CZ2015141A3 - Apparatus for magnetic separation of ferromagnetic particles, set for magnetic separation of particles, separation process of magnetic particles from a solution and use of the apparatus or set for magnetic separation of particles - Google Patents

Abstract

The subject of the invention is a device for magnetic separation of ferromagnetic particles from solutions comprising a magnet and a separation vessel holder, the holder being positioned relative to the magnet such that each separation vessel is placed in the holder by a region of its separation wall adjacent to it the edge of the north or south pole of the magnet, wherein the distance of any other portion of the separation vessel from the edge of the opposite pole of the magnet is always greater than the distance between the wall area to be separated and the edge of the magnet pole used for separation. The invention also provides a magnetic particle separation kit comprising a device for magnetic separation of ferromagnetic particles from solutions and at least one separation vessel. The invention also relates to a method for separating magnetic particles from a solution and to using a device for separating magnetic particles from a solution, mixture or suspension.

Description

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The invention relates to a device and a set for the separation of ferromagnetic particles from a roll and for the separation of magnetic particles.

Current state of the art

Magnetic separations are widely used in many fields. One of these areas is also separation using particles that contain a ferromagnetic component (further referred to as ferromagnetic particles), which are usually associated with other substances that serve as more or less specific absorbers of molecules contained in the solution. An example is separation using ferromagnetic particles associated with extravidin, which serve to isolate substances containing biotin. Another example is ferromagnetic particles that are associated with protein A or particles used for nucleic acid isolation. These particles are then useful for the separation of complexes that are associated with antibodies.

Special separators are usually used for magnetic separations. The most common way is to place a container with ferromagnetic particles in a device that is equipped with a container holder and a magnet. In these separators, the containers are tilted with respect to the bushing of the pole in such a way that separation takes place only in a certain part of the container (Qbr. 1). The effect of the magnet results in the concentration of particles on the wall and this enables, for example, the subsequent removal of the solution from the container, e.g. using a pipette, without the simultaneous absorption of ferromagnetic particles with the isolated substance. These separators are most often produced for a single container size. For a different size, an additional separator must be purchased. A certain disadvantage is also the fact that the ferromagnetic particles are usually attached to a large part of the wall, including the part closely adjacent to the bottom of the container or even extending to the bottom itself. This is due to the fact that the difference in magnetic strength at different distances is not large enough to concentrate the particles into a narrow area above the bottom. Therefore, relatively careful control is necessary during the removal of the solution, so as not to remove part of the Particles at the same time. In the case of a low concentration of separated particles, due to the uniform distribution over a relatively large area, there are difficulties in deciding whether there has been ! « * · Si « ·· * • · V ♦ ♦ · >· · i «»»· · · ··5 • · · · « · ··*

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The essence of the invention

The present invention describes a device for magnetic separation of ferromagnetic particles. The described device allows checking the position of the separated ferromagnetic particles in the separation container and achieving a situation where the separated particles are in a very narrow area of the wall of the separation container. Furthermore, this device allows the use of different sized separation containers. The following observations were used in its construction:

1^) If the ferromagnetic particles are freely dispersed in a solution in a fully filled separation container, which is essentially a cylinder, and this cylinder is placed close to the wall of the magnet so that the longitudinal axis of the separation container is oriented parallel to the wall of the magnet connecting its south and north poles , while the separation container on both sides is longer than the length of the magnet, the particles and concentrate in the area of the poles of the magnet (^br. 2).

2^ If this separation vessel is moved so that its bottom is above the level of the edge of one of the poles, and/or a vessel is used whose shape ensures that the bottom is at a greater distance from cc of that pole than any other part of the vessel from the opposite pole (0br. 3 and 4), the highest concentration of particles is in the region of the edge of the opposite pole.

3^) If the wall of the separation container is inclined along the edge of the north or south pole (@br. 5 and 6), thereby causing the bottom of the separation container to deviate from the opposite pole, there will be a significant enrichment of the amount of ferromagnetic particles in the areas around these edges.

