WO2012046131A1 - Magnetic tissue homogenizing - Google Patents
Magnetic tissue homogenizing Download PDFInfo
- Publication number
- WO2012046131A1 WO2012046131A1 PCT/IB2011/002360 IB2011002360W WO2012046131A1 WO 2012046131 A1 WO2012046131 A1 WO 2012046131A1 IB 2011002360 W IB2011002360 W IB 2011002360W WO 2012046131 A1 WO2012046131 A1 WO 2012046131A1
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- WO
- WIPO (PCT)
- Prior art keywords
- magnetic
- magnetic field
- container
- sample
- homogenizing element
- Prior art date
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C17/00—Disintegrating by tumbling mills, i.e. mills having a container charged with the material to be disintegrated with or without special disintegrating members such as pebbles or balls
- B02C17/005—Disintegrating by tumbling mills, i.e. mills having a container charged with the material to be disintegrated with or without special disintegrating members such as pebbles or balls the charge being turned over by magnetic forces
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C17/00—Disintegrating by tumbling mills, i.e. mills having a container charged with the material to be disintegrated with or without special disintegrating members such as pebbles or balls
- B02C17/10—Disintegrating by tumbling mills, i.e. mills having a container charged with the material to be disintegrated with or without special disintegrating members such as pebbles or balls with one or a few disintegrating members arranged in the container
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B02—CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
- B02C—CRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
- B02C17/00—Disintegrating by tumbling mills, i.e. mills having a container charged with the material to be disintegrated with or without special disintegrating members such as pebbles or balls
- B02C17/18—Details
- B02C17/20—Disintegrating members
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N1/00—Sampling; Preparing specimens for investigation
- G01N1/28—Preparing specimens for investigation including physical details of (bio-)chemical methods covered elsewhere, e.g. G01N33/50, C12Q
- G01N1/286—Preparing specimens for investigation including physical details of (bio-)chemical methods covered elsewhere, e.g. G01N33/50, C12Q involving mechanical work, e.g. chopping, disintegrating, compacting, homogenising
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F33/00—Other mixers; Mixing plants; Combinations of mixers
- B01F33/45—Magnetic mixers; Mixers with magnetically driven stirrers
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N1/00—Sampling; Preparing specimens for investigation
- G01N1/28—Preparing specimens for investigation including physical details of (bio-)chemical methods covered elsewhere, e.g. G01N33/50, C12Q
- G01N1/286—Preparing specimens for investigation including physical details of (bio-)chemical methods covered elsewhere, e.g. G01N33/50, C12Q involving mechanical work, e.g. chopping, disintegrating, compacting, homogenising
- G01N2001/2866—Grinding or homogeneising
Definitions
- the present invention relates to a method and device for homogenizing by mechanical action, a sample in a container having a container wall with the sample adhered at a site of the container wall.
- Sample preparation plays a crucial role in particular in preparing samples for sensitive diagnostic analyses.
- nucleic acids for use in diagnostics often have to be isolated from various tissues. The isolation is frequently followed by amplification reactions, such as the so-called polymerase chain reaction (PCR).
- PCR polymerase chain reaction
- the methods for isolation and in particular also the initial step of sampling from tissue can be automated.
- a container comprising a sample is introduced in a centrifuge, wherein, due to the centrifugal forces action on the sample, a solid fraction of the sample is adhered at a site of the container wall. This solid fraction of the sample has to be treated further in accordance with procedures known in the art.
- nucleic acids for PCR is work-up of tissue for treating disrupted tissues or tissue cells by a mechanical and/or chemical treatment for example by enzymes such as proteinases. Then the nucleic acid e. g. genomic DNA is adsorbed on carriers such as e.g. magnetic beads. After washing steps often a rigid solid body remains, from which the DNA can often only be removed in a cumbersome way.
- the quality of the isolation of nucleic acids for PCR is often determined by the skill of the technician and thus not reproducible when changing from one laboratory to another.
- WO-A-2004/004874 One example of such a steering apparatus is disclosed in WO-A-2004/004874. However, this known steering apparatus cannot be used e.g. for disintegrating or grinding a sample adhered to a container wall and to be dissolved in a liquid.
- JP-A-2008 136945 JP-A-2006 320888, US-A- 2004/053319, and US-A-2002/119200.
- a magnetic grinding element is subjected to a discontinuous magnetic field resulting in impacting the grinding element onto a sample.
- An object of the present invention is to provide a method which improves sample preparation .
- a method for homogenizing, by mechanically action, a sample in a container wherein the container comprises a container wall with the sample adhered at a site of a container wall, and wherein the method comprises the steps of
- the magnetic homogenizing element placing a magnetic homogenizing element in the container, the magnetic homogenizing element having an axis, and
- the magnetic homogenizing element under the influence of the time-variant magnetic field, is rotated around its axis as well as is press against an area of the container wall comprising the site where the sample adheres at the container wall thereby homogenizing the sample.
- a device for grinding, by mechanical action, a sample in a container comprising a support for supporting the container,
- a magnetic field generating means for creating a magnetic field having a direction which is time-variant, with the magnetic field extending through the container, and
- the magnetic homogenizing element for placing into the container, the magnetic homogenizing element having a axis,
- the magnetic homogenizing element under the influence of the changing magnetic field, is capable of being rotated around its axis and is pressed against the sample so as to mechanically interact with the sample for homogenizing the same.
- One of the main features of the present invention is the use of a time-variant magnetic field and at least one magnetic homogenizing element subjected to the magnetic field. Since the magnetic field is time-variant (in its direction and optionally in its magnetic force distribution), the magnetic homogenizing element is moved within the container in a plurality of directions in space and, moreover, is rotated, wherein both movements are highly inhomogeneous and irregular. This effect can be used according to the invention by impinging on the sample for homogenizing the same.
- homogenizing means the result of each kind of mechanical action of the homogenizing element on the sample. Together with homogenizing, the sample can also be subjected to a grinding process meaning crushing, fragmenting, comminuting, breaking, disintegrating, mincing, smashing or the like.
- a magnetic field generating means is used which comprises a permanent magnet or an electromagnet both provided with a north pole region and a south pole region.
- this magnet preferably is formed of an NbFeB alloy.
- the magnetic field generating means further comprises a control unit so as to control the current through the electromagnet for generating a magnetic field having a timed-variant direction/orientation and, optionally, a time-variant magnet force distribution.
- the homogenizing element may have an arbitrary shape.
- experiments have shown that forming the homogenizing element as a substantially elongated body is preferred for the homogenizing process.
- a substantially elongated homogenizing element the same is divided along its longitudinal direction into a north pole region and a south pole region wherein each of these regions extend along a lateral side of the substantially elongated body.
- the shape of the container within which the at least one homogenizing element is arranged is not relevant for the invention.
- substantially cylindrical containers or other test tubes are preferred experiments carried out in which the container was an Eppendorf test tube having a substantially conically-shaped bottom.
- the homogenizing element is a substantially elongated body oriented in a substantially upright direction within the container so as to impinge onto the inner side wall of the container if the homogenizing element is subjected to the time-variant magnetic field.
- the method and device according to the invention can be applied to a plurality of containers positioned in a rack and arranged in columns and rows of a two- dimensional area or arranged along a circle of an annular rack, wherein at least one homogenizing element is arranged in each container.
- the present invention can be used for e.g. dissolving samples of any kind in a liquid.
- the sample can be tissue of various origins such as plant, animal or human tissue and/or wherein the sample comprises biopolymers such as proteins, carbohydrates, lipids, nucleic acids, in particular DNA, RNA, and/or wherein the sample is a lysate from cells prepared for the isolation of nucleic acids, in particular genomic DNA.
- time-invariant magnetic field means an (external) local magnetic field or magnetic field area at the site of the magnetic homogenizing element which the magnetic homogenizing element is subjected to wherein the magnetic coupling of the local magnetic field to the magnetic homogenizing element is changing i.e. is time-invariant upon relative movement of the container including the magnetic homogenizing element and the magnetic field generating means or movement of the container including the magnetic homogenizing element within an external magnetic field with, upon movement of the container, changing the relative orientation of the magnetic homogenizing element and its north-south-pole orientation and the magnetic field lines i.e.
