DE2426908A1 - CENTRIFUGAL PARTICLE ELUTRATION DEVICE AND METHOD OF USING IT - Google Patents

Description

United States Atomic Energy Commission, Washington, D.C. 20545, UNITED STATES.

Centrifugal Particle Elution Apparatus and Method of Use.

The invention relates generally to elution. In many areas of technology, the elution is used as a
Means for separating particles with equal densities, but
different effective diameters are used. The method is generally based on an application of Stokes' law relating to sedimentation. The method is applied to particles smaller than about 100 microns. If the particle sizes are below approximately

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40 microns, the centrifugal force became acceleration used during the weaning process.

In the field of blood separation, centrifugation in the batch type operation used to separate the various components. One such known method is as follows: Lindahl and others, IVA. Tidskrift for Teknisk Vetenskoplig Forskning 26, 309 (1955). This device has a cone-shaped inclined cavity within a turntable, with a sixth loop attached to the cavity. The inclination and the side loop are used to minimize circulating currents and thus for mixing. But even with this training step currents returning to the circuit and the mixing also continues.

Another such device is in the following reference described: McEwen and Others, Analytical Biochemistry 23, 369-377 (1968). This device has a rotatable disc on, which has a kite-shaped cavity in a radial part. The sample to be separated is pumped into the centrifugal side of the cavity while the disk rotates. The slower settling particles are pumped out of the centripetal side of the cavity in this way, while the faster settling particles are kept within the cavity. By changing the speed of rotation, particles can of different sizes are pumped out of the cavity one by one.

Another method uses a suspending liquid, the viscosity of which changes over time. The sedimentation rate of the particles to be separated is determined by the viscosity of the suspending agent according to Stokes' law causes.

The methods described above use the concept of flow by a finite (limited) space within a turntable. Such an operation represents

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various inherent disadvantages. Come with the above procedures the flowing contents of the cavity in contact with the radial walls during the separation process. This is what causes the rise of Coriolis force effects, the turbulence along the wall adjacent to the rotation and a mixing of those to be separated Effect particles. Another problem with the prior art is that the fluid enters the cavity in the section of the smallest cross-section is introduced and in the centripetal direction into sections with increased cross-section emotional. This causes the overall velocity to decrease as the fluid moves in the centripetal direction. It is known in the fluidization art that high fluid velocity results in low particle concentration and therefore leads to a low suspension density. As a result, the suspension density within the cavity the tendency to be small at the outer radius and to increase in the centripetal direction. One such dense configuration is not stable (it's like trying to suspend a layer of mercury above a layer of water in a beaker) and leads to reversal and turbulent mixing. Since also If laminar flow exists at the radial boundaries of the void, the central part of the fluid has a greater velocity than the fluid flowing laminar at the borders. This process tends to create a convection mixing to evoke.

A particular problem with the above-described known methods when used in the field of blood separation and In other processes, too, there is a density gradient in the particles as a result of the different velocities in the various cross-sectional zones of the vacancy. This results in a turbulent mixing of the particles. Another result of the radial velocity gradient is that in zones of different velocities different refusal conditions occur. Blood particles exist from composite particles. At high shear conditions, the aggregates or composite particles become broken up into primary particles. At low shear conditions, the particles reassemble and move in

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Centrifugal direction to be broken up there again.

In addition to the problems mentioned above, what a separation seek to prevent at all, the specified procedures can only be used in batch operation. Such systems would not suitable for a continuous process where a specific blood component is removed from a donor's blood, while the remaining plasma and blood components are returned to the donor in a single continuous operation will.

The present invention aims to provide a method and an apparatus to be provided for centrifugal elution, the fluid with axially extending radial walls not should come into contact. Another object of the invention is to provide a method for centrifugal elution where the shear conditions are of such a nature that no breakdown of composite particles occurs.

The aforementioned advantages and other objects are achieved by placing a sample to be separated in a toroidal cavity which introduces concentrically within a turntable at a point between the centrifugal and centripetal boundaries of the cavity is arranged, and that one suspending agent uniformly from the centrifugal limit of the cavity to the centripetal limit can flow, with faster settling solids and suspending agents removed from the centrifugal part of the cavity and particles and suspensions that settle more slowly

to the
sion agents are removed from / centripetal part of the border.

