JPH0151777B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a liquid chromatography separation method.

The present invention uses a tube that repeatedly bends the flow of liquid when it passes through the tube, applies centrifugal force to the tube, introduces a liquid containing multiple components with different sedimentation coefficients or flotation coefficients into the tube, and The present invention provides a method for performing liquid chromatography in which a liquid is separated in terms of its components in the longitudinal direction of a tube by the force of the liquid flow inside the tube and the centrifugal force applied to the tube.

In the method of the invention, a rotating tube and an external stationary system are communicated through a liquid tube to obtain centrifugal force. In that case, the liquid tube does not twist, and liquid is introduced into the rotating tube from the stationary system and discharged from the rotating tube into the external stationary system.

Conventionally, methods that utilize the partition coefficient of a substance between two liquid phases, such as paper chromatography and column chromatography, have been used. A stationary phase was adsorbed onto a solid, and a mobile phase was flowed through the stationary phase in a manner that facilitated contact with the stationary phase to develop or elute the sample. For this reason, these methods require solid adsorbents that are not directly involved in separation. On the other hand, there are no papers, silica gels, etc. that have uniform adsorption power, and some substances are irreversibly adsorbed or altered by solid adsorbents.

Conventionally, countercurrent distribution methods have been used in that solid adsorbents are not introduced into the system, but in principle, this method introduces two liquid phases with different specific gravities in a gravitational field. Separation was performed based on the distribution coefficient of each liquid phase of the substance. For this reason, a pipe in which a number of specially shaped separation funnels were connected was required as a countercurrent distribution pipe.

In the method of the present invention, we focus on the fact that the sedimentation coefficient or flotation coefficient of a substance varies depending on the particle size, Reynolds number, and specific gravity of the substance. Direct separation in the longitudinal direction of the tube is achieved by differences in sedimentation coefficients or flotation coefficients.

By the way, when connecting a stationary pipeline to a rotating centrifugal processing chamber, there is a method that uses a mechanical sliding member at the connecting portion. However, mechanical sliding members inevitably suffer from wear and tear.
This is accompanied by problems such as heat generation. Therefore, a U.S. patent for a device for centrifugally processing liquid by maintaining continuous liquid communication between a stationary pipeline and a rotating centrifugal processing chamber without using mechanical sliding members was patented. It is disclosed in the specification of No. 4113173. The U.S. patent describes an apparatus for centrifugally processing liquid, in which a rotating body including a centrifugal processing chamber and a turntable for rotating a liquid tube are rotated in the same direction at a speed ratio of 2:1 to prevent the liquid tube from twisting. This is a device that allows you to In that device, the rotation speed of the liquid tube is 1/2 of the rotation speed of the liquid treatment chamber.
To this extent, the degree of freedom in structural design was not necessarily large.

The method of the present invention provides a liquid chromatography separation method that solves the above problems.

In the method of the present invention, a tube is rotatably supported around a predetermined axis, and one end of a flexible liquid tube is connected to the tube along the axis of rotation. a first intermediate portion of the liquid tube is extended to a second intermediate portion, bypassing a rotatable region of the tube so as not to touch the tube; The _second intermediate portion is rotatable along the rotational axis on the side opposite to the coupled side and extended to a third intermediate portion. The middle part extends to the other end by detouring the rotatable area of the first middle part so as not to touch the first middle part, and the third middle part rotates around the rotational axis at a rotational speed. w ₂ and the other end is coupled to a stationary system on the same side along the axis of rotation as the coupled side, and the tube is rotated at a rotation speed of 2 (w ₁ −
w ₂ ), a liquid containing particles having different sedimentation coefficients or flotation coefficients is continuously introduced into the tube, and the liquid is separated in the longitudinal direction of the tube in terms of particle components. This is a characteristic liquid chromatography separation method.