The device according to the present invention contains a magnet and a holder for separation containers ensuring their position relative to the magnet. According to our observations, for optimal separation, the magnet must be placed so that the separation container is the area of its wall where the user wants to separate ferromagnetic particles, as close as possible to the edge of the north or south pole of the magnet, optimally touching the magnet at the edge, while the distance from this edge must always be less than O' the distance of any other part of the container from the edge of the other pole (0br. 3 to 7). This can be achieved by holding the separation containers and/or the position of the magnet and/or the shape of the separation containers. If magnets are used in the device, the axes connecting the north and south poles are parallel to the axes of the containers, then these containers are fixed so that the bottom is located in the vertical direction above the surface of the pole, which is opposite to the pole, whose edge are used for separation (0br. 3) and/or specially shaped containers are used, which by their shape ensure that the distance of the bottom of the container from the pole opposite to the pole whose edge is used for separation is greater than the distance of this edge from the container ( ^br. 4 and 6). If inclined magnets are used, it is indifferent, it attracts ie in the vertical direction nnlnha Hna nádnl-iVv whlerlem V nA In Ltorv in nnopnó V Lkní t · « * · # *»· I ' < t · * · · » · « « * « « · · » ** ····>· » · * * a » · * ** j 4 · > · · 9 9 9**·· · · · í d

the edge serves to separate particles (0br. 5 and 7). The indisputable contribution of the device to the state of the art is the concentration of separated particles in a narrow range of the wall, while it is possible to optionally move this area to any height of the container. This facilitates visual inspection of the separation and subsequent removal of the solution from the container.

The present invention describes a device for the magnetic separation of ferromagnetic particles from solutions, which contains a magnet, preferably in the shape of a perpendicular prism, more preferably a cuboid, and a holder for separation containers, wherein the holder for the separation containers is positioned relative to the magnet in such a way that each separation container is placed after being inserted into the holder the area of its wall on which separation is to take place near the edge of the north or south pole of the magnet, the distance of any other part of the separation vessel from the edge of the opposite pole of the magnet being always greater than the distance between the area of the wall on which separation is to take place and the edge of the magnet pole , which serves for separation.

In one embodiment, the device includes a magnet holder.

In an advantageous embodiment, the device according to the invention contains a plate on which a magnet holder is placed, under which a separation plate is replaceably placed, while the plate contains a recess for a magnet holder and holes for pins used to seat a replaceable separation container holder with holes for separation containers.

In another preferred embodiment, the openings for the separation containers are located in opposite plates, the magnet being located between these plates. The holder of the separation containers is therefore formed by a pair of mutually parallel surfaces that contain openings for different sizes of separation containers, while the magnet is placed between these two surfaces so that, depending on the need, it is possible to use one or the other size of the separation containers.

In another advantageous embodiment, the holder for the separation containers is replaceable.

The device according to the present invention is made, with the exception of the magnet and optional ferromagnetic inserts for attaching the magnet and screws, from a material that is not attracted by the magnetic field of the magnet, preferably selected from the group including thermoplastics, stainless non-magnetic steel and aluminum alloys. In one embodiment of the invention, the holder is maanptii vvmhpn 7

The magnet is selected from the group including permanent magnets, preferably a neodymium, samarium-cobalt or AlNiCo magnet.

In another embodiment, the device according to the invention comprises pins, fixed in a plate that fixes the magnet holder, and replaceable container holders in the form of plates pushed onto the pins, which fit into holes in these plates.

The subject of the present invention is also a set for magnetic separation, containing a device according to the invention and at least one separation container, wherein the magnet has the shape of a perpendicular prism, preferably a cuboid, and the separation containers have a conical shape or the shape of an essentially cylinder with a flat, conical or rounded bottom, whereby the magnet is positioned so that its axis, directed from the north pole to the south, makes an angle equal to or greater than 0° and less than 90° with the axes of the separation vessels, connecting the bottom and the neck of the vessels, preferably ⁰ * to 80°.

In another embodiment, the magnetic separation kit has a magnet in the shape of a perpendicular prism, preferably a cuboid, and the separation vessels have a conical shape and/or an essentially cylindrical shape with a flat, conical or rounded bottom, the magnet being positioned so that its axis, pointing from the north pole to the south, makes an angle of 0° with the axes of the separation vessels, connecting the bottom and the neck of the separation vessels.

The separation containers are made of a material that is not attracted by the magnetic field of the magnet, preferably selected from the group including thermoplastics.