Further advantages, goals and details of the invention emerge from the description of exemplary embodiments on the basis of FIG Drawing; in the drawing shows:

Fig. 1 is an oblique section through a designed according to the invention Rotor housing;

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2 shows a section through an alternative design of a rotor housing according to the invention;

FIGS. 3 and 4 are graphic representations for determining the overall geometry a rotor housing according to the invention.

According to the invention, it has been recognized that axially extending radial walls in a centrifugal elution device can be omitted = a cross-sectional view of the elution device according to the invention is shown in FIG. The elutration device (elutrator) has a

Win kiima · π Housing 1 with a quite toroidal cavity 6 enclosed therein. Line means 7, 8, 9 and 10 are associated with the Cavity in connection at different places. The line 7 serves as an inlet for the one used in the method according to the invention Suspension fluid. The line 10 serves as a Sample inlet. Line 8 and line 9 are the Zentripetalbzw. Centrifugal outlets. The lines or conductors are tubular Openings leading from the central inlet to the corresponding openings in the cavity. With small centrifuges (less than about 15 cm radius) is to obtain a satisfactory Flow one line arranged every 30 degrees or 12 lines for each of those shown in Fig. 4 suffice. However, any other arrangement, such as, for example, disk-shaped, can also be used Cavities, are used, which require the use of a uniform Allow flow.

On the centrifugal and centripetal sides of the cavity are permeable baffle plates 2 and 4 arranged through which Suspending agents and particles can flow. The outer baffle plate 2 is required to ensure that through Line 7 introduced suspending agent flows into the central part of the cavity, with a uniform and uniform Speed around the cavity. Such a steady flow minimizes those that would otherwise occur Mixed effects. The inner baffle 4 is for a successful Operation of the device is not absolutely necessary. It will

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however, it is preferred to provide the baffle plate 4 in the device, so as to minimize and evenly distribute any suction effects that can be caused by line 8.

The permeable baffle plates can be in the shape of wire mesh or in the form of a perforated plate-shaped material. Preferably, however, the baffle plates consist of a porous material, the open porosity of which is of the order of magnitude of the material to be separated. When blood separated is commercially available porous polytetrafluoroethylene having a pore size of approximately 25 microns expedient. The baffles can also be constructed in the form of a packed bed of beads.

The rotor 1 is designed in the same way as it is in centrifuges is common. Suitably grooved and drilled stacked stainless steel plates circumferentially attached to each other are connected by bolts, form a suitable training. However, if blood is to be separated it is necessary that the stainless steel is coated with an inert material such as polytetrafluoroethylene.

Conventional temperature control and rotating devices can be used. For example, together with the invention Rotor can be used with the control system used in the K-series centrifuge. Such means are in the the following literature reference: Brantley and others in "K-Series Centrifuges", Analytical Biochemistry 36, 434-442 (1970).

An alternative embodiment is shown in FIG. In this alternative embodiment, the permeable baffle plate 2 'extends only partially over the cavity 6 and a partition 13 intersects the baffle plate 2 ^{1 in} such a way that a flow path for the liquid flowing through the conductor 7 is formed by the permeable baffle plate 2 ¹ . In this case, the conductor 9 ^{1 is} centrifugally offset with respect to the permeable baffle plate 2 * in zones where no countercurrent occurs.

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Such an arrangement results in a higher degree of packing for Particles that settle faster before removal.