"A tube that repeatedly bends the flow of fluid when it passes through it" refers to a tube in which a fluid containing multiple particles with different sedimentation coefficients or levitation coefficients is passed through the tube at a predetermined flow rate and placed in a predetermined centrifugal field. , a tube having sufficient bends and a sufficient number of repetitions thereof to substantially separate each component by a difference in sedimentation coefficient or flotation coefficient of each particle. Examples of such tubes include conventionally known small counterflow distribution pipes with multiple stages, coiled polyethylene tubes, coiled glass tubes, zigzag shaped metal tubes,
Zigzag-shaped vinyl chloride pipes, pipes filled with polyester flocculent, pipes filled with carbon fiber flocculent, tubes filled with ceramic continuous porous body,
Various types of tubes can be used, such as a tube filled with a continuous porous urethane foam, a tube filled with glass beads, a tube filled with Teflon beads, or a combination thereof. These flocculent bodies, open porous bodies, solid beads, etc. are not essentially carriers for conventional partition chromatography, but are used to repeatedly bend the flow of liquid, and various arrangements are possible. However, as tubes that do not introduce solids into the system and have a simple shape, coiled tubes or zigzag tubes are excellent. It goes without saying that the cross-sections of these tubes need not be circular. The zigzag tube can be flat and occupy substantially less space than the coiled tube.
In addition, the coiled tube can also be made into a flat spiral shape so that it occupies substantially less space. If the diameter of the coiled tube or zigzag tube is d, and the diameter of the spiral drawn by the coiled tube or the width of the zigzag drawn by the zigzag tube is D, then the effect of repeatedly bending the liquid flow can be increased. It is desirable that d<D.

The tube is supported for rotation about a predetermined axis. A flexible liquid tube is provided in the above-described manner, and includes the first middle portion and the third middle portion.
The middle part of the pipe and the pipe are respectively w ₁ :w ₂ :2
When rotated at (w ₁ −w ₂ ), the rotating tube communicates with an external stationary system through a liquid tube, which does not twist. The basic principle behind this is that U.S. Pat.
It is explained in Publication No. 4230263 and the like.

In the present invention, a liquid containing particles with different sedimentation coefficients or levitation coefficients is introduced as a fluid into a tube that is being rotated by an external stationary system, and the force of the liquid flow inside the tube and the centrifugal force that is applied to the tube. The tubes are separated in the longitudinal direction by "Liquid flow force" refers to the force applied to particles existing in the field of liquid flow, and is based on the Stokes equation of fluid mechanics (when the Reynolds number Re < 2 for ultrafine particles) or Allen's equation. It is a force that can be approximated by the equation (when 2<Re<500), the Yuutren equation (when 500<Re), etc. Particles with a large sedimentation coefficient are subject to centrifugal force immediately after being introduced into a tube, and therefore it is difficult for them to repeatedly bend and flow, and particles with a small sedimentation coefficient are subject to centrifugal force immediately after being introduced into a tube. Since it is easy to bend and flow, it can easily pass through the tube in the longitudinal direction.

In the present invention, when at least two liquid tubes are used as the liquid tubes, the liquid is introduced into the rotating tube from a stationary system through at least one liquid tube, and then through at least one other liquid tube. , it is possible to drain liquid from a rotating tube into a stationary system.

In the present invention, the liquid tube that communicates the stationary system with the rotating tube does not have a rotating sliding member. Therefore, frictional heat is not generated, bacteria are not mixed in, and the system can be maintained in an oxygen-free state without damaging the liquid. For this purpose, the method of the present invention can be applied to components of biological fluids such as suspensions of organic compounds such as sugars, lipids, and amino acids, in particular serum, urine, suspensions of blood cells, bacteria, and cancer cells. It is suitable for separating.

In the present invention, since there is essentially no adsorbent in the system, the sample can be almost completely recovered. Furthermore, compared to conventional partition chromatography using carriers, in the present invention, only the liquid is present in the system other than structures such as tubes and pipelines that repeatedly bend the flow of the liquid. Therefore, it is extremely easy to reproduce the separation conditions and cleaning is also easy. In particular, suspensions of blood cells, bacteria, cancer cells, etc. can be separated without damaging their viability, physiological functions, etc.