- the sample to be homogenized does not have to include magnetic particles agglomerates but can include other particles agglomerates.
- Figs. 1 to 4 schematically show the interaction of a displaceable magnetic field and a magnetic homogenizing element arranged within a test tube for homogenizing a sample adhered at a site of the inner wall of the test tube
- Fig. 5 shows a section of a rack supporting a plurality of test tubes with a magnetic field generating means arranged between the test tubes for generating a time-variant magnetic field subjected to adjacent test tubes.
- Fig. 6 shows comparative results of qualitative PCR results.
- Fig . 7 shows an electrophoretic gel of conventionally prepared DNA and the one according to the invention.
- Figs. 8 to 12 show further embodiments of a homogenizing device in which a container including a sample to be homogenized is moved relative a magnetic field.
- a container 10 comprises a substantially conically-shaped bottom 12 with a sample 14 to be dissolved in a liquid 16 within the container 10 is adhered at a site 18 at the inner side of the container wall 20.
- a magnetic field generating means 22 is arranged outside of the container 10 and comprises a permanent magnet 24 which is displaceable.
- the permanent magnet 24 has a north pole region 26 and a south pole region 28 and generates a magnetic field 30 having magnetic field lines 32 extending through the container wall 20 and the sample 14.
- the permanent magnet 24 in this embodiment is rotatable in the direction of arrow 34. However, in the sense of the invention it would be sufficient if the permanent magnet 24 would oscillate about an oscillation access extending between the north and south pole regions 26 and 28, respectively.
- the magnetic field generating means generates a time- variant changing magnetic field within the container 10. Again, it is to be noted that this can be provided by any kind of movement of the permanent magnet 24. Also it is to be noted that the permanent magnet 24 could be replaced by an electromagnet.
- a homogenizing element 36 which in this embodiment comprises an elongated body.
- the magnetic homogenizing element also comprises a north pole region 38 and a south pole region 40 which under the influence of the magnetic field established by the magnetic field lines 32 is oriented accordingly. Therefore, when changing the magnetic field of the magnetic field generating means 22, the magnetic homogenizing element 36 will be moved by tilting, rocking, turning and the like movements within the container 10 as shown in Figs. 1 to 4.
- the result of these movements of the magnetic homogenizing element 36 in diverse directions in space and around the longitudinal axis of the magnetic homogenizing element 36 is that the magnetic homogenizing element 36 impinges and acts on the sample 14 for homogenizing the same. This process is very efficient as experiments have shown.
- FIG. 5 illustrates several containers 10 that can be supported in a rack 42 wherein within each container 10 a sample 14 and a homogenizing element 36 are arranged.
- a magnetic field generating means 22 is arranged close to the containers 10 for generating a time-variant magnetic field (with regard to the direction of the magnetic field lines and/or the magnetic force distribution). Under the influence of this time-variant magnetic field, the magnetic homogenizing elements 36 act on the respective sample 14 for homogenizing them.
- the invention can be used in the field of molecular biology and chemistry and is applied in laboratory diagnostics, in particular for sample preparation for PCR analysis, for the extraction of DNA from biological preparations and for the elimination or neutralization of contaminants to obtain DNA having a purity grade that is suitable for the amplification reaction.
- the invention relates also to a process for homogenizing concentration as formed during mixing of a blood sample with magnetic iron oxide nanoparticles coated with Si0 2 adsorbent in a lysing solution.
- the use of magnetic particles is not fundamentally different from the use of other kinds of sorbents (latexes, polymer sorbents or glass), but enables the application of magnetic separation instead of centrifugation and filtration.
- the magnetic particles are based on iron oxide nanoparticles having super paramagnetic properties. Particles based on iron oxide having super paramagnetic properties possess a number of advantages, in particular:
- the particles have virtually zero residual magnetization, i.e., after the external magnetic field has been removed (transfer from a magnetic stand to a usual stand), they will not agglutinate and can be easily resuspended.
- the particles are chemically inert and can be stored for a long time in aqueous solutions, do not inhibit enzymatic reactions and can be used in both in vitro and in vivo experiments without undesirable consequences.
- the particles offer many possibilities for the automatization of processes for the isolation of nucleic acids, proteins and cells.
- Processes for obtaining nucleic acids using magnetic particles are known.
- the process for the purification of a substance follows a protocol wherein the material containing the substance and magnetic particles coated or treated with a reagent which binds the particles to the substance are dispensed in a first medium, and upon binding of the substance to the particles a magnetic probe is added to the medium, whereby the particles adhere to the probe, and the probe together with the particles and the substance bound to them is transferred to a second medium, and if desired, separated from the second medium and transferred to a third medium for further working-up.
- One of the main drawbacks of this purification process is the fact that the magnetic probe with the particles adhering thereto must be transferred between the individual media, which highly increases the risk of contaminating the sample to be examined.
- Magnetic granular supports are used which were obtained by suspending the polymer phase containing magnetic colloids of polyvinyl alcohol in an organic phase containing a mixture of specific emulsifiers. In this way, particles having a diameter of 1 to 8 ⁇ that can chemically bind ligands are obtained.
- the supports can be used for the isolation and detection of biomolecules, cells, antibodies and nucleic acids.
- a substance is detected and quantified by the use of magnetic colloidal particles functionalized at the surface with a specific ligand that is to be detected or subject to the quantification of the analyte.
- magnetic colloidal particles functionalized at the surface with a specific ligand that is to be detected or subject to the quantification of the analyte.
- strong magnets based on rare earth elements are used for the magnetic separation.
- the complete collection of the magnetic particles in a magnetic stand usually takes several seconds to several minutes. The separation time depends on the volume and viscosity of the liquid from which the magnetic particles are collected.
- a problem arising when magnetic particles are used is as follows : After the adsorption, i.e., the "adhesion" of the DNA to the surface of the magnetic particles and the collection thereof by a magnetic field on one of the walls of the test tube, the problem is the formation of a "bundle” of magnetic particles, i.e., a "DNA bundle", which complicates the implementation of the further washing steps and prevents the PCR reaction from being performed during a period of time realistic for DNA analysis.
- the effective washing and elution or separation of the DNA from the magnetic particles is performable without transfer of the magnetic probe, which would involve the risk of contamination between the individual volumes, and for ensuring optimum conditions for the fluorescence analysis of the DNA isolated and purified with "PC RealTime" type equipment, and thus for the automatization of the whole DNA analysis cycle.
- partial defragmentation of the DNA molecules is achieved by compensating for any inhomogeneities of the concentration of magnetic particles jammed, by a strong inhomogeneous magnetic field, between the interior surface of the test tube and the magnetic probe rotating about its axis.
- the rotation of the magnetic probe, which is simultaneously pressed against the interior wall of the test tube, is caused by the rotating super paramagnetic (e.g. 1.2-1.3 T) beads of the magnetic stand.
- the magnetic particles, i.e., the "entangled” DNA form a "bundle", which is a very elastic porous medium of high tear strength, which was the major obstacle in the use of the standard method for isolating DNA using magnetic particles and a magnetic field.
- a positive result i.e., the production of a homogeneous solution of the magnetic particles with the DNA adhering thereto, was obtained only by applying the principle of compensating and leveling microinhomogeneities jammed between the two surfaces.
- the microinhomogeneities with the magnetic particles i.e., the "agglomerates" are attracted into the range of a strong magnetic field and at the same time pressed against the walls of the test tube. This is done in a standard magnetic stand with a stationary magnetic field.
- the magnets for the stand we used super paramagnetic beads of Nd-Fe-B having a diameter of 5 mm (B reS iduai ⁇ 1-2- 1.3 T). They were positioned on the outside of the test tube and were free to rotate about any axis.
