The power supply 84 supplies power to the motor 82 and the system control unit 80. For example, an AC adapter is used as the power source 84. The power source may be a commercially available battery or a car battery.

  Hereinafter, the operation of the above configuration will be described along the flow of the flowchart of FIG. As shown in FIG. 2, the cartridge holder 19 holding the plurality of extraction cartridges 2 is attached to the first attachment position of the container holder 20 holding the plurality of waste liquid containers 3 and the collection containers 4. The discharge part 2c of each extraction cartridge 2 is inserted into each waste liquid container 3. Thereafter, the sample solution S containing the nucleic acid is manually injected into each extraction cartridge 2.

  The rack 18 is placed on the placement tray 12, the rack 18 is slid in the X-axis minus direction, and the rack 18 is stopped when the abutting surface 27 abuts against the abutting block 26. The pressure device 10 can be attached. The pressure head 16 is in the retracted position, and each extraction cartridge 2 is located directly below the air nozzles 15A to 15H.

  When the gripping portion 65 is gripped and rotated, this operating force is transmitted to the pressure head 16 via the rotating shaft 63 and the cam 64, and the pressure head 16 moves to the air supply position as shown in FIG. . The air supply units 30A to 30H are individually rotatable around the shaft 14, and the front part is biased downward by the coil spring 45. Therefore, the air nozzles 15A to 15H are extracted by an appropriate force. 2 and the extraction cartridge 2 are airtightly closed.

  When the pressure head 16 moves to the air supply position, the position sensor 81 detects this, and the motor 82 starts driving. When the motor 82 is driven, the shaft 14 rotates and the air pumps 31A to 31H are individually driven to generate pressurized air. The generated pressurized air passes through the space 90 and the pipe line 91 of the check valves 32A to 32H, the resistance filter 93, the pipe line 92 of the air nozzles 15A to 15H, and the corresponding extraction cartridge 2 respectively. Supplied at the same time. The sample solution S passes through the filter 2a, and the nucleic acid is adsorbed on the filter 2a. Other liquid components are discharged into the waste liquid container 3.

  When the set time has passed, the motor 82 stops driving, and the supply of pressurized air by the air pumps 31A to 31H is stopped. If the filter 2a is clogged and the sample liquid S remains in the extraction cartridge 2, the gripping section 65 is rotated to move the pressure head 16 to the retracted position and then the pressure head 16 again. Needs to be moved to the air supply position to supply pressurized air.

  The case where the sample liquid S remains in the extraction cartridge 2 corresponding to the air supply unit 30A will be described as an example. The air nozzle 15 </ b> A is in close contact with the extraction cartridge 2, and the pressurized air remains in the space 89, the space 90, the conduit 91, the conduit 92, and the extraction cartridge 2. When the pressure head 16 starts to move to the retracted position, the air nozzle 15A moves away from the extraction cartridge 2, and the pressurized air remaining in the conduit 92 and the extraction cartridge 2 blows out. At this time, since the pressure in the pipe line 92 rapidly decreases, the pressurized air remaining in the space 89, the space 90, and the pipe line 91 tends to flow into the pipe line 92 with a rapid force. Since the air passes through the filter 93, the flow rate of the pressurized air is suppressed. For this reason, the pressurized air is not blown against the liquid surface of the sample liquid S of the extraction cartridge 2 with a strong force, and the sample liquid S is not scattered. After the pressure head 16 has been moved to the retracted position, it is again moved to the air supply position, and the air nozzle 15A is brought into close contact with the extraction cartridge 2 in which the sample liquid S remains to supply pressurized air.

  When it can be visually confirmed that the sample liquid S has been discharged from all the extraction cartridges 2, the gripping portion 65 is rotated to move the pressure head 16 to the retracted position.

  Next, after the rack 18 is taken out and the cleaning liquid W is injected into each extraction cartridge 2, the rack 18 is attached to the pressure device 10. The pressurizing process for the cleaning liquid W is performed in the same manner as the pressurizing process for the sample liquid S. The cleaning liquid W that has passed through the filter 2a is discharged into the waste liquid container 3 together with impurities other than nucleic acids.

  Thereafter, the rack 18 is taken out, and the cartridge holder 19 is attached to the second attachment position of the container holder 20. The ejection part 2c of each extraction cartridge 2 is inserted into each collection container 4. When this rack 18 is attached to the pressurizing device 10, each extraction cartridge 2 is positioned directly below the air nozzles 15A to 15H. The pressurizing process for the recovered liquid R is performed in the same manner as the pressurizing process for the sample liquid S. The recovery liquid R passes through the filter 2a and is stored in the recovery container 4 together with the nucleic acid adsorbed on the filter 2a. The gripping section 65 is rotated to move the pressure head 16 to the retracted position, the rack 18 is taken out, and all nucleic acid extraction processes are completed.