Next, an apparatus for carrying out the method of the present invention will be explained using the drawings.

FIG. 1 is a front view showing an example of the device of the present invention, with a portion removed to make the interior easier to see.

FIG. 2 is a perspective view of the main parts of the apparatus shown in FIG. 1, with some parts removed to make the interior easier to see. Elements corresponding to those in FIG. 1 are designated with the same numbers.

In the apparatus shown in FIG. 1 or 2, fluid communication is performed between a rotating body 2 including a coiled vinyl chloride pipe 1 and a stationary system, and the rotating body 2 is connected to a rotation axis A.
- The flexible liquid tube 3 is rotatably supported around A, and one end of the flexible liquid tube 3 is coupled to the rotating body 2 along the rotational axis A-A, with the first intermediate portion 4 not touching the rotating body 2. The rotatable region of the rotating body 2 is detoured and extended to the second intermediate portion 5, and the first intermediate portion 4 is rotated around the rotational axis A-A at a rotation speed w ₁
The second intermediate portion 5 is rotatably supported along the axis of rotation A-A on the opposite side of the connection and extended to the third intermediate portion 6;
The third intermediate portion 6 detours the rotatable region of the first intermediate portion 4 so as not to touch the first intermediate portion 4 and extends to the other end 7.
is rotated at a rotational speed w ₂ around the axis of rotation A-A, and the other end 7 is connected to a stationary system along the axis of rotation A-A on the same side as said connected, so that the liquid tube 3 is not twisted. This device rotates the rotating body 2 at a rotational speed of 2 (w ₁ -w ₂ ) by applying an external force to the rotating body using a rotational force transmission means.

That is, the rotating body 2 is the first turntable 8
The first turntable 8 is rotatably supported relative to the second turntable 9 . first turntable 8
connects the first intermediate portion 4 of the liquid tube 3 to the second
The turntables 9 are for rotating the third intermediate portions 6 of the liquid tube 3 around the rotational axis A-A. The second turntable 9 is rotatably supported on a stationary table and connected to the shaft of a motor 10. A stationary pulley 11 is fixed to the stationary table, and a rotating pulley 13 revolves around the axis A-A with the shaft 12 rotatably held by the second turntable 9.
is rotated by the timing belt 14 together with the rotation of the second turntable 9, and the other rotary pulley 15 sharing the shaft 12 is also rotated. A pulley 16 fixed to the shaft of the first turntable 8 is rotated by a timing belt 17 as the rotary pulley 15 rotates. The ratio of the diameters of pulley 11 and pulley 13 is, for example,
2:1, the ratio of the diameters of the pulley 15 and the pulley 16 is, for example, 1:1, and the timing belt 1
4 and 17 are hung in a wedge shape as shown in the figure, and at this time, the first turntable 8 rotates at the same rotation speed as the second turntable 9 and in the opposite direction, that is, w ₁ /w ₂ = -1 rotation. Rotated by a number ratio. As an alternative to the pulley 11 and the pulley 13 and the pulley 15 and the pulley 16, a combination of gears may be used. A gear 18 is fixed to the second turntable 9 around the rotational axis A-A, and a rotating gear 20 is rotatably held by the first turntable 8 and revolves around the axis A-A. rotates along with the rotation of the first turntable 8, and the rotating pulley 21 sharing the shaft 19 is also rotated. A pulley 22 fixed to the shaft of the rotary body 2 is rotated by a timing belt 23 as the rotary pulley 21 rotates. The ratio of the number of teeth between the gear 18 and the gear 20 is, for example, 3:1, the ratio of the diameters of the pulley 21 and the pulley 22 is, for example, 1:2, and the timing belt 23 is, for example, wrapped in a wedge shape as shown in the figure. w ₁ =-1,
When w ₂ = 1, the rotation speed w ₃ of the rotating body 2 is w ₃ = 2
It is rotated by (w ₁ −w ₂ )=−4.