- the second surface causing the pressing effect is the magnetic probe introduced into the test tube, i.e., a small cylinder with a diameter of 1.5-2.0 mm and a length of 6- 8 mm that is magnetized transversely to the cylinder axis (in parallel with the test tube axis) and has a value of B reS iduai 3 ⁇ 4 0.2-0.3 T on the surface.
- the material for preparing the magnetic cylinder magnetoplast prepared by casting (silicone with an addition of 80% quickly cured magnetic powder made of a neodymium alloy) is used, followed by magnetization by means of an inductor.
- the magnetic cylindrical probe attracted by a strong magnet jammed the "agglomerates” between itself and the interior wall of the test tube.
- the magnetic probe caused the "agglomerates” of the magnetic particles of the "entangled DNA” to be ground up, which also in part defragments the DNA as seen from a subsequent electrophoresis.
- a suspension of magnetic particles with DNA adsorbed thereto is formed.
- Sixteen test tubes with magnetic cylindrical disposable probes were uniformly arranged on the inside at the circumference of the magnetic stand.
- Fig. 1 shows a model of the device without test tubes.
- the rotation of the eight super paramagnetic beads of the stand was brought about by generating an induction vector of the magnetic field in the plane of the circumference of their arrangement that rotates within the horizontal plane.
- the generation of a magnetic field rotating at a frequency of 10 to 30 Hz was effected by the rotation in the radial plane of a bar magnet arranged along the diameter of the circumference of the test tubes.
- Fig. 2 which shows the model from underneath, shows the arrangement of the bar magnet that generates the rotating magnetic field.
- An electric motor supplied with power by batteries (3-6 V) and having a rotation frequency of 30- 50 Hz served as a drive.
- the cavities in the stand for the test tubes were surrounded by an elastic heating element (nichrome in a carbon tape, power consumption about 10 W) for heating at 50-60 °C after the third washing step and for the drying (5 minutes) as well as for heating at 60-65 °C (10 minutes) in the elution solution for separating the DNA from the sorbent on the surface of the magnetic particles.
- the elastic carbon heating tape with two nichrome filaments is shown in Fig. 1 and Fig. 2.
- the last step of the sample processing is the collection of the magnetic particles on the test tube wall and on the magnetic probe.
- the isolated and purified DNA will then remain dissolved.
- the DNA is isolated from blood samples using a standard reagent kit. For a 1.5 ml test tube, the following steps apply:
- test tubes For isolating the DNA from blood cells, sixteen 1.5 ml test tubes were arranged in the model of the device. One test tube served to survey the temperature conditions on steps 4 and 5 of the sample processing. For this purpose, a digital temperature sensor was inserted into the sixteenth test tube. In the remaining 15 test tubes, the magnetic cylindrical probe was arranged.
- First step After pouring a solution containing 50 ⁇ of blood + 150 ⁇ of lysing solution into the test tube, 5 ⁇ of a standard concentration of magnetic particles was added. By switching on a rotating magnetic field for 5 to 10 seconds, the rotation of the magnetic probe caused a uniform distribution of the magnetic particles in the solution, wherein optimum conditions for the adsorption of the DNA to their surface were achieved. As experiments have shown, the rotation frequency of the magnetic probe must not exceed 50 Hz, because otherwise the solution would foam up and spray onto the test tube walls.
- the super paramagnetic beads of the stand then collected the magnetic particles at the wall of the test tube at a level of about 100 ⁇ .
- the magnetic cylindrical probe was also pressed against the test tube wall. Part of the magnetic particles settled on the surface of the magnetic probe. The drifting of the magnetic particles from the solution and the settling thereof on the test tube wall and the probe surface took about 1 minute. Thereafter, the liquid phase was removed from the test tube using a usual pipette with a disposable spout.
- Second step After pouring 400 ⁇ of washing solution No. 1 into the test tube, the model of the device was switched on for about 1 minute.
- the rotating magnetic probe which was pressed against the test tube wall by the super paramagnetic beads of the stand, ground up any inhomogeneities contained in the magnetic particles at the interior wall of the test tube to produce a suspension of magnetic particles.
- the microturbulent rotational movement of the liquid in the test tube favored a thorough washing of the DNA.
- the super paramagnetic beads of the stand collected the magnetic particles at the test tube wall at a level of about 100 ⁇ .
- the cylindrical magnetic probe was also pressed against the test tube wall. Part of the magnetic particles settled on the surface of the magnetic probe. The drifting of the magnetic particles from the solution and the settling thereof on the test tube wall and the probe surface took about 1 minute.
- the liquid phase was removed from the test tube using a conventional pipette with a disposable spout.
- Third step After pouring 200 ⁇ of washing solution No. 2 into the test tube, the same procedure as above was applied.
- Fourth step After pouring 200 ⁇ of washing solution No. 3 into the test tube, the same procedure as above was applied.
- the contents of the test tube had to be dried for 5 minutes at a temperature of 50-65 °C.
- the elastic heating element that surrounded all the 16 test tubes at the positions where they were fitted into the stand was turned on.
- the heating element was supplied with power by a traditional type HY3005C power source with a voltage of about 15 V.
- the temperature monitoring was effected by means of a digital temperature sensor arranged in the sixteenth test tube. The drying process had to be performed thoroughly, since the washing solution No. 3 blocked the reaction of DNA amplification.
- the magnetic particles were collected for one minute on the side walls of the test tube and on the disposable magnetic probe under the action of the inhomogeneous magnetic field of the beads.
- the purified DNA remained in the solution and was ready for further analysis.
- amplification reactions were performed with samples of all kinds.
- the amplification was effected by means of a type DT-96 detection amplificator (registration certificate of the Federal Regulatory Agency in the area of public health and social development No. FSR 2007/01250 of November 20, 2007).
- the results of the amplification performed are shown in Fig. 6.
- the identification number of the cycle for the beginning of the reaction is 27 in both cases.
- the degree of defragmentation of the DNA isolated by means of the model of the device can be established by means of the electrophorogram shown in Fig. 7.
- Fig. 6 shows the results of a comparison of the qualitative PCR analysis of the DNA using the conventional manual method of DNA isolation with the method using the model of the device for sample processing.
- the coincidence of the upper curves demonstrates the high performance of the method of the invention.
- the two curves shifted to a higher number of PCR cycles (x-axis: No of cycles) have been prepared conventionally.
- Fig. 7 shows the results of a comparison of the qualitative PCR analysis of the DNA obtained by conventional sample processing on the one hand with the PCR analysis of the DNA obtained by the process of homogenization using the model of the device for sample processing.
- the results of the electrophoresis show some defragmentation of the DNA isolated using the model of the device (see the first 6 columns) as compared to the conventional manual method (see columns 7 and 8).
- FIGs. 8 to 11 schematically show diverse embodiments of the present invention and explain once again the concept and major features of the invention.
- a permanent or electromagnetic magnet 24 rotates outside a container 10 which includes a magnetic homogenizing element 36 which is pressed against a sample 14 which in this embodiment includes magnetic particles.
- the sample 14 is a magnetic particle agglomerate to be homogenized.
- the homogenizing element 36 is also rotated under the influence of the rotating magnetic field of magnet 24. Accordingly, the homogenizing element 36 which can be a magnetic pistil rolls and presses against the sample 14.
- FIG. 9 an embodiment is shown in which the container 10 is moved linearly along a plurality of magnets 24 oriented differently so that the magnetic field lines penetrate through the container 10 at the side of the sample and the magnetic homogenizing element in different directions. This results in a magnetic coupling of the magnet homogenizing element 36 and the magnets 24 which in turn results in the magnetic homogenizing element 36 being rotated and pressed against the sample 14.
- a rotor comprising a plurality of containers 10 along its periphery. Outside of the rotor there are arranged a plurality of magnets 24 oriented the same, i.e. with parallel north-south-pole orientations. This results in different local magnet coupling effects between the magnets 24 and the homogenizing elements 36 within the containers 10 as the containers are moved rotationally along the individual magnets 24. Again this results in the magnetic homogenizing elements 36 being rotated and pressed against the samples 14 in the containers 10.
