The present invention generally pertains to mixing the contents of a two-dimensional array of vessels and is particularly directed to mixing such contents by causing magnetic stir elements within the vessels to tumble in response to the rotation of magnetic flux lines.
In a prior art magnetic tumble stirring apparatus, which is described in U.S. Pat. No. 6,176,609 to Cleveland and Markle, a two-dimensional array of vessels which contain magnetic stir elements is disposed above a rotatable permanent magnet that is disposed to have its physical axis of rotation in a horizontal plane and a magnetic-flux axis in a vertical plane. Rotation of the permanent magnet causes the magnetic flux lines emanating from the magnet to rotate through 360 degrees in the vertical plane within the vessels to thereby cause the magnetic stir elements in the vessels to tumble and thereby mix the contents of the vessels.
In prior art systems in which the contents of a two-dimensional array of vessels are mixed by a vortex created by continuous lateral tumbling of a magnetic stir element within each vessel, a magnetic drive that provides magnetic flux lines of varying orientation to thereby cause the tumbling of the stir elements is positioned beneath each vessel. These systems are impractical for stirring the contents of a large array of vessels that are embodied as wells in a microplate.
The present invention provides system for mixing the contents of a two-dimensional array of vessels, wherein each vessel has a vertical axis as defined when the vessel is disposed for the mixing of said contents, the system comprising: means for receiving at least one array of vessels in a disposition for the mixing of said contents; a drive magnet disposed to one side of the receiving means, wherein the drive magnet is adapted for providing magnetic flux lines that can be caused to rotate horizontally through 360 degrees within the received vessels to thereby cause magnetic stir elements in the received vessels to continuously revolve around the vertical axis of the vessel and while so revolving to continuously tumble laterally against the side wall of the vessel; and means for causing the magnetic flux lines to rotate horizontally through 360 degrees within the received vessels; whereby the contents of a said vessel containing a said magnetic stir element are mixed by a vortex created by the continuous lateral tumbling of the stir element against the side wall of the vessel.
The term “lateral” is defined as “of, at, from or toward the side”.
The present invention also provides a method of mixing the contents of a two-dimensional array of vessels, wherein each vessel has a vertical axis as defined when the vessel is disposed for the mixing of said contents, the method comprising the steps of:
(a) receiving at least one array of vessels in a disposition for the mixing of said contents; and
(b) causing magnetic flux lines to rotate horizontally through 360 degrees within the received vessels to thereby cause magnetic stir elements in the received vessels to continuously revolve around the vertical axis of the vessel and while so revolving to continuously tumble laterally against the side wall of the vessel;
whereby the contents of a said vessel containing a said magnetic stir element are mixed by a vortex created by the continuous lateral tumbling of the stir element against the side wall of the vessel.
In contrast lateral tumble stirring against the sidewall of the vessel, as provided by the present invention, the above-described prior art magnetic tumble stirring apparatus causes the stir element to tumble against the bottom of vessel. Tumble stirring against the sidewall of the vessel has the advantage of creating a vortex that results in better mixing of the contents of a tall vessel. In addition, the present invention does not require a magnetic-field axis-of-rotation beneath each vessel for efficient mixing, as does the above-described prior art magnetic tumble stirring apparatus.
Additional features of the present invention are described with reference to the detailed description of the preferred embodiments.
Referring to
The shelf-spacing elements 16 can be so disposed that the space above one of the shelves 14 can be different than the space above another of the shelves 14. In the preferred embodiment, all of the shelf-spacing elements 16 are of the same predetermined height. In alternative embodiments, some of the shelf-spacing elements are of one height and others of the shelf-spacing elements are of one or more different heights.
After the shelves 14 and shelf-spacing elements 16 have been disposed to provide a set of shelves 14 having preferred amounts of space above the respective shelves 14 in order to accommodate the reception of arrays of vessels of different heights, the poles 15 are secured to a transparent top plate 17. The tops of each pole 15 are threaded and nuts 18 are screwed onto the threads to secure the poles 15 to the top plate 17.
The plurality of shelves 14 contain a plurality of array-receiving sites 20 disposed at different heights and at different positions about the axis of rotation of the carousel 13. Each array-receiving site 20 is adapted for receiving a two-dimensional array 21 of vessels 22. Each vessel 22 has a vertical axis as defined when the vessel 22 is disposed for the mixing of its contents.
The vertical physical axis of the drive magnet 12 is aligned with the axis of rotation of the carousel 13 so that the drive magnet 12 is disposed to one side of each of the array-receiving sites 20. In the preferred embodiment the drive magnet 12 is a permanent magnet that is sealed within a cylindrical casing 23, as shown in
The array-receiving sites 20 are vertically extended for receiving a plurality of the arrays 21 at different heights in a direction that is parallel to a vertical physical axis of the drive magnet 12. The array-receiving sites 20 are also horizontally extended about the vertical physical axis of the drive magnet 12 for receiving a plurality of the arrays 21 of vessels 22 at different angular positions at least one of the different heights.