In order to achieve the above rotational speed ratio, the ratio of the number of teeth of gear 18 and gear 20 is set to 3:2, for example, and the ratio of the diameters of pulley 21 and pulley 22 is set to 1:1.
Alternatively, instead of gears, a pulley with a belt wrapped around it may be used. To explain the operation of this rotation transmission, when the gear 18 rotates at w and the gear 20, which is 2/3 of the gear, revolves at -w, the gear 20 rotates at -4w. When the pulley 21 rotates at -4w and revolves around the pulley 22 having the same diameter at -w, the pulley 22 rotates at -4w.

The mutual rotational relationship of the above series of rotation transmission operations will be explained using an example.

The pulley 11 is stationary, and when the pulley 13 with a diameter of 1/2 is revolved at w, the pulley 13 is rotated at -w. When the pulley 15 rotates at -w while revolving at w, the pulley 16 rotates at -w. Gear 18 rotates at W and has 1/3 teeth.
When the gear 20 revolves at -w, the gear 20 rotates at -7w. Pulley 21 rotates at -7w and moves around pulley 22, which is twice the diameter, at -w.
When the pulley 22 is rotated at -4w, the pulley 22 is rotated at -4w.

In the apparatus of the present invention, w ₁ and w ₂ are preferably rotated at a rotational speed ratio of −2.4≦w ₁ /w ₂ ≦−0.4 (the negative sign represents rotation in opposite directions). More preferably, the range is −1.6≦w ₁ /w ₂ ≦−0.6, and even more preferably, the range is −1.2<w ₁ /w ₂ ≦−0.8.

w ₁ /w ₂ =-1, that is, |w ₃ /w ₁ |=|w ₃ /
When w ₂ |=4, when the first intermediate portion 4 and the second intermediate portion 6 described above are rotated in opposite directions at, for example, 500 rpm, the rotating body 2 is
This means that it rotates at 2000rpm.

In this way, the components are separated in the coiled vinyl chloride pipe 1. Fluid is introduced into the rotating tube 1 from an external stationary system through the small diameter tube 24, and is discharged from the tube 1 into the external stationary system through the small diameter tube 25. These small diameter tubes 24, 25 are inserted into the fluid tube 3. The tube 1 and the flexible fluid tube 3, including the small diameter tubes 24, 25, can be provided as replaceable or disposable components.

Although the drawings show an embodiment of the apparatus for carrying out the method of the present invention, it is easy to modify these in accordance with the idea of the present invention.

[Brief explanation of drawings]

FIG. 1 is a front view showing an example of an apparatus for carrying out the method of the present invention. FIG. 2 is a perspective view of the main parts of the apparatus shown in FIG. 1. 1... Coiled tube, 2... Rotating body, 3... Fluid tube, 24, 25... Small diameter tube.

[Claims]

1. A solvent degasser for liquid chromatography comprising a solvent storage vessel partially filled with solvent and the remaining volume consisting of a vapor volume, with a helium source connected to said vapor volume and a suction line connected to said vapor volume. A solvent degassing apparatus for a liquid chromatograph, comprising: a vacuum pump connected to the vapor volume; a solvent source connected to the vapor volume by a supply line; and a filter terminating the feed line within the vapor volume. 2. The solvent degassing device for liquid chromatography according to claim 1, characterized in that the helium source is continuously connected to the vapor volume via a flow resistance. 3. The solvent degassing device for liquid chromatography according to claim 1, characterized in that the vapor volume is provided with a vent hole. 4. The solvent degassing apparatus for liquid chromatography according to claim 1 is characterized in that a liquid trap is installed between the vapor volume and the vacuum pump.

Claims (1)

2. The method according to claim 1, wherein the liquid is a biological liquid such as a suspension of an organic compound such as a serum, urine, a suspension of blood cells, a suspension of bacteria, a cancer cell, etc.