- the samples to be homogenized extends along the whole circumferential wall of the containers 10 or at least along portions of the container walls 10.
- Fig. 11 an embodiment is shown in which the rotor according to Fig. 10 is rotated in a homogeneous magnetic field generated externally of the rotor.
- the magnetic coupling of the individual magnetic homogenizing elements 36 and the field lines of the external homogeneous magnetic field results in the same movement of the magnetic homogenizing elements within the containers 10 and along the container walls where the particle agglomerates to be homogenized are adhered.
- FIG. 12 shows another example of a rotating magnetic field generating means having multiple permanent magnets.
- Several containers are arranged around the rotor and include magnetic pistils which under the influence of the rotating permanent magnets rotate against and press against the inner surfaces of the container walls at sites of the particle agglomerates located opposite to the rotor so as to be arranged as close as possible to the rotor of the magnetic field generating means.
- the invention can also be used in a method for mechanical homogenization (including, if desired, decomposition, grinding) of a heterogeneous magnetic or other medium, particularly of magnetic particles, on which a lysate of biological tissue is absorbed, characterized in that
- the heterogeneous (magnetic) medium represents a heterogeneity of (magnetic) particles which is concentrated and is held on the wall of the test vessel (container), i.e. is focused at a specific (fixed) point or is arranged along the wall of the container;
- the homogenizing element rotating about its own axis, is consistently pressed and held against the (magnetic) particles at the special (fixed) point of or along the wall of the container; and 3. for achieving the objects mentioned under 1. and 2. (target homogenization of the lysate), a consistently large gradient of a magnetic field is built up in the fixed point on the wall of the container or along the wall of the container when the same is moved, the vector of the gradient rotating about the axis of the homogenizing element and the axis of the container.
- the invention can be used in a method for disruption of (magnetic or other) particle agglomerates, characterized in that
- the pressing of the pistil onto the surface of the container and the concentration of the (magnetic) particles at a specific point is effected by a magnetic field
- the rotating of the pistil is effected by the rotation of the vector of the magnetic field or by changing the movement vector of the container and pistil within the magnetic field.
- the invention can be used in a method of disruption of (magnetic or other) particle agglomerates, comprising the effects of:
- agglomerate disruption is the result of grinding by rotating a magnetic pistil (magnetic homogenizing element) against the container wall ; and pressing the magnetic pistil against the container wall and the (magnetic) particle agglomerates placed between the magnetic pistil and a container wall being a simultaneous result of a magnetic field;
- magnetic pistil rotation is the result of magnetic field vector movement or container moving vector movement.
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Abstract
The present invention comprises a method for homogenizing, by mechanical action, a sample in a container having a container wall with the sample adhered at a site of the container wall, comprising the steps of placing a magnetic homogenizing element (36) in the container (10), the magnetic homogenizing element (36) having an axis, and subjecting the container (10) to a magnetic field (30) having a direction which is time-variant, wherein the magnetic homogenizing element (36), under the influence of the time-variant magnetic field (30), is rotated around its axis as well as is pressed against an area of the container wall (20) comprising the site (18) where the sample (14) adheres at the container wall (20) thereby homogenizing the sample (14).
Description
TITLE
Magnetic Tissue Homogenizing BACKGROUND OF THE INVENTION
Field of the invention
The present invention relates to a method and device for homogenizing by mechanical action, a sample in a container having a container wall with the sample adhered at a site of the container wall.
Description of the prior art
Sample preparation plays a crucial role in particular in preparing samples for sensitive diagnostic analyses. For example, nucleic acids for use in diagnostics often have to be isolated from various tissues. The isolation is frequently followed by amplification reactions, such as the so-called polymerase chain reaction (PCR). It is preferred that the methods for isolation and in particular also the initial step of sampling from tissue can be automated. For example, a container comprising a sample is introduced in a centrifuge, wherein, due to the centrifugal forces action on the sample, a solid fraction of the sample is adhered at a site of the container wall. This solid fraction of the sample has to be treated further in accordance with procedures known in the art. Up to now, one of the initial steps for obtaining nucleic acids is work-up of tissue for treating disrupted tissues or tissue cells by a mechanical and/or chemical treatment for example by enzymes such as proteinases. Then the nucleic acid e. g. genomic DNA is adsorbed on carriers such as e.g. magnetic beads. After washing steps often a rigid solid body remains, from which the DNA can often only be removed in a cumbersome way.
The quality of the isolation of nucleic acids for PCR is often determined by the skill of the technician and thus not reproducible when changing from one laboratory to another. It is basically known to provide sample preparation by means of steering a sample within a liquid. For these purposes, it is also known to use magnetic steering methods and apparatus. One example of such a steering apparatus is disclosed in WO-A-2004/004874. However, this known steering apparatus cannot be used e.g. for disintegrating or grinding a sample adhered to a container wall and to be dissolved in a liquid.
The same is true for JP-A-2008 136945, JP-A-2006 320888, US-A- 2004/053319, and US-A-2002/119200. In each of these documents a magnetic grinding element is subjected to a discontinuous magnetic field resulting in impacting the grinding element onto a sample.
An object of the present invention is to provide a method which improves sample preparation . SUMMARY OF THE INVENTION
According to one aspect of the present invention, there is provided a method for homogenizing, by mechanically action, a sample in a container, wherein the container comprises a container wall with the sample adhered at a site of a container wall, and wherein the method comprises the steps of
placing a magnetic homogenizing element in the container, the magnetic homogenizing element having an axis, and
subjecting the container to a magnetic field having a direction which is time-variant,
- wherein the magnetic homogenizing element, under the influence of the time-variant magnetic field, is rotated around its axis as well as is press
against an area of the container wall comprising the site where the sample adheres at the container wall thereby homogenizing the sample.
Moreover, in a further aspect of the present invention, there is provided a device for grinding, by mechanical action, a sample in a container, comprising a support for supporting the container,
a magnetic field generating means for creating a magnetic field having a direction which is time-variant, with the magnetic field extending through the container, and
- a magnetic homogenizing element for placing into the container, the magnetic homogenizing element having a axis,
wherein the magnetic homogenizing element, under the influence of the changing magnetic field, is capable of being rotated around its axis and is pressed against the sample so as to mechanically interact with the sample for homogenizing the same.
One of the main features of the present invention is the use of a time-variant magnetic field and at least one magnetic homogenizing element subjected to the magnetic field. Since the magnetic field is time-variant (in its direction and optionally in its magnetic force distribution), the magnetic homogenizing element is moved within the container in a plurality of directions in space and, moreover, is rotated, wherein both movements are highly inhomogeneous and irregular. This effect can be used according to the invention by impinging on the sample for homogenizing the same.
In the context of the present invention, homogenizing means the result of each kind of mechanical action of the homogenizing element on the sample. Together with homogenizing, the sample can also be subjected to a grinding process meaning crushing, fragmenting, comminuting, breaking, disintegrating, mincing, smashing or the like.
For generating the magnetic field having a time-variant direction and orientation and, optionally, a time-variant magnetic force distribution, a magnetic field generating means is used which comprises a permanent magnet or an electromagnet both provided with a north pole region and a south pole region. When using a permanent magnet, this magnet preferably is formed of an NbFeB alloy. In case of providing an electromagnet, the magnetic field generating means further comprises a control unit so as to control the current through the electromagnet for generating a magnetic field having a timed-variant direction/orientation and, optionally, a time-variant magnet force distribution.
Basically, the homogenizing element may have an arbitrary shape. However, experiments have shown that forming the homogenizing element as a substantially elongated body is preferred for the homogenizing process. In case of a substantially elongated homogenizing element, the same is divided along its longitudinal direction into a north pole region and a south pole region wherein each of these regions extend along a lateral side of the substantially elongated body. Basically, the shape of the container within which the at least one homogenizing element is arranged is not relevant for the invention. However, substantially cylindrical containers or other test tubes are preferred experiments carried out in which the container was an Eppendorf test tube having a substantially conically-shaped bottom. In such a container (either substantially cylindrical and, optionally, provided with a substantially conically- shaped bottom) it is preferred if the homogenizing element is a substantially elongated body oriented in a substantially upright direction within the container so as to impinge onto the inner side wall of the container if the homogenizing element is subjected to the time-variant magnetic field.