The subject of the present invention is also a method of separating magnetic particles from a solution, in which the solution is transferred to a separation container, and subsequently the separation container is brought closer to a magnet in the shape of a perpendicular prism, preferably a cuboid, so that it is placed by the area of its wall on which the separation is to take place , near the edge of the north or south pole of the magnet, while the distance of any other part of the separation vessel from the edge of the opposite pole magnet is always greater than the distance between the area of the wall on which the separation is to take place and the edge of the magnet pole that serves for the separation.

The subject of the present invention is also the use of a device or set according to the invention for the separation of ferromagnetic particles from a solution, mixture or suspension.

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Giant. 1 (state of the art): Schematic of mutual placement of magnet 1 and separation container A in a classic separator. Poles are represented by different shades. The magnet is placed with the pole facing the container containing the ferromagnetic particles. Ferromagnetic particles are concentrated in the area AT Pn when aspirating liquid, it is necessary to place the tip of the pipette as far as possible in the lower right corner of the container to avoid aspirating particles.

Giant. 2 (essence of the invention): With the illustrated orientation of the magnet 1 and the separation container A, the highest accumulation of particles in the container occurs in the areas AI adjacent to the edges of the poles.

Giant. 3 (essence of the invention): With the shown mutual position of magnet 1 and separation container A, when the bottom of the container is above the edge of the magnet pole, the highest accumulation of separated ferromagnetic particles occurs in the area AI of the upper edge of the magnet. This arrangement allows precise control of the position of the ferromagnetic particles in the container. In our experience, this is a sufficient solution for most situations.

Giant. 4 (essence of the invention): When container A with a rounded or conical bottom is used, sedimentation of the separated particles is minimized due to the separation of the bottom from the magnet 1 in the area of the bottom. Accumulation occurs in the AI region of the edge of the magnet.

Giant. 5 (essence of the invention): With the illustrated orientation of the magnet 1 and the wall of the separation container A, there is an almost exclusive accumulation of ferromagnetic particles in the AI region. This arrangement allows the most precise accumulation of particles in the desired position defined by the edge of the magnet.

Giant. 6 (the essence of the invention): When using a container A with an inclined wall and a magnet 1, it is possible to use such an arrangement to ensure the maximum accumulation of ferromagnetic particles in the area AI.

Giant. 7 (the essence of the invention): It is completely indifferent whether the edge of the north or south pole of the magnet 1 is used for the separation in the containers A. The particles accumulate in the areas AI.

Giant. 8: 3D model of the device according to Example 1 (A), front view (B) and side view (C). These parts are visible in the pictures: Plate 4 with wbránim nrn O marmat 1 n - in „ -----pins 5 and with holes 4A for screws Λ separation plate 3 with holes, allowing changing the height of the magnet by replacing it with another one with a different thickness 1^ exchangeable holders 6 of separation containers equipped with holes 6B for separation containers and a pair of holes 6A, which are complementary to the mountings on the pins 5. The holder 2 of the magnet 1 contains holes 2A with threads for screws 7.

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Giant. 9: 3D model of the device from Example 4 (A) and side view (B).

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Giant. 10: 3D model of the device from Example 6 (A) and side view (B).

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Giant. 11: 3D model of the device from Example 9 (A) and side view (B).

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Giant. 12: 3D model of the device of Example 11 (A) and side view (B). The body 8 of the device contains holes 6B for separation containers and simultaneously serves as a holder for the magnet 1.

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Giant. 13: 3D model of the device of Example 14 (A) and side view (B).

Examples of embodiments of the invention

Example 1: Device for magnetic separation of ferromagnetic particles d

A magnetic separation device was assembled. On $br. 8A to 8C show a ferromagnetic particle separation device for 3 different sizes of fitted containers. The device consists of a base plate 4 with holes 4B for pins 5, holes 4A for screws 7 for fixing the holder 2 of the magnet 1 and a recess 4C for the holder 2 of the magnet 1 and a separation plate 3, three types of holders 6 separation containers with one row of holes 6B for separation cups and holes 6A for pins 5, holder 2 of the magnet £ with holes 2A provided with thread for fixing screws, magnet 1, different thickness separating replaceable plates 3 with holes for screws 7 for fixing the holder 2 of the magnet 1, two screws 7 for fixing the holder 2 magnet 1 and four pins 5, which are embedded in the base plate 4. The pins 5 are provided with a fitting that is complementary to the holes 6A in the container holders. With the different sizes of these offsets and complementary holes 6A in the holders 6 of the separation containers, the positioning of the holders 6 of the separation containers at suitable heights for different separation containers is achieved. The separation containers are fixed in the holder 6 by means of the mounting on the containers or by means of the base plate 4. The separation plates 3 allow checking the height of the maenet 1 location relative to the senaration containers. At the same time, two different «