The method according to the invention is generally applicable to particles within

half of the size range of approximately 100 microns to 100 Å is applicable. Although a wide range of particle sizes can exist within the above range, so is the process of the invention designed in such a way that it divides the particles into two groups, one of which is larger than the dividing size, while the other is smaller than the dividing size. The inventive The method is carried out in such a way that continuously a sample containing the particles and a suspension liquid introduces into the cavity 6 through conductor 10, while at the same time the suspension liquid through the Conductor means 7 flows while the housing 1 is being rotated at a suitable speed. The through channel 10 Introduced particles tend to reach the centrifugal limit 1 2 to move and that with changing speeds as a result of the prevailing within the rotating housing Centrifugal field. Particles of different sizes tend to settle towards the centrifugal boundary 12, at different speeds, like this in general is given by Stokes' law. The by line 7 flowing suspension liquid - is through the cavity 6 pushed through at a speed intermediate the settling speeds of the particles introduced through line 10. The particles that settle at a speed which is greater than the speed of the line 7 entering suspension fluid, move in the centrifugal direction and out through line 9. Particles which settle at a speed less than the speed of the flowing suspension liquid / move in the centripetal direction and through line 8 to the outside. In the Carrying out the method according to the invention must have four flow rates or flow rates can be monitored and regulated to obtain satisfactory results. The four

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Flow rates are as follows.

1) The flow of the incoming sample through line 10;

2) The flow of suspending agent through line 7;

3) The flow of the slower settling particles and suspending agent through line 8;

4) The flow of the fast settling particles and suspending agent through line 9.

The first and second flow rates are determined by the geometry or dimensional considerations explained below. The third and fourth flow rates are best determined by considering the fourth flow rate regulated in such a way that the radiate separating intermediate layer of the rapidly and slowly settling particles between conductor means is regulated 10 and the inner permeable baffle plate 4 maintains. This can be done by having the separated products observed, or by providing transparent windows in the rotor housing, so that the intermediate layer either visually or can be observed photometrically. The intermediate layer is preferably centrally between line 10 and the inner permeable one Baffle plate 4 arranged.

In practicing the present invention, the overall geometry of the device are based on the particular fluid particle system with which the device is operated. As an an example consider a device capable of separating white cells or blood cells at 1.0 cm / sec. Thoroughbred with one typical volume fraction of 0.45 red blood cells. The maximum volume required for the cavity 6 is 500 ecm, there this is a safe volume that can be withdrawn from the donor.

The sedimentation coefficient of white blood cells in plasma at 37 C is approximately

S _n = 12 χ 10 ~ ⁸ sec.
W.

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The sedimentation coefficient of red cells or red blood cells depends on the degree to which individual cells combine to form large aggregates. This tendency changes from one individual to another. A shearing off of the blood shortly before the sedimentation tends towards the larger ones Breaking up aggregates and thus the sedimentation rate to reduce. The following value should be noted here:

S _R = 12 χ 1O ~ ⁷ see,

which should be readily achieved with most people's blood if severe shearing is avoided. Let this value a moderate amount of shear in the tubes and seals that deliver the blood to the separator.

The percentage by volume of white blood cells (C _rT ) in the blood is

about 0.002. This small value enables a convenient approximation that C _{w is} too small to noticeably influence the sedimentation rates of the red or white blood cells. Using this approximation, the representations of Figures 3 and 4 have been made to aid in determining the required size of the device and the amount of flow to be pumped through the porous or perforated baffle plates.

In Fig. 3, the ordinate is defined as follows:

FC ^F red blood cell flow rate = R

whereby .

F = volume flow rate of the blood in the current feeding the separator (in cm / see.)

C_ = concentration of red blood cells in the separator

feeding current (volume fraction)

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r = radial arrangement of the conductor means 10 (cm) & = axial length of the separator cavity (cm)

In Fig. 4 the ordinate is defined as follows:

Elution flow = E,

u.- ² r £ 2fes _R

E = volume flow rate of the plasma through

3 permeable baffle plate 2 (cm / see)

In both FIGS. 3 and 4, the concentration is on the abscissa of the red blood cells in the one that feeds the separator

F.
Current, namely C _R , plotted.

Since the capacity, as shown in Fig. 3, by using lower Feed concentration is increased, the whole blood is reduced to a concentration of

C _n = 0.30 diluted. The rotor speed was 700 revolutions per ti.

Minute and a feed channel radius of r _F = 10 cm selected. These values are useful and lead to a radial acceleration approximately equal to 55 times the gravity, which avoids damage to the blood cells.