The method and device according to the invention can be applied to a plurality of containers positioned in a rack and arranged in columns and rows of a two-
dimensional area or arranged along a circle of an annular rack, wherein at least one homogenizing element is arranged in each container.
The present invention can be used for e.g. dissolving samples of any kind in a liquid. For example, the sample can be tissue of various origins such as plant, animal or human tissue and/or wherein the sample comprises biopolymers such as proteins, carbohydrates, lipids, nucleic acids, in particular DNA, RNA, and/or wherein the sample is a lysate from cells prepared for the isolation of nucleic acids, in particular genomic DNA.
The term "time-invariant magnetic field" means an (external) local magnetic field or magnetic field area at the site of the magnetic homogenizing element which the magnetic homogenizing element is subjected to wherein the magnetic coupling of the local magnetic field to the magnetic homogenizing element is changing i.e. is time-invariant upon relative movement of the container including the magnetic homogenizing element and the magnetic field generating means or movement of the container including the magnetic homogenizing element within an external magnetic field with, upon movement of the container, changing the relative orientation of the magnetic homogenizing element and its north-south-pole orientation and the magnetic field lines i.e. upon movement along a curved movement path in a homogeneous magnetic field having its field lines arranged substantially in parallel, or along any other shaped movement path in a magnetic field having its field lines oriented in different directions. Also, the sample to be homogenized does not have to include magnetic particles agglomerates but can include other particles agglomerates.
BRIEF DESCRIPTION OF THE DRAWINGS A full and enabling disclosure of the present invention, including the best mode thereof, enabling one of ordinary skill in the art to carry out the invention, is set forth in greater detail in the following description, including
reference to the accompanying drawing in which Figs. 1 to 4 schematically show the interaction of a displaceable magnetic field and a magnetic homogenizing element arranged within a test tube for homogenizing a sample adhered at a site of the inner wall of the test tube, and Fig. 5 shows a section of a rack supporting a plurality of test tubes with a magnetic field generating means arranged between the test tubes for generating a time-variant magnetic field subjected to adjacent test tubes. Fig. 6 shows comparative results of qualitative PCR results. Fig . 7 shows an electrophoretic gel of conventionally prepared DNA and the one according to the invention. Figs. 8 to 12 show further embodiments of a homogenizing device in which a container including a sample to be homogenized is moved relative a magnetic field.
DESCRIPTION OF PREFERRED EMBODIMENTS Figs. 1 to 4 show schematically the principles of the present invention. A container 10 comprises a substantially conically-shaped bottom 12 with a sample 14 to be dissolved in a liquid 16 within the container 10 is adhered at a site 18 at the inner side of the container wall 20. A magnetic field generating means 22 is arranged outside of the container 10 and comprises a permanent magnet 24 which is displaceable. The permanent magnet 24 has a north pole region 26 and a south pole region 28 and generates a magnetic field 30 having magnetic field lines 32 extending through the container wall 20 and the sample 14. The permanent magnet 24 in this embodiment is rotatable in the direction of arrow 34. However, in the sense of the invention it would be sufficient if the permanent magnet 24 would oscillate about an oscillation access extending between the north and south pole regions 26 and 28, respectively.
It is important that the magnetic field generating means generates a time- variant changing magnetic field within the container 10. Again, it is to be noted that this can be provided by any kind of movement of the permanent
magnet 24. Also it is to be noted that the permanent magnet 24 could be replaced by an electromagnet.
Within the container 10 is arranged a homogenizing element 36 which in this embodiment comprises an elongated body. The magnetic homogenizing element also comprises a north pole region 38 and a south pole region 40 which under the influence of the magnetic field established by the magnetic field lines 32 is oriented accordingly. Therefore, when changing the magnetic field of the magnetic field generating means 22, the magnetic homogenizing element 36 will be moved by tilting, rocking, turning and the like movements within the container 10 as shown in Figs. 1 to 4. The result of these movements of the magnetic homogenizing element 36 in diverse directions in space and around the longitudinal axis of the magnetic homogenizing element 36 is that the magnetic homogenizing element 36 impinges and acts on the sample 14 for homogenizing the same. This process is very efficient as experiments have shown.
According to Fig. 5, several containers 10 can be supported in a rack 42 wherein within each container 10 a sample 14 and a homogenizing element 36 are arranged. A magnetic field generating means 22 is arranged close to the containers 10 for generating a time-variant magnetic field (with regard to the direction of the magnetic field lines and/or the magnetic force distribution). Under the influence of this time-variant magnetic field, the magnetic homogenizing elements 36 act on the respective sample 14 for homogenizing them.
In one embodiment of the invention it can be used in the field of molecular biology and chemistry and is applied in laboratory diagnostics, in particular for sample preparation for PCR analysis, for the extraction of DNA from biological preparations and for the elimination or neutralization of contaminants to obtain DNA having a purity grade that is suitable for the amplification reaction. The invention relates also to a process for homogenizing concentration as formed
during mixing of a blood sample with magnetic iron oxide nanoparticles coated with Si02 adsorbent in a lysing solution.
The use of magnetic particles is not fundamentally different from the use of other kinds of sorbents (latexes, polymer sorbents or glass), but enables the application of magnetic separation instead of centrifugation and filtration. The magnetic particles are based on iron oxide nanoparticles having super paramagnetic properties. Particles based on iron oxide having super paramagnetic properties possess a number of advantages, in particular:
The particles have virtually zero residual magnetization, i.e., after the external magnetic field has been removed (transfer from a magnetic stand to a usual stand), they will not agglutinate and can be easily resuspended.
The particles are chemically inert and can be stored for a long time in aqueous solutions, do not inhibit enzymatic reactions and can be used in both in vitro and in vivo experiments without undesirable consequences.
The particles offer many possibilities for the automatization of processes for the isolation of nucleic acids, proteins and cells.
Processes for obtaining nucleic acids using magnetic particles are known. For example the process for the purification of a substance follows a protocol wherein the material containing the substance and magnetic particles coated or treated with a reagent which binds the particles to the substance are dispensed in a first medium, and upon binding of the substance to the particles a magnetic probe is added to the medium, whereby the particles adhere to the probe, and the probe together with the particles and the substance bound to them is transferred to a second medium, and if desired, separated from the second medium and transferred to a third medium for further working-up.
One of the main drawbacks of this purification process is the fact that the magnetic probe with the particles adhering thereto must be transferred between the individual media, which highly increases the risk of contaminating the sample to be examined.
Another method of prior art uses magnetic polymer particles based on polyvinyl alcohol. Magnetic granular supports are used which were obtained by suspending the polymer phase containing magnetic colloids of polyvinyl alcohol in an organic phase containing a mixture of specific emulsifiers. In this way, particles having a diameter of 1 to 8 μπτι that can chemically bind ligands are obtained. The supports can be used for the isolation and detection of biomolecules, cells, antibodies and nucleic acids.
In a further method of prior art a substance is detected and quantified by the use of magnetic colloidal particles functionalized at the surface with a specific ligand that is to be detected or subject to the quantification of the analyte. For the magnetic separation, strong magnets based on rare earth elements are used. The complete collection of the magnetic particles in a magnetic stand usually takes several seconds to several minutes. The separation time depends on the volume and viscosity of the liquid from which the magnetic particles are collected.
A problem arising when magnetic particles are used is as follows : After the adsorption, i.e., the "adhesion" of the DNA to the surface of the magnetic particles and the collection thereof by a magnetic field on one of the walls of the test tube, the problem is the formation of a "bundle" of magnetic particles, i.e., a "DNA bundle", which complicates the implementation of the further washing steps and prevents the PCR reaction from being performed during a period of time realistic for DNA analysis.