holders for 6 separation containers. The base plate 4 and the holders 6 of the separation containers are made of polycarbonate. Alternatively, plexiglass, polyethylene, polypropylene or ABS (acrylonitrile butadiene styrene) were used. The holder 2 of the magnet 1, the separation plates 3 and the pins 5 are made of aluminum or non-magnetic steel. Alternatively, polyvinylidene fluoride, polyethylene terephthalate or polyamide have been used. A neodymium magnet 1 in the shape of a regular quadrilateral prism magnetized in the direction of its width was used. Alternatively, a samarium cobalt magnet, an AlNiCo magnet or a ferrite magnet was used. The magnet 1 was glued to the holder 2 of the magnet 1, alternatively the holder 2 of the magnet 1 contained a recess for a ferromagnetic metal plate, which, if it was on the side of the magnet, was alternatively glued, pressed or cast into the body of the holder, on which the magnet was seated without its gluing needs. Alternatively, the recess is on the side away from the magnet. In this case, there was no need to glue the plate. The magnetic force of the magnet was enough to fix it and at the same time fix the magnet. Magnet 1 was placed so that its axis connecting its poles formed an angle of approximately 45 ⁰ with the axis connecting the bottom and neck of the separation containers. Thanks to the possibilities of combining different holders of separation containers on opposite sides of the magnet, the device allows simultaneous separation in at least two types of separation containers. If the separation vessels have the shape of a cylinder with approximately the same diameter, it is possible to use several types of separation vessels for magnetic separation. Thanks to the use of separation plates 3 of different thickness and different holders 6 of the separation containers, it is possible to achieve different levels of separation of ferromagnetic particles.

Example 2: Equipment for magnetic separation.

The device is identical to the device from Example 1 with the following difference:

The shape of the magnet 1 is a perpendicular prism, preferably a cuboid, which is oriented so that its axis connecting its poles forms an angle greater than 0° and less than

Example 3: Magnetic Separation Kit.

The magnetic separation kit includes the apparatus of example 1 or 2 as well as conical or substantially cylindrical separation vessels with a flat, conical or rounded bottom. The containers were made of thermoplastics. Cylindrical separation containers have the same diameter, but different length and thus also volume. This makes it possible to use one set of separation container holders to separate several types of containers. In addition, thanks to the use of separation plates 3 in all these cylindrical types, it is possible to simply control the height at which the separation of ferromagnetic particles occurs.

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Example 4: Apparatus for magnetic separation (Figs. 9A and 9B).

IV

The device is identical to the device from example 1 with the following difference:

The shape of the magnet 1 is a perpendicular prism, preferably a cuboid, and the magnet is oriented in such a way that its axis Λ connecting its poles forms an angle with the axis connecting the bottom and neck of the separation containers. magnetic stainless steels. In the second case, JHis magnetic force is used to hold the magnet. The holder 2 of the magnet 1 is similarly attached to the base plate 4 using screws 7 as in example 1. Alternatively, a plate made of ferromagnetic material, e.g. stainless steel, is inserted into the recess for the magnet. This plate is attached alternatively by gluing, pouring, pressing or by means of screws, and the magnet is then fixed directly to the plate thanks to the magnetic force. In this case, a separate magnet holder is not used. Alternatively, a recess is placed in the lower side of the base plate, into which a plate made of ferromagnetic material is inserted, e.g. non-rusting ferromagnetic steel, which can alternatively be glued, cast, pressed or screwed on, preferably just inserted and the force of the magnet sufficient to fix it. This also ensures the fixation of the magnet. Also in this case, the device does not include a separate magnet holder. Instead, the magnet is directly placed in a recess in the base plate. Alternatively, the magnet is inserted or pressed into the recess without additional fixation, or is fixed with glue without the need to use additional fixation elements.

Example 5: Magnetic separation kit.