  According to the pressurizing apparatus 10, since the plurality of extraction cartridges 2 can be processed simultaneously, the pressurizing and extracting process can be completed in a short time. Moreover, since the structure of the pressurization apparatus 10 is very simple, the pressurization apparatus 10 can be provided at low cost.

  In the above embodiment, there are eight air nozzles held by the pressure head and eight air pumps, but these numbers may be arbitrary. Although the above embodiment has been described using a piston-type air pump, other air pumps such as a bellows pump may be used.

  In the above embodiment, the container holder of the rack is provided with a slit so that the capacity of the waste liquid container can be confirmed. Instead of this configuration, or in addition to this configuration, the rack mounted on the pressurizer main body. Alternatively, a light source may be arranged at the rear, and the container holder and the waste liquid container may be illuminated by this light source. In this case, the container holder and the waste liquid container are formed of a transparent resin.

  In the above embodiment, the air nozzle moves with respect to the fixed extraction cartridge. However, the extraction cartridge may move with respect to the fixed air nozzle.

  In the embodiment described above, the cleaning process using the cleaning liquid is performed, but this is not necessarily required depending on the permeation ability of the filter member. In the above embodiment, the recovery operation is performed using the recovery liquid. However, for example, when the analysis is performed with the specific substance adsorbed on the filter member, the recovery liquid is not necessarily required.

  Although the pressurization apparatus used for extracting nucleic acid is described in the above embodiment, the pressurization apparatus is not limited to this, and the pressurization apparatus can be used also when extracting various specific substances. .

  In the above embodiment, the resistance filter is arranged in the air nozzle line, but the resistance filter may be arranged in the cylinder of the air pump. For example, as shown in FIG. 12, the resistance filter 100 is disposed so as to cover the air outlet 33b of the air pump 31A. Further, a resistance filter may be arranged in the pipe line of the check valve. In the above embodiment, the resistance filter is used as the air flow path resistance means, but an orifice may be used instead.

  A damper for slowing the moving speed of the pressure head may be provided instead of or in addition to the air flow path resistance means of the above embodiment. As shown in FIG. 13, there is provided a damper 101 having a lower end 101a attached to the head base 66 of the pressure head 16 and an upper end 101b attached to the side plate 13 (see FIG. 2). Since the moving speed of the pressurizing head 16 is suppressed and the pressure in the extraction cartridge 2 gradually decreases, the pressurized air does not blow out vigorously and the sample liquid does not scatter. In addition to or in addition to this damper, when the shape of the cam constituting the head displacement mechanism is changed and the pressure head is displaced from the air supply position to the retracted position, the amount of displacement at the initial stage of the displacement is small. You may comprise so that it may become.

  Instead of or in addition to the air flow path resistance means of the above embodiment, the shape of the air nozzle pipe may be changed so that the pressurized air does not blow out vigorously. As shown in FIG. 14, the diameter of the conduit 103 of the air nozzle 102 increases toward the air supply port 104. Thereby, the flow rate of the pressurized air is suppressed. As shown in FIG. 15, a protrusion 106 is provided at the tip of the air nozzle 105, and an air supply port 107 is formed on a side surface of the protrusion 106. The lower end portion of the duct 108 of the air nozzle 105 extends parallel to the liquid surface of the sample liquid S. Thereby, the pressurized air is not directly blown against the liquid surface of the sample liquid, and the flow rate of the pressurized air is suppressed.

  Instead of the air nozzle used in the above embodiment, an air nozzle 300 shown in FIG. 12 may be used. The air nozzle 300 is detachable from a nozzle holding unit 301 attached to the front surface of the air pump 31A. The nozzle holding part 301 has an air flow path 301 a for sending the pressurized air generated by the air pump 31 </ b> A to the air nozzle 300. The nozzle holding portion 301 is provided with a first protrusion 302 and a second protrusion 303 corresponding to the first protrusion 41 and the second protrusion 42 of the above embodiment.

  The air nozzle 300 includes a nozzle body 304 and a contact portion 305 attached to the lower surface of the nozzle body 304. A spacer is provided in a partial region of the upper surface of the nozzle body 304, and the pressurized air flows into the air flow path 304a of the nozzle body 304 through the spacer. An air flow path 305 a is formed in the contact portion 305.

  A check valve 306 is disposed in the air flow path 304a. The check valve 306 is provided in place of the check valve 32A of the above embodiment, and plays the same role as the check valve 32A. The check valve 306 is made of rubber and is detachable. A resistance filter 307 is disposed across the air flow path 304a and the air flow path 305a. The resistance filter 307 has a large number of minute holes, and the hole diameter is preferably 0.22 μm or less. The resistance filter 307 is preferably a biofilter, but other filters such as those made of PTFE (polytetrafluoroethylene) may be used as long as the flow rate of pressurized air can be suppressed. . In the resistance filter 307, when the pressure suddenly decreases downstream from the resistance filter 307, the pressurized air remaining upstream from the resistance filter 307 blows out from the air nozzle 300 with rapid force. It plays the role which prevents that, prevents the liquid in an extraction cartridge from scattering, and prevents contamination.