According to another embodiment of the present invention to develop a process for the homogenization, i.e., resuspension, of a solution of DNA adsorbed to magnetic particles by partial defrag mentation thereof and reduction of supercoiling, the effective washing and elution or separation of the DNA from the magnetic particles is performable without transfer of the magnetic probe, which would involve the risk of contamination between the individual volumes, and for ensuring optimum conditions for the fluorescence analysis of the DNA isolated and purified with "PC RealTime" type equipment, and thus for the automatization of the whole DNA analysis cycle.
According to the present invention partial defragmentation of the DNA molecules is achieved by compensating for any inhomogeneities of the concentration of magnetic particles jammed, by a strong inhomogeneous magnetic field, between the interior surface of the test tube and the magnetic probe rotating about its axis. The rotation of the magnetic probe, which is simultaneously pressed against the interior wall of the test tube, is caused by the rotating super paramagnetic (e.g. 1.2-1.3 T) beads of the magnetic stand.
The following example illustrates this embodiment.
To a 1.5 ml test tube as used in a standard procedure of DNA isolation, the following was added :
1. 5 μΙ of the standard concentration of magnetic particles;
2. 50 μΙ of blood for the isolation of the DNA;
3. 150 μΙ of lysing solution;
4. a magnetic cylindrical probe.
The rotation of the magnetic probe about its own axis, which is collinear with the test tube axis and generates microturbulent flows, favored maximum adsorption, i.e., the "sticking" of the DNA to the surface of the magnetic particles.
After the rotational movement of the probe has stopped and the magnetic nanoparticles with the DNA have been collected on the interior surface of the test tube by the strong inhomogeneous magnetic field of the beads of the stand and in part on the surface of the magnetic probe, the magnetic particles, i.e., the "entangled" DNA, form a "bundle", which is a very elastic porous medium of high tear strength, which was the major obstacle in the use of the standard method for isolating DNA using magnetic particles and a magnetic field.
For the elimination (disentanglement) of the agglomeration of the magnetic particles, different attempts have been made, such as repeated pipetting, comminuting by means of the blades of a mixer at a frequency of above about 50 Hz and comminuting by means of larger ferromagnetic particles according to the functional principle of ball mills. However, all these attempts failed to succeed. Thus, it was not possible to perform the further standard steps of sample processing, i.e., the 3 washing steps and the elution of the DNA from the magnetic particles, nor was it possible to perform the isolation of pure DNA samples suitable for PCR analysis.
A positive result, i.e., the production of a homogeneous solution of the magnetic particles with the DNA adhering thereto, was obtained only by applying the principle of compensating and leveling microinhomogeneities jammed between the two surfaces.
The microinhomogeneities with the magnetic particles, i.e., the "agglomerates", are attracted into the range of a strong magnetic field and at the same time pressed against the walls of the test tube. This is done in a standard magnetic stand with a stationary magnetic field. As the magnets for the stand, we used super paramagnetic beads of Nd-Fe-B having a diameter of 5 mm (BreSiduai ~ 1-2- 1.3 T). They were positioned on the outside of the test tube and were free to rotate about any axis. According to the method proposed by us, the second surface causing the pressing effect is the magnetic probe introduced into the test tube, i.e., a small cylinder with a diameter of 1.5-2.0 mm and a length of 6-
8 mm that is magnetized transversely to the cylinder axis (in parallel with the test tube axis) and has a value of BreSiduai ¾ 0.2-0.3 T on the surface. As the material for preparing the magnetic cylinder, magnetoplast prepared by casting (silicone with an addition of 80% quickly cured magnetic powder made of a neodymium alloy) is used, followed by magnetization by means of an inductor.
The magnetic cylindrical probe attracted by a strong magnet jammed the "agglomerates" between itself and the interior wall of the test tube. By rotating about its own axis while remaining pressed against the interior wall of the test tube, the magnetic probe caused the "agglomerates" of the magnetic particles of the "entangled DNA" to be ground up, which also in part defragments the DNA as seen from a subsequent electrophoresis. In the test tube, a suspension of magnetic particles with DNA adsorbed thereto is formed. Sixteen test tubes with magnetic cylindrical disposable probes were uniformly arranged on the inside at the circumference of the magnetic stand. Super paramagnetic (1.2-1.3 T) beads having a diameter of 5 mm were arranged between each of the eight pairs of test tubes in the cylindrical cavities (diameter 5.1 mm) of the stand 8 for a total of eight beads, each of which was free to rotate about any axis. Fig. 1 shows a model of the device without test tubes. The rotation of the eight super paramagnetic beads of the stand was brought about by generating an induction vector of the magnetic field in the plane of the circumference of their arrangement that rotates within the horizontal plane. According to our model, the generation of a magnetic field rotating at a frequency of 10 to 30 Hz was effected by the rotation in the radial plane of a bar magnet arranged along the diameter of the circumference of the test tubes.
Fig. 2, which shows the model from underneath, shows the arrangement of the bar magnet that generates the rotating magnetic field. An electric motor supplied with power by batteries (3-6 V) and having a rotation frequency of 30- 50 Hz served as a drive. The cavities in the stand for the test tubes were
surrounded by an elastic heating element (nichrome in a carbon tape, power consumption about 10 W) for heating at 50-60 °C after the third washing step and for the drying (5 minutes) as well as for heating at 60-65 °C (10 minutes) in the elution solution for separating the DNA from the sorbent on the surface of the magnetic particles. The elastic carbon heating tape with two nichrome filaments is shown in Fig. 1 and Fig. 2.
The last step of the sample processing is the collection of the magnetic particles on the test tube wall and on the magnetic probe. The isolated and purified DNA will then remain dissolved.
Steps of the isolation of the DNA from a biological sample using the invention
The DNA is isolated from blood samples using a standard reagent kit. For a 1.5 ml test tube, the following steps apply:
First step
50 μΙ of blood + 150 μΙ of lysing solution + 5 μΙ of standard concentration of magnetic particles;
- washing;
holding the magnetic particles to the test tube wall;
removing the liquid phase from the test tube.
Second step
- 400 μΙ of standard washing solution No. 1;
washing;
holding the magnetic particles to the test tube wall;
removing the liquid phase from the test tube. Third step
200 μΙ of standard washing solution No. 2;
washing;
holding the magnetic particles to the test tube wall;
removing the liquid phase from the test tube.
Fourth step
- 200 pi of standard washing solution No. 3;
washing;
holding the magnetic particles to the test tube wall;
removing the liquid phase from the test tube;
drying the content of the test tube for 5 minutes at a temperature of 50- 65 °C.
Fifth step
100 pi of standard elution solution for 10 minutes at a temperature of 50- 65 °C;
- holding the magnetic particles to the test tube wall;
collecting the isolated and purified DNA from the test tube for the subsequent analysis.
Concrete Example
For isolating the DNA from blood cells, sixteen 1.5 ml test tubes were arranged in the model of the device. One test tube served to survey the temperature conditions on steps 4 and 5 of the sample processing. For this purpose, a digital temperature sensor was inserted into the sixteenth test tube. In the remaining 15 test tubes, the magnetic cylindrical probe was arranged.
First step: After pouring a solution containing 50 μΙ of blood + 150 μΙ of lysing solution into the test tube, 5 μΙ of a standard concentration of magnetic particles was added. By switching on a rotating magnetic field for 5 to 10 seconds, the rotation of the magnetic probe caused a uniform distribution of the magnetic particles in the solution, wherein optimum conditions for the adsorption of the DNA to their surface were achieved. As experiments have shown, the rotation
frequency of the magnetic probe must not exceed 50 Hz, because otherwise the solution would foam up and spray onto the test tube walls.
After the rotational movement was stopped, the super paramagnetic beads of the stand then collected the magnetic particles at the wall of the test tube at a level of about 100 μΙ. At the same time, the magnetic cylindrical probe was also pressed against the test tube wall. Part of the magnetic particles settled on the surface of the magnetic probe. The drifting of the magnetic particles from the solution and the settling thereof on the test tube wall and the probe surface took about 1 minute. Thereafter, the liquid phase was removed from the test tube using a usual pipette with a disposable spout.