The vertical physical axis of the permanent magnet 12 is elongated to provide a vertically elongated zone of horizontal magnetic flux lines. Such vertically elongated zone approximately coincides with the vertical extension of the vertically extended array-receiving sites 20 to thereby provide the magnetic flux lines in the plurality of arrays 21 of vessels 22 received at the different heights.
The permanent magnet 12 is disposed for providing magnetic flux lines that can be caused to rotate horizontally through 360 degrees within the received vessels when the permanent magnet 12 is rotated about its vertical physical axis to thereby cause magnetic stir elements in the received vessels 22 to continuously revolve around the vertical axis of the vessel 22 and while so revolving to continuously tumble laterally against the side wall of the vessel 22. A motor 24 is coupled to the permanent magnet 12 for so rotating the permanent magnet 12.
In an alternative embodiment (not shown), the drive magnet is not a permanent magnet, but instead is an electromagnet that is disposed in the same position as the drive magnet 12 shown in
In both the permanent-magnet embodiment and the electromagnet embodiment, the contents of the vessels 22 containing a magnetic stir element are mixed by the continuous lateral tumbling of the stir element against the side wall of the vessel 22.
An array 21 of vessels 22 may be inserted into a array-receiving site 20 by a robotic device 26. The carousel 13 is mounted in a chassis 11 for rotation about the vertical physical axis of the drive magnet 12 so that a plurality of arrays 21 of vessels 22 can be received respectively by array-receiving sites 20 at different heights from a predetermined rotational position.
The carousel 13 is rotated independently of the drive magnet 12 by a motor 27 and a gear system 28. In the preferred embodiment, the motor and the gear system 28 are adapted for rotating the carousel 13 from one predetermined rotational position at which the arrays 21 of vessels 22 can be received from the robotic device 26 to another such predetermined rotational position, and for maintaining the carousel 13 in the predetermined rotational position to which the carousel 13 has been rotated when the carousel 13 is not being rotated. In alternative embodiments (not shown) the carousel 13 is rotatable by hand and/or is maintained in the rotational position to which the carousel 13 has been rotated by means other than a motor and/or gear system.
The robotic device 26 includes claws 32 that are disposed for gripping opposite sides of a plate 30 that extends outward at the bottom of the array 21 of vessels 22. At each array-receiving site 20, the shelves 14 include tapered sides 34 to facilitate the insertion of an array 21 of vessels 22 onto a shelf 14 by the robotic device 26 without the claws 32 making contact with the shelf 14.
Different types of suitable magnet stir elements are described in the aforementioned U.S. Pat. No. 6,176,609, the disclosure of which is incorporated herein by reference. Stainless steel magnetic stir elements are preferred for cost reasons. Alternatively, stir elements including permanent magnets may be used.
A magnetic stir element 40 of the type shown in
A magnetic stir element 42 of the type shown in
A magnetic stir element 44 of the type shown in
The position of the stirring vortex is dependent upon the size and shape of the magnetic stir element. The smaller the stir element relative to the inside diameter of the vessel, the more “off-center” the vortex will be towards the side of the vessel closest to the source of the magnetic field. If the stir element is nearly the same size as the inside diameter of the vessel, the vortex will be in the center of the vessel.
A magnetic stir element 44 of the type shown in
When the magnetic stir elements of the type illustrated in
In other various alternative embodiments (not shown):
(a) array-receiving sites are not provided at every angular position at a given height when the array-receiving sites are vertically extended for receiving a plurality of the arrays at different heights and the array-receiving sites are also extended about the vertical physical axis of the drive magnet for receiving a plurality of the arrays of vessels at different angular positions at least one of the different heights;
(b) array-receiving sites are not provided at the same height in all of the vertical extensions of array-receiving sites when the array-receiving sites are vertically extended for receiving a plurality of the arrays at different heights and the array-receiving sites are also extended about the vertical physical axis of the drive magnet for receiving a plurality of the arrays of vessels at different angular positions at least one of the different heights;
(c) the array-receiving sites are not vertically extended for receiving a plurality of the arrays at different heights;
(d) the array-receiving sites are not extended about the vertical physical axis of the drive magnet for receiving a plurality of the arrays of vessels at different angular positions at any given height;
(e) there is only one array-receiving site for receiving an array of vessels, wherein such array-receiving site is disposed to one side of a permanent magnet of the type and disposition shown in
(f) the array-receiving sites are within an assembly that is not rotatable.
In still other embodiments (not shown) the various aspects of the different embodiments described herein are combined with one another to the extent that they are not incompatible with each other.
The advantages specifically stated herein do not necessarily apply to every conceivable embodiment of the present invention. Further, such stated advantages of the present invention are only examples and should not be construed as the only advantages of the present invention. While the above description contains many specificities, these should not be construed as being necessarily required for use of the present invention or as limitations on the scope of the present invention, but rather as examples of the embodiments described herein. Other variations are possible and the scope of the present invention should be determined not by the embodiments described herein but rather by the claims and their legal equivalents.