  The contact portion 305 is formed in a substantially cylindrical shape, and a groove 305b is formed on the lower surface. The groove 305b is formed in a size that allows the upper part of the extraction cartridge to enter. An O-ring 308 that contacts the upper surface of the extraction cartridge is attached to the back of the groove 305b.

  The air nozzle 300 is provided with a rubber anti-slip ring 309. When the air nozzle 300 is inserted into the holding groove 301 b of the nozzle holding portion 301, the air nozzle 300 is held by the nozzle holding portion 301 by the action of the anti-slip ring 309.

  By changing the volume upstream of the check valve 306 in the air flow path 304a of the nozzle body 304, the pressure of the pressurized air can be changed. When the volume is reduced, the pressure of the pressurized air increases. When the volume is increased, the pressure of the pressurized air decreases. By simply replacing the air nozzle 300 with another one, the pressure of the pressurized air can be changed without replacing the air pump 31A. In addition, since the air nozzle 300 can be replaced, it is easy to replace the check valve 306 and the resistance filter 307 with new ones.

Note that the pressure of the pressurized air may be changed by changing the position of the air nozzle 300 relative to the nozzle holder 301 without replacing the air nozzle 300 with another one. In this case, it is preferable to use a non-slip ring having a high anti-slip effect, or a configuration in which the position of the air nozzle 300 relative to the nozzle holding portion 301 can be changed in several stages.

It is explanatory drawing which shows a nucleic acid extraction operation | movement in order. It is an external appearance perspective view of a pressurizing device and a rack. It is an external appearance perspective view of a cartridge. It is a disassembled perspective view of a rack. It is an external appearance perspective view of an air supply unit. It is sectional drawing of a pressurization head when cut | disconnecting by a XZ plane. It is explanatory drawing explaining the phase difference of an air pump. It is principal part sectional drawing of the air pump which the phase has advanced 135 degrees. It is a block diagram which shows the electrical structure of a pressurization apparatus. It is a flowchart which shows the flow of nucleic acid extraction operation | movement. It is sectional drawing of the pressurization head which moved to the air supply position. It is principal part sectional drawing of the air supply unit which shows embodiment which has arrange | positioned the filter for resistance in the cylinder of the air pump. It is a schematic block diagram of the head displacement mechanism which shows embodiment which attached the damper to the pressurization head. It is sectional drawing of the air nozzle which shows the 1st modification of the pipe line of an air nozzle. It is sectional drawing of the air nozzle which shows the 2nd modification of the pipe line of an air nozzle. It is sectional drawing of the air nozzle provided with the check valve and the filter for resistance.

Explanation of symbols

S Sample liquid W Cleaning liquid R Collected liquid 2 Cartridge 2a Filter 10 Pressure device 14 Shaft 15A-15H, 300 Air nozzle 16 Pressure head 17 Head displacement mechanism 18 Rack 19 Cartridge holder 20 Container holder 30A-30H Air supply unit 31A-31H Air pump 37 Eccentric cam 37b Fitting part 93, 307 Resistance filter

Claims (7)

In the pressurizing device of the extraction cartridge that supplies pressurized air to the extraction cartridge that adheres the specific substance contained in the liquid injected from the inlet to the filter member,
An air nozzle for supplying pressurized air in close contact with the inlet of the extraction cartridge;
Displacement means for relatively displacing the air nozzle and the extraction cartridge so that the air nozzle is in close contact with the inlet of the extraction cartridge and in a retracted state away from the inlet of the extraction cartridge;
An air pump for generating pressurized air;
An air flow path for sending pressurized air of the air pump to the air nozzle;
An extraction cartridge pressurizing device comprising: an air flow path resistance means provided in the air flow path for suppressing the flow rate of the pressurized air. The displacement means includes a pressure head that holds the air nozzle;
The head displacement mechanism for displacing the pressure head between an air supply position where the air nozzle is in the close contact state and a retreat position where the air nozzle is in the retracted state. Pressurization device for the extraction cartridge.   3. The extraction according to claim 2, wherein the head displacement mechanism includes a cam that selectively positions the pressure head at the air supply position or the retracted position, and an operation unit that rotates the cam. Pressure device for cartridge.   The pressurizing device for an extraction cartridge according to any one of claims 1 to 3, wherein the air flow path resistance means is provided in an air flow path of the air nozzle.   5. The pressurizing device for an extraction cartridge according to claim 1, wherein the air flow path resistance means is a resistance filter member.   The pressurizing device for an extraction cartridge according to claim 5, wherein the resistance filter is a biofilter and has a large number of minute holes.   7. The pressurization device for an extraction cartridge according to claim 1, wherein the liquid containing the specific substance is a sample liquid containing nucleic acid.

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