Second step: After pouring 400 μΙ of washing solution No. 1 into the test tube, the model of the device was switched on for about 1 minute. The rotating magnetic probe, which was pressed against the test tube wall by the super paramagnetic beads of the stand, ground up any inhomogeneities contained in the magnetic particles at the interior wall of the test tube to produce a suspension of magnetic particles. The microturbulent rotational movement of the liquid in the test tube favored a thorough washing of the DNA. After the rotational movement was stopped, the super paramagnetic beads of the stand collected the magnetic particles at the test tube wall at a level of about 100 μΙ. At the same time, the cylindrical magnetic probe was also pressed against the test tube wall. Part of the magnetic particles settled on the surface of the magnetic probe. The drifting of the magnetic particles from the solution and the settling thereof on the test tube wall and the probe surface took about 1 minute. Thereafter, the liquid phase was removed from the test tube using a conventional pipette with a disposable spout.
Third step: After pouring 200 μΙ of washing solution No. 2 into the test tube, the same procedure as above was applied.
Fourth step: After pouring 200 μΙ of washing solution No. 3 into the test tube, the same procedure as above was applied. However, after the liquid phase had been drawn off, the contents of the test tube had to be dried for 5 minutes at a temperature of 50-65 °C. For this purpose, the elastic heating element that surrounded all the 16 test tubes at the positions where they were fitted into the stand was turned on. The heating element was supplied with power by a traditional type HY3005C power source with a voltage of about 15 V. The temperature monitoring was effected by means of a digital temperature sensor arranged in the sixteenth test tube. The drying process had to be performed thoroughly, since the washing solution No. 3 blocked the reaction of DNA amplification.
Fifth step: After 100 μΙ of elution solution separating the DNA from the magnetic particles had been poured into the test tube, the elastic heating element was again turned on, and a temperature of 50-65 °C was set in the test tubes for 10 minutes. During this time, the rotation of the magnetic probe was effected periodically for 10 to 15 seconds once a minute. This enabled the homogenization of the solution on the one hand and prevented the DNA molecules from too strongly defragmenting on the other.
After the device had been turned off, the magnetic particles were collected for one minute on the side walls of the test tube and on the disposable magnetic probe under the action of the inhomogeneous magnetic field of the beads. The purified DNA remained in the solution and was ready for further analysis.
For a comparison of the amount of DNA isolated by the conventional method with the corresponding amount obtained using the model of the device, including in different test tubes, amplification reactions were performed with samples of all kinds. The amplification was effected by means of a type DT-96 detection amplificator (registration certificate of the Federal Regulatory Agency in the area of public health and social development No. FSR 2007/01250 of November 20,
2007). The results of the amplification performed are shown in Fig. 6. The identification number of the cycle for the beginning of the reaction is 27 in both cases. The degree of defragmentation of the DNA isolated by means of the model of the device can be established by means of the electrophorogram shown in Fig. 7.
Fig. 6 shows the results of a comparison of the qualitative PCR analysis of the DNA using the conventional manual method of DNA isolation with the method using the model of the device for sample processing. The coincidence of the upper curves demonstrates the high performance of the method of the invention. The two curves shifted to a higher number of PCR cycles (x-axis: No of cycles) have been prepared conventionally. Fig. 7 shows the results of a comparison of the qualitative PCR analysis of the DNA obtained by conventional sample processing on the one hand with the PCR analysis of the DNA obtained by the process of homogenization using the model of the device for sample processing. The results of the electrophoresis show some defragmentation of the DNA isolated using the model of the device (see the first 6 columns) as compared to the conventional manual method (see columns 7 and 8).
Figs. 8 to 11 schematically show diverse embodiments of the present invention and explain once again the concept and major features of the invention.
According to Fig. 8, a permanent or electromagnetic magnet 24 rotates outside a container 10 which includes a magnetic homogenizing element 36 which is pressed against a sample 14 which in this embodiment includes magnetic particles. The sample 14 is a magnetic particle agglomerate to be homogenized. By rotating the permanent or electromagnetic magnet 24, the homogenizing element 36 is also rotated under the influence of the rotating magnetic field of
magnet 24. Accordingly, the homogenizing element 36 which can be a magnetic pistil rolls and presses against the sample 14.
In Fig. 9 an embodiment is shown in which the container 10 is moved linearly along a plurality of magnets 24 oriented differently so that the magnetic field lines penetrate through the container 10 at the side of the sample and the magnetic homogenizing element in different directions. This results in a magnetic coupling of the magnet homogenizing element 36 and the magnets 24 which in turn results in the magnetic homogenizing element 36 being rotated and pressed against the sample 14.
In Fig. 10 a rotor is shown comprising a plurality of containers 10 along its periphery. Outside of the rotor there are arranged a plurality of magnets 24 oriented the same, i.e. with parallel north-south-pole orientations. This results in different local magnet coupling effects between the magnets 24 and the homogenizing elements 36 within the containers 10 as the containers are moved rotationally along the individual magnets 24. Again this results in the magnetic homogenizing elements 36 being rotated and pressed against the samples 14 in the containers 10. In this embodiment the samples to be homogenized extends along the whole circumferential wall of the containers 10 or at least along portions of the container walls 10.
In Fig. 11 an embodiment is shown in which the rotor according to Fig. 10 is rotated in a homogeneous magnetic field generated externally of the rotor. The magnetic coupling of the individual magnetic homogenizing elements 36 and the field lines of the external homogeneous magnetic field results in the same movement of the magnetic homogenizing elements within the containers 10 and along the container walls where the particle agglomerates to be homogenized are adhered.
Finally, Fig. 12 shows another example of a rotating magnetic field generating means having multiple permanent magnets. Several containers are arranged
around the rotor and include magnetic pistils which under the influence of the rotating permanent magnets rotate against and press against the inner surfaces of the container walls at sites of the particle agglomerates located opposite to the rotor so as to be arranged as close as possible to the rotor of the magnetic field generating means.
Although the invention has been described and illustrated with reference to specific illustrative embodiments thereof, it is not intended that the invention be limited to those illustrative embodiments. Those skilled in the art will recognize that variations and modifications can be made without departing from the true scope of the invention as defined by the claims that follow. It is therefore intended to include within the invention all such variations and modifications as fall within the scope of the appended claims and equivalents thereof.
For example, the invention can also be used in a method for mechanical homogenization (including, if desired, decomposition, grinding) of a heterogeneous magnetic or other medium, particularly of magnetic particles, on which a lysate of biological tissue is absorbed, characterized in that
1. the heterogeneous (magnetic) medium represents a heterogeneity of (magnetic) particles which is concentrated and is held on the wall of the test vessel (container), i.e. is focused at a specific (fixed) point or is arranged along the wall of the container;
2. the homogenizing element, rotating about its own axis, is consistently pressed and held against the (magnetic) particles at the special (fixed) point of or along the wall of the container; and 3. for achieving the objects mentioned under 1. and 2. (target homogenization of the lysate), a consistently large gradient of a magnetic field is built up in the fixed point on the wall of the container or along the
wall of the container when the same is moved, the vector of the gradient rotating about the axis of the homogenizing element and the axis of the container. In a further example, the invention can be used in a method for disruption of (magnetic or other) particle agglomerates, characterized in that
the disruption of (magnetic) particle agglomerates is effected in that a rotating magnetic pistil (magnetic homogenizing element) is frictionally moved over the surface of the container mechanically contacting the surface,
the pressing of the pistil onto the surface of the container and the concentration of the (magnetic) particles at a specific point is effected by a magnetic field, and the rotating of the pistil is effected by the rotation of the vector of the magnetic field or by changing the movement vector of the container and pistil within the magnetic field.
In another example, the invention can be used in a method of disruption of (magnetic or other) particle agglomerates, comprising the effects of:
agglomerate disruption is the result of grinding by rotating a magnetic pistil (magnetic homogenizing element) against the container wall ; and pressing the magnetic pistil against the container wall and the (magnetic) particle agglomerates placed between the magnetic pistil and a container wall being a simultaneous result of a magnetic field;
magnetic pistil rotation is the result of magnetic field vector movement or container moving vector movement.