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The kit includes the device from example 4 as well as separation containers with a flat, conical or rounded bottom.

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Example 6: Device for magnetic separation (^)br. 10A and 10B).

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The device is identical to the device from example 1 with the following difference:

The base plate 4 contains two holes 4B for the pins 5. The holders 6 of the separation containers contain two rows of holes 6B for the separation containers. As a rule, the device does not allow simultaneous separation in two types of separation containers. The exception is when cylindrical containers of approximately the same diameter are used.

Example 7: Magnetic separation kit.

The set includes the device from Rříklad 6 as well as the separation conical or shaped containers

In the shape of a cylinder With a conical bottom and a cylindrical bottom

they have the same diameter, but different length and thus volume. This makes it possible to use one set of separation container holders to separate several types of containers. In addition, thanks to the use of separation plates 3 in all these types, it is possible to simply control the height at which ferromagnetic particles are separated.

Example 8: Equipment for magnetic separation.

The device is identical to the device from example 4 and in terms of arrangement similar to the device from example 6 with the following difference:

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Compared to the device of example 4, the base plate 4 contains two holes 4B for pins. The holders 6 of the separation containers contain two rows of openings 6B for the separation containers.

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Compared to the device from example 6, the orientation of the magnet is the same as in example 4.

As a rule, the device does not allow simultaneous separation in two types of separation containers.

The exception is when cylindrical containers of approximately the same diameter are used.

Containers with a flat, conical or rounded bottom are preferably used.

Example 9: Apparatus for magnetic separation (Figs. 11A and 11B).

The device is identical to the device from example 1 with the following difference:

The base plate 4 contains two holes 4B for the pins 5 and, thanks to its special shaping, provides support for the magnet L Magnet X in the shape of a perpendicular prism, preferably a cuboid, is glued directly to the base plate 4 or attached by means of an alternatively glued, cast or pressed stainless steel ferromagnetic plate of steel in a position where the surface of its poles forms an angle equal to or greater than 0° and less than 9θ£ with the surface of the holders 6 of the separation containers with the openings 6B for the separation containers. The edge of magnet 1 is used for separation. As a rule, the device does not allow simultaneous separation in two types of separation containers.

Example 10: Magnetic separation kit.

The kit includes the apparatus of Example 9 as well as separation conical or substantially cylindrical shaped containers with a straight, conical or rounded bottom. Cylindrical separation containers have the same diameter, but a different length and thus volume. This makes it possible to use one set of separation container holders to separate several types of containers.

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Example 11: Device for magnetic separation (0br. 12A and 12B).

The device is composed of a separator body 8, created as a combination of a holder for separation containers and a holder mannpfu kfprp dá1p nheahnip wvhroní mnnnut 1 <>

The body 8 of the separator is made of thermoplastics. Magnet 1 is the same as in example 1 and has the same orientation with respect to the holes for separating the container. The magnet is either simply inserted into the hole in the separator body or glued on.

Example 12: Equipment for magnetic separation.

The device is identical to the device described in Example 11 with the following difference:

The position of magnet 1 in relation to the separation containers is the same as in example 4.

Example 13: Device for magnetic separation (®br. 13A and 13B).

The device consists of a separator body 8, which contains a recess for the magnet 1 and openings 6B for separating the container and magnet 1. The separator body 8 serves as a holder for the separation containers and simultaneously as a magnet holder. Body 8 is made of thermoplastics, the magnet is the same as in Example 1. It differs only in shape. Magnet 1 in the shape of a perpendicular prism, preferably a cuboid, is inserted into the surface of the partition that connects two opposite parallel plates with holes for separating the container. Alternatively, the magnet is pressed into the recess without further fixation or glued and is positioned so that its axis connecting its poles is clamped with the axis connecting the bottom and the neck of the separation vessels at an angle equal to or greater than 0° and less than 9θ£. The edge of a magnet is used for separation. By combining different mutual distances of opposite plates with holes for separating the container and the distance of these holes from the separating edges, it is achieved that one device can be used for separation in at least two types of separating containers.

Example 14: Magnetic separation kit.

The set includes the device from example 13 as well as a separate! conical containers or substantially cylindrical shaped containers with a flat, conical or rounded bottom of two different diameters and different lengths.

