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| United States Patent | 4963236 |
| Link to this page | http://www.wikipatents.com/4963236.html |
| Inventor(s) | Rodkey; L. Scott (Houston, TX);
Huff; G. David (Houston, TX) |
| Abstract | The present invention includes novel apparatus and methods for isoelectric
focusing of amphoteric substances within fluids containing carrier
ampholytes. The present invention utilizes multichannel recycling
isoelectric focusing techniques which eliminate mixing of fluid which
passes through the isoelectric focusing cell with the original crude fluid
sample. Mixing is avoided by preferably using a dual reservoir system and
alternating the fluid flow into and out of each reservoir after each pass
through the isoelectric focusing cell. Fluid flow is alternated into and
out of each reservoir of each reservoir pair through use of reservoir
inlet and outlet valves. The reservoir inlet and outlet valves preferably
operate in response to the fluid level within the reservoir supplying
fluid to the isoelectric focusing cell. When the reservoir empties the
corresponding reservoir outlet valve automatically engages to stop fluid
flow from the empty reservoir and to start fluid flow from the full
reservoir. Near instantaneously therewith, the reservoir inlet valve
engages to stop fluid flow into the full reservoir and to start fluid flow
into the empty reservoir.
The isoelectric focusing cell preferably has a plurality of inlet ports and
a plurality of corresponding outlet ports. The inlet and outlet ports
permit fluid to flow into and out of the isoelectric focusing cell along
discrete channels. Each inlet and outlet port is then coupled to a pair of
the alternating reservoirs.
The apparatus within the scope of the present invention preferably includes
a heat exchanger for removing heat generated by the isoelectric focusing
cell. The heat exchanger is preferably coupled directly to the isoelectric
focusing cell thereby permitting greater power input to the focusing cell
which results in rapid focusing of both the carrier ampholytes and the
fluid sample. |
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Title Information  |
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Drawing from US Patent 4963236 |
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Apparatus and methods for isoelectric focusing |
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| Publication Date |
October 16, 1990 |
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| Filing Date |
March 8, 1989 |
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Title Information |
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References |
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Claims |
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What is claimed and desired to be secured by United States Letters Patent
is:
1. An apparatus for isoelectric focusing of biological amphoteric
substances within a fluid containing buffering components capable of
establishing a stable pH gradient in an electric field, the apparatus
comprising:
an isoelectric focusing cell having a plurality of inlet ports and a
plurality of corresponding outlet ports;
a plurality of reservoirs arranged in pairs, each reservoir having a
reservoir entrance to allow fluid flow into the reservoir and a reservoir
exit to allow fluid flow out of the reservoir; each pair of reservoirs
being coupled to a single inlet port of the isoelectric focusing cell and
to the corresponding outlet port of the isoelectric focusing cell;
means for directing fluid flow from each outlet port of the isoelectric
focusing cell to the respective reservoir pair;
means for directing fluid flow from each reservoir pair to the respective
inlet port of the isoelectric focusing cell;
means for alternating the fluid flow into and out of each reservoir of each
reservoir pair such that when fluid flows from a first reservoir towards
the isoelectric focusing cell, fluid flows from the isoelectric focusing
cell towards a second of each reservoir pair such that after the first
reservoir empties, fluid is directed to flow from the second reservoir of
the respective reservoir pair towards the isoelectric focusing cell and
fluid is simultaneously directed to flow into the first reservoir from the
isoelectric focusing cell.
2. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 1, further comprising a heat exchanger for
removing heat generated by the isoelectric focusing cell.
3. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 2, wherein the isoelectric focusing cell
comprises:
means for separating the flow of fluid which enters the isoelectric
focusing cell into a plurality of parallel focusing cell passageways such
that fluid flowing through the inlet ports is channeled to corresponding
outlet ports; and
means for applying an electric potential substantially transverse the
plurality of parallel focusing cell passageways.
4. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 3, wherein the heat exchanger is coupled to
the isoelectric focusing cell.
5. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 3, wherein the heat exchanger is coupled to
the plurality of reservoirs.
6. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 3, further comprising means for sensing the
temperature and pH of the fluid within the isoelectric focusing apparatus.
7. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 6, further comprising computer means for
monitoring and recording data received from the means for sensing the
temperature and pH of the fluid within the isoelectric focusing apparatus.
8. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 7, wherein the means for sensing the
temperature and pH of the fluid is coupled to at least one of the outlet
channels.
9. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 7, wherein the means for sensing the
temperature and pH of the fluid is coupled to at least one of the inlet
channels.
10. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 3, wherein the means for separating the
flow of fluid in the plurality of parallel focusing cell passageways
comprise a ion nonselective permeable screen.
11. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 10, wherein the ion nonselective permeable
screen has a pore size less than about 100 microns.
12. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 11, wherein the ion nonselective permeable
screen comprises nylon.
13. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 11, wherein the ion nonselective permeable
screen comprises teflon.
14. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 3, wherein the means for directing fluid
flow from each outlet port of the isoelectric focusing cell to the
respective reservoir pair comprises biocompatible tubing.
15. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 3, wherein the means for directing fluid
flow from each reservoir pair to the respective inlet port of the
isoelectric focusing cell comprises biocompatible tubing.
16. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 14, wherein the biocompatible tubing
comprises teflon.
17. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 15, wherein the biocompatible tubing
comprises teflon.
18. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim wherein the portion of the isoelectric
focusing cell which contacts the biological amphoteric substances is
constructed of a biocompatible material.
19. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 1, wherein the portion of the plurality of
reservoirs which contacts the biological amphoteric substances is
constructed of a biocompatible material.
20. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim further comprising a multichannel pump for
pumping fluid from each outlet port of the isoelectric focusing cell to
the respective reservoir pair.
21. An apparatus for isoelectric focusing of amphoteric substances within a
fluid containing buffering components capable of establishing a stable pH
gradient in an electric field, the apparatus comprising:
an isoelectric focusing cell having a plurality of inlet ports and
plurality of corresponding outlet ports;
a plurality of reservoirs arranged in pairs, each reservoir having a
reservoir entrance to allow fluid flow into the reservoir and a reservoir
exit to allow fluid flow out of the reservoir, each pair of reservoirs
corresponding to a single inlet port of the isoelectric focusing cell and
a single outlet port of the isoelectric focusing cell;
a plurality of outlet channels, each coupling an outlet port of the
isoelectric focusing cell to the respective reservoir pair;
a plurality of inlet channels, each coupling the outlet opening of each
reservoir pair to the respective inlet port of the isoelectric focusing
cell;
a plurality of reservoir outlet valves coupling the outlet openings of each
pair of reservoirs to the corresponding inlet channel, said outlet valves
controlling fluid flow out of each pair of reservoirs and into the
respective inlet channel, said outlet valves operating independently in
response to the fluid level within each pair of reservoirs, such that as
the first reservoir empties, its corresponding outlet valve closes the
outlet opening of the first reservoir thereby stopping fluid flow from the
first reservoir through the inlet channel and opens the corresponding
outlet opening of the second reservoir, thereby initiating fluid flow from
the second reservoir to the focusing cell;
a plurality of reservoir inlet valves coupling the inlet openings of each
pair of reservoirs to the corresponding outlet channel, said inlet valves
controlling fluid flow into each pair of reservoirs, said inlet valves
operating in harmony with said outlet valves such that as the outlet valve
for each pair of reservoirs switch fluid flow from the first reservoir to
the second reservoir, said inlet valves close the inlet opening into the
second reservoir and to open the inlet opening into the first reservoir;
a multichannel pump for pumping the fluid in said outlet channels; and
a heat exchanger for removing heat generated by the isoelectric focusing
cell.
22. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 21, wherein the isoelectric focusing cell comprises:
means for separating the flow of fluid which enters the isoelectric
focusing cell into a plurality of parallel focusing cell passageways such
that fluid flowing through the inlet ports is channeled to corresponding
outlet ports; and
means for applying an electric potential substantially transverse the
plurality of parallel focusing cell passageways.
23. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, wherein the heat exchanger is coupled to the
isoelectric focusing cell.
24. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, wherein the heat exchanger is coupled to the
plurality of reservoirs.
25. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, further comprising means for sensing the temperature
and pH of the fluid within the isoelectric focusing apparatus.
26. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 25, further comprising computer means for monitoring and
recording data received from the means for sensing the temperature and pH
of the fluid within the isoelectric focusing apparatus.
27. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 25, wherein the means for sensing the temperature and pH
of the fluid is coupled to at least one of the outlet channels.
28. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 25, wherein the means for sensing the
temperature and pH of the fluid is coupled to at least one of the inlet
channels.
29. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 22, wherein the means for separating the
flow of fluid into the plurality of parallel focusing cell passageways
comprise a ion nonselective permeable screen.
30. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, wherein the ion nonselective permeable screen has a
pore size less than about 100 microns.
31. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, wherein the ion nonselective permeable screen
comprises nylon.
32. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, wherein the ion nonselective permeable screen
comprises teflon.
33. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 21, wherein the means for directing fluid flow from each
outlet port of the isoelectric focusing cell to the respective reservoir
pair comprises biocompatible tubing.
34. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 22, wherein the means for directing fluid flow from each
reservoir pair to the respective inlet port of the isoelectric focusing
cell comprises biocompatible tubing.
35. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 33, wherein the biocompatible tubing comprises teflon.
36. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 34, wherein the biocompatible tubing comprises teflon.
37. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 21, wherein the portion of the isoelectric focusing cell
which contacts the amphoteric substances is constructed of a biocompatible
material.
38. An apparatus for isoelectric focusing of amphoteric substances as
defined in claim 21, wherein the portion of the plurality of reservoirs
which contacts the amphoteric substances is constructed of a biocompatible
material.
39. An apparatus for isoelectric focusing of biological amphoteric
substances within a fluid containing buffering components capable of
establishing a stable pH gradient in an electric field, the apparatus
comprising:
an isoelectric focusing cell constructed from a plurality of parallel
focusing cell elements separated by a plurality of focusing cell
separators, each said focusing cell element having a respective inlet port
and a corresponding outlet port, each said focusing cell element having a
fluid passageway therein;
a plurality of reservoirs arranged in pairs, each reservoir having a
reservoir entrance to allow fluid flow into the reservoir and a reservoir
exit to allow fluid flow out of the reservoir, each pair of reservoirs
being coupled to the inlet port of a corresponding focusing cell element
and to the outlet port of the corresponding focusing cell element;
means for directing fluid flow from each outlet port of the focusing cell
elements to the respective reservoir pair;
means for directing fluid flow from each reservoir pair to the respective
inlet ports of the focusing cell elements;
means for alternating the fluid flow into and out of each reservoir of each
reservoir pair such that when fluid flows from a first reservoir towards
the isoelectric focusing cell, fluid flows from the isoelectric focusing
cell towards a second of each reservoir pair such that after the first
reservoir empties, fluid is directed to flow from the second reservoir of
the respective reservoir pair towards the isoelectric focusing cell and
fluid is simultaneously directed to flow into the first reservoir from the
isoelectric focusing cell.
40. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 39, further comprising a heat exchanger for
removing heat generated by the isoelectric focusing cell.
41. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 40, wherein the isoelectric focusing cell
further comprises means for applying an electric potential substantially
transverse the plurality of parallel focusing cell elements.
42. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 41, wherein the heat exchanger is coupled
to the isoelectric focusing cell.
43. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 41, wherein the heat exchanger is coupled
to the plurality of reservoirs.
44. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 41, further comprising means for sensing
the temperature and pH of the fluid within the isoelectric focusing
apparatus.
45. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 44, further comprising computer means for
monitoring and recording data received from the means for sensing the
temperature and pH of the fluid within the isoelectric focusing apparatus.
46. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 45, wherein the means for sensing the
temperature and pH of the fluid is coupled to at least one of the outlet
channels.
47. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 45, wherein the means for sensing the
temperature and pH of the fluid is coupled to at least one of the inlet
channels.
48. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 41, wherein the means for separating the
flow of fluid in the plurality of parallel focusing cell passageways
comprise a ion nonselective permeable screen.
49. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 48, wherein the ion nonselective permeable
screen has a pore size less than about 100 microns.
50. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 49, wherein the ion nonselective permeable
screen comprises nylon.
51. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 49, wherein the ion nonselective permeable
screen comprises teflon.
52. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 41, wherein the means for directing fluid
flow from each outlet port of the isoelectric focusing cell to the
respective reservoir pair comprises biocompatible tubing.
53. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 41, wherein the means for directing fluid
flow from each reservoir pair to the respective inlet port of the
isoelectric focusing cell comprises biocompatible tubing.
54. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 52, wherein the biocompatible tubing
comprises teflon.
55. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 53, wherein the biocompatible tubing
comprises teflon.
56. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 39, wherein the plurality of focusing cell
elements which contact the biological amphoteric substances are
constructed of a biocompatible material.
57. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 39, wherein the plurality of focusing cell
separators which contact the biological amphoteric substances are
constructed of a biocompatible material.
58. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 39, wherein the portion of the plurality of
reservoirs which contacts the biological amphoteric substances is
constructed of a biocompatible material.
59. An apparatus for isoelectric focusing of biological amphoteric
substances as defined in claim 39, further comprising a multichannel pump
for pumping fluid from each outlet port of the isoelectric focusing cell
to the respective reservoir pair.
60. A method for isoelectric focusing of amphoteric substances comprising
the steps of:
passing fluid containing buffering compon | | |