Claims
1. A method for homogenizing, by mechanical action, a sample in a container having a container wall with the sample adhered at a site of the container wall, comprising the steps of
placing a magnetic homogenizing element (36) in the container (10), the magnetic homogenizing element (36) having an axis, and subjecting the container (10) to a magnetic field (30) having a direction which is time-variant,
wherein the magnetic homogenizing element (36), under the influence of the time-variant magnetic field (30), is rotated around its axis as well as is press against an area of the container wall (20) comprising the site (18) where the sample (14) adheres at the container wall (20) thereby homogenizing the sample (14).
2. The method according to claim 1, wherein the magnetic field (30) further comprises a magnetic force distribution which is time-variant.
3. The method according to claim 1 or 2, wherein the magnetic field (30) extends substantially perpendicular to the extension of the container wall (20) at a site (18) of which the sample (14) adheres.
4. The method according to any one of claims 1 to 3, wherein the magnetic field (30) is generated by at least one permanent magnet (24) which is displaced and, accordingly, generates a magnetic field (30) having a time-variant direction and/or a time-variant magnetic force distribution.
5. The method according to claim 4, wherein the at least one permanent magnet (24) is formed of an NbFeB alloy.
6. The method according to any one of claims 1 to 3, wherein the magnetic field (30) is created by at least one electromagnet controlled so as to generate a magnetic field (30) having a time-variant direction or a time- variant direction as well as time-variant magnetic force distribution.
7. The method according to any one of claims 1 to 6, wherein the magnetic homogenizing element (36) comprises a permanent magnet (24) or an electromagnet having a north pole region (26) and a south pole region (28) located laterally at opposite sides of the axis of the magnetic homogenizing element (36).
8. The method according to any one of claims 1 to 7, wherein the homogenizing element (36) comprises a substantially elongated body.
9. The method according to claims 7 and 8, wherein the substantially elongated body is divided along its longitudinal direction such that the north and south pole regions (26,28) extend at opposite lateral sides of the substantially elongated body along its longitudinal direction.
10. The method according to any one of claims 1 to 9, wherein the container wall (20) is substantially cylindrical.
11. The method according to any one of claims 1 to 10, wherein the container wall (20) comprises a substantially conically-shaped bottom (12).
12. The method according to any one of claims 8 to 11 wherein the substantially elongated body of the magnetic homogenizing element (36) is oriented in a substantially upright direction within the container (10).
13. The method according to any one of claims 1 to 12, wherein the container (10), the magnetic homogenizing element (36) and a magnetic field generating means (22) are arranged relative to each other such that the site (18) of the container wall (20) at which the sample (14) adheres is located between the magnetic field generating means (22) and the magnetic homogenizing element (36).
14. The method according to any one of claims 1 to 13, wherein a plurality of containers (10) are positioned in a rack (42) and are arranged in columns and rows of a two-dimensional area or are arranged along a circle, and wherein at least one homogenizing element is arranged in each container (10).
15. The method according to any one of claims 1 to 14, wherein the container (10) and the magnetic homogenizing element (36) are moved linearly relative to each other along a movement path wherein the magnetic field along the relative movement path is changing and, in particular, is cyclically changing.
16. The method according to any one of claims 1 to 14, wherein the container (10) is, and in particular, a plurality of containers (10) are moved along an arbitrarily shaped movement path within a magnetic field, in particular, a magnetic field, in particular, a homogenous magnetic field, and, in particular, along an endless, cyclically repeated movement path having e.g. an annular shape such as a circular shape or a substantially rectangular shape being curved within the corner areas or having a shape according to the digit "8".
17. The method according to any one of claims 1 to 16, wherein the sample (14) is tissue of various origins such as plant, animal or human tissue and/or wherein the sample (14) comprises biopolymers such as proteins, carbohydrates, lipids, nucleic acids, in particular DNA, RNA, and/or wherein the sample (14) is a lysate from cells prepared for the isolation of nucleic acids, in particular genomic DNA.
18. Device for homogenizing, by mechanical action, a sample in a container, comprising
a support for supporting the container (10),
a magnetic field generating means (22) for creating a magnetic field (30) having a direction which is time-variant, with the magnetic field (30) extending through the container (10), and
a magnetic homogenizing element (36) for placing into the container (10), the magnetic homogenizing element (36) having a axis, wherein the magnetic homogenizing element (36), under the influence of the changing magnetic field, is capable of being rotated around its axis and is pressed against the sample so as to mechanically interact with the sample (14) for homogenizing the same.
19. The device according to claim 18, wherein the magnetic field (30) further comprises a magnetic force distribution which is time-variant.
20. The device according to claim 18 or 19, wherein the magnetic field extends substantially perpendicular to the extension of the container wall (20) at a site (18) of which the sample (14) adheres.
21. The device according to any one of claims 18 to 20, wherein the magnetic field generating means (22) comprises at least one permanent magnet (24) which is displaced and, accordingly, generates a magnetic field (30) having a time-variant direction and/or a time-variant magnetic force distribution.
22. The device according to claim 21, wherein the at least one permanent magnet (24) is formed of an NbFeB alloy.
23. The device according to any one of claims 18 to 20, wherein the magnetic field generating means (22) comprises at least one electromagnet controlled so as to generate a magnetic field (30) having a time-variant direction or a time-variant direction as well as time-variant magnetic force distribution.
24. The device according to any one of claims 18 to 23, wherein the magnetic homogenizing element (36) comprises a permanent magnet (24) or an electromagnet having a north pole region (38) and a south pole region (40) located laterally at opposite sides of the axis of the magnetic homogenizing element (36).
25. The device according to any one of claims 18 to 24, wherein the homogenizing element (36) comprises a substantially elongated body.
26. The device according to claims 24 and 25, wherein the substantially elongated body is divided along its longitudinal direction such that the north and south pole regions (38,40) extend at opposite lateral sides of the substantially elongated body along its longitudinal direction.
27. The device according to any one of claims 18 to 26, wherein the container wall (20) is substantially cylindrical.
28. The device according to any one of claims 18 to 27, wherein the container wall (20) comprises a substantially conically-shaped bottom (12).
29. The device according to any one of claims 25 to 28 wherein the substantially elongated body of the magnetic homogenizing element (36) is oriented in a substantially upright direction within the container (10).
30. The device according to any one of claims 18 to 29, wherein the container (10), the magnetic homogenizing element (36) and the magnetic field generating means (22) are arranged relative to each other such that a site (18) of a container wall (20) at which a sample (14) adheres is located between the magnetic field generating means (22) and the magnetic homogenizing element (36).
The device according to any one of claims 18 to 31, wherein a plurality of containers (10) are positioned in a rack (42) and are arranged in columns and rows of a two-dimensional area or are arranged along a circle, and wherein at least one magnetic homogenizing element (36) is arranged in each container (10) wherein the plurality of containers (10) are movable relative to the magnetic field generating means (22) or within a common magnetic field of the magnetic field generating means (22) with the magnetic field can be homogeneous.
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IBPCT/IB2010/002511 | 2010-10-04 | ||
PCT/IB2010/002511 WO2012046089A1 (en) | 2010-10-04 | 2010-10-04 | Magnetic tissue grinding |
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PCT/IB2011/002360 WO2012046131A1 (en) | 2010-10-04 | 2011-10-04 | Magnetic tissue homogenizing |
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CN109752223A (en) * | 2017-11-06 | 2019-05-14 | 丹阳市宏光机械有限公司 | A kind of pulse homogenizer |
WO2022109623A1 (en) * | 2020-11-23 | 2022-05-27 | Spangler Frank Leo | System and method of nucleic acid extraction |
CN117511740A (en) * | 2024-01-08 | 2024-02-06 | 山东伯桢生物科技有限公司 | Tissue dissociation device and control method for tissue dissociation device |
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