Industrial applicability

The device according to the present invention can be used, for example, in areas where magnetic separations are performed. An example is the separation of proteins using antibodies, when ferromagnetic particles are conjugated with protein A. Another example is the separation of substances containing biotin in the whole molecule. In this case, it is possible to use particles containing a ferromagnetic component and streptavidin for separation. Another example is the non-specific isolation of nucleic acids.

Claims (13)

1. Device for the magnetic separation of ferromagnetic particles from solutions, which contains a magnet (1) and a holder (6) of separation containers (A), characterized by the fact that the holder (6) of separation containers (A) is positioned relative to the magnet (1) in such a way that that each separation vessel (A) after being inserted into the holder (6) of the separation vessels (A) is placed with the area of its wall on which the separation is to take place near the edge of the north or south pole of the magnet (1), while the distance of any other part of the separation vessel (A) from the edge of the opposite pole of the magnet (1) is always higher than the distance between the area of the wall on which the separation is to take place and the edge of the pole of the magnet (1) that serves for separation. 2. The device according to claim 1, characterized in that it further comprises a magnet holder (2). 3. Device according to claim 1, characterized by the fact that it further includes a plate (4) on which the holder (2) of the magnet (1) is optionally placed, under which a separation plate (3) is placed, preferably replaceable, while the plate ( 4) contains a recess (4C) for the holder (2) of the magnet (1) or for the magnet (1) and holes (4B) for the pins (5) used to seat the holder (6) of the separation container (A). 4. The device according to claim 1, characterized in that the openings (6B) for the separation containers (A) are located in opposite plates, while the magnet (1) is located between these plates. 5. Device according to claim 1 to 3, characterized in that the holder (6) of the separation container (A) is replaceable. 6. Device according to any of the preceding claims, characterized in that it is made, with the exception of the magnet (1) and optional ferromagnetic inserts for attaching the magnet and the screw, from a material that is not attracted by the magnetic field of the magnet, preferably selected from the group including thermoplastics, stainless non-magnetic steel and aluminum alloys. 7. Device according to claim 2 or 3, characterized in that the magnet holder (2) is made of ferromagnetic material. 8. Device according to any one of the preceding claims, characterized in that the magnet (1) is a permanent magnet, preferably selected from the group comprising a neodymium magnet, a samarium cobalt magnet or an AlNiCo magnet. 9. Device according to any one of claims 3 and 5 to 8, characterized in that it contains pins (5) fixed in a plate (4) which fixes the magnet (1) and exchangeable holders (6) of the separation containers (A) in the form plates pushed onto the pins (5) that fit into the holes (6A) in these plates. 10. A set for magnetic separation^ comprising a device according to any one of the preceding claims, and at least one separation vessel (A), characterized in that the magnet (1) has the shape of a perpendicular prism and the separation vessels (A) have a conical or substantially cylindrical shape with a flat, conical or rounded bottom, the magnet (1) being positioned so that its axis, directed from the north pole to the south, is in contact with the axes of the separation vessels connecting the bottom and the neck of the vessels, an angle equal to or greater than 0° and less than 90 {°. / 'zJ&aj , _r ......_ , , .....\ 11. Magnetic separation kit according to any one of claims 1 to 8, characterized in that the magnet (1) has the shape of a perpendicular prism, and the separation vessels (A) have a conical shape and/or a substantially cylindrical shape with a flat, conical or rounded bottom, wherein the magnet (1) is positioned so that its axis, pointing from the north pole to the south, makes an angle of 0° with the axes of the separation vessels connecting the bottom and the neck of the separation vessels (A). 12. A method of separating magnetic particles from a solution, characterized by the fact that the solution is transferred to a separation container (A), and subsequently the separation container (A) is brought close to the magnet (1) in the shape of a perpendicular prism, so that it is placed by the area (AI) of its the wall on which the separation is to take place, near the edge of the north or south pole of the magnet (1), while the distance of any other part of the separation vessel (A) from the edge of the opposite pole of the magnet (1) is always greater than the distance between the area (AI) of the wall, on which the separation is to take place, and the edge of the magnet pole (1), which is used for separation. , . 7 .....~ ._________—...............'' _____________---- 13. Use of a device/or set according to any one of claims 11 to 11 for separating ferromagnetic particles from a solution, mixture or suspension.