From Fig. 3 the following results at C = 0.30:

XV.

TPP

^JL R = 0.076

The then required axial length of the cavity is Z = 1.9 cm

F From Fig. 4 the following results for C _n = 0.30:

Ε ' = 0.195

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The volume throughput of the plasma through the porous plates is then

E = 1.16 cm / see.

Typical dimensions for an elution device under the above conditions would be the following:

Radius of the centripetal wall 11: 6 1/2 cm. Radius of the centripetal plate 4: 7 1/2 cm Intermediate layer of red and white blood cells: 8 1/2 cm TO line: 10 cm

Centrifugal plate 2: 10 1/2 cm

Centrifugal wall 12: 11 1/2 cm

Axial height: 1.9cm

The above equations and approximations can of course be used to determine the elution device dimensions can be used for each system which is to be separated. The inventive The device and the method according to the invention can also be used in more than one stage. For example, the red and white blood cells can be in a first stage of each other while the plasma is separated from the red and white blood cells in a second and third stage. On the other hand, the products of the first stage can again be separated in order to achieve a higher separation quality. It Additional stages can also be formed in the same rotor housing simply by stacking these steps on top of each other or by using separate steps.

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Claims (6)

PATENT CLAIMS 1. Process for the separation of particles in a suspension liquid are suspended, characterized by the following steps: Continuously introducing a sample comprising the particles and the suspension liquid into a central part of a limited rotary cavity, a first part of the particles having different settling speeds compared to a second Has part of the particles within the suspension liquid, Flowing the liquid from the centrifugal side of the cavity to the centripetal side of the cavity at a rate which lies between the settling velocities of the first and second fraction of the particles, where the is The faster settling part of the particles moves in the centrifugal direction and the slower settling particles move move together with the flowing liquid in the centripetal direction, Removal of the faster settling particles and the suspension liquid from the centrifugal side of the cavity, and Removal of the slower settling particles and the suspension liquid from the centripetal side of the cavity. 2. The method according to claim 1, characterized in that the sample is whole blood, with the slower settling particles being the white blood cells, while the The faster settling particles are the red blood cells, and the suspending fluid is the plasma. 3. Centrifugal elution device, characterized by the following elements: w ι η Vc U ^ C «λ A rotor housing (1), which has a quite toroidal cavity (6) encloses, which is arranged concentrically around the axis of the housing and has a centrifugal limit and a centripetal 4 0 9 8 81/0911 has limit, the centrifugal limit with a radial distance is arranged opposite to the axis, which is greater than the radial distance of the central limit of this axis, first conductor means (7) communicating with the cavity at a point adjacent to the centrifugal boundary, second conductor means (9) communicating with the cavity, third conductor means (10) connected to the cavity at one point are in communication, the centripetal opposite the second conductor means and generally centrally on a radius of the Is arranged in the cavity, fourth conductor means (8) connected to the cavity at one point are in connection, the centripetal opposite the third conductor means and arranged adjacent to the centripetal boundary is, wherein the 'first, second, third and fourth conductor means are in communication with the outside of the housing, and a permeable baffle plate (2) concentric with the centrifugal and centripetal boundaries and axially cuts through at least a portion of the cavity and is attached to the housing at a radius intermediate the first and third conductor means whereby fluid entering through the first conductor means through the baffle flows to reach any one of the conductor means. 4. Apparatus according to claim 3, characterized in that - A second permeable baffle plate (4) between the third and fourth conductor means is provided. 5. Apparatus according to claim 3, characterized in that the permeable plate extends over the entire axial height of the cavity. 6. Apparatus according to claim 3, characterized in that the plate extends over only part of the cavity, and that a concentric partition extends from the permeable plate to the centrifugal boundary, whereby the 409881/0911 first conductor means are in communication with the cavity, namely within the space formed by the aforementioned permeable plate, the partition and the centrifugal wall and wherein the second conductor means is centrifugally opposite the permeable plate and on the opposite side of the cavity are arranged opposite the first conductor means. 409881/091 1 Blank page