Claims
- 1. A transport unit for transporting hyperpolarized gas products therein, said transport unit comprising:
at least one gas chamber configured to hold a quantity of hyperpolarized gas product therein; and an electromagnet disposed in said transport unit, said electromagnet configured and sized to define a magnetic holding field having at least one region of homogeneity therein, wherein a major portion of each of said at least one gas chamber is sized and configured to reside in said magnetic field homogeneous region.
- 2. A transport unit according to claim 1, further comprising at least one electrical current carrying wire, wherein said at least one electrical wire is configured to generate at least a portion of said magnetic holding field.
- 3. A transport unit according to claim 1, wherein said electromagnet comprises at least one cylindrical solenoid.
- 4. A transport unit according to claim 3, wherein said solenoid comprises a plurality of coil segments thereon.
- 5. A transport unit according to claim 3, said transport unit further comprising a metallic enclosure, wherein said solenoid is positioned in said enclosure such that it extends longitudinally therein.
- 6. A transport unit according to claim 5, wherein said enclosure includes at least one layer of an electrically conducting metal thereon, thereby providing one or more of shielding from external electromagnetic radiation and structural support during transport.
- 7. A transport unit according to claim 5, wherein said enclosure includes at least one layer of magnetically permeable material to provide at least one of additional electromagnetic shielding, DC magnetic shielding, or a flux return.
- 8. A transport unit according to claim 3, further comprising operating circuitry operably associated with said transport unit, said operating circuitry including a direct current power supply operably associated with said solenoid.
- 9. A transport unit according to claim 8, wherein said operating circuitry is configured to direct electrical current to said solenoid to define the magnetic holding field having a field strength corresponding to the amount of current directed to said solenoid.
- 10. A transport unit according to claim 4, wherein said operating circuitry is configured to allow an adjustable amount of current to said solenoid thereby providing an adjustable magnetic holding field strength.
- 11. A transport unit according to claim 3, wherein said solenoid provides a homogeneous magnetic holding field volume defined relative to the center of said solenoid, and wherein said container has a hyperpolarized product holding chamber configured and sized such that said holding chamber is held in said homogeneous field volume.
- 12. A transport unit according to claim 6, wherein said solenoid is disposed in said transport unit such that it longitudinally extends in said enclosure and defines a magnetic holding field which is substantially aligned with the earth's magnetic field.
- 13. A transport unit according to claim 4, wherein said plurality of coil segments includes spatially separated first, second, and third coil segments.
- 14. A transport unit according to claim 13, wherein said second coil segment is disposed intermediate said first and third coil segments, and wherein said second coil segment has a lower number of electrical windings per unit length then said first and third coil segments.
- 15. A transport unit according to claim 14, wherein said first and third coil segments extend a first longitudinal distance along said solenoid and said second coil segment extends a second longitudinal distance along said solenoid, and wherein said second distance is greater than said first and third distance.
- 16. A transport unit according to claim 1, wherein said gas chamber includes a gas holding chamber having a major body portion with a first length and a capillary stem with a second length, said capillary stem is in fluid communication with said gas holding chamber and having a capillary length and a capillary diameter, wherein said capillary length is greater than said major body portion length.
- 17. A transport unit according to claim 3, wherein said at least one solenoid and gas chamber is a plurality of corresponding solenoids and gas chambers for transporting multiple doses of hyperpolarized gas products therein.
- 18. A transport unit according to claim 3, wherein said at least one gas chamber is a plurality of separate gas chambers.
- 19. A transport unit according to claim 1, wherein said gas chamber is defined by at least one resilient bag defining at least one expandable gas holding chamber.
- 20. A transport unit according to claim 19, wherein said at least one gas chamber is a plurality of gas chambers defined by a plurality of resilient bags for transporting multiple separate doses of hyperpolarized products therein.
- 21. A transport unit according to claim 20, further comprising a tray for holding said plurality of bags, said tray configured and sized to reside within said magnetic field generator.
- 22. A solenoid for providing a shield for hyperpolarized gases to protect said gases from stray magnetic field gradients to minimize the depolarization affects associated therewith, comprising:
a cylindrical body; a first coil segment having a first coil length and a first number of windings disposed on said cylindrical body; a second coil segment having a second coil length and a second number of windings disposed on said cylindrical body; and a third coil segment having a third coil length and a third number of windings disposed on said cylindrical body, wherein said first, second, and third coil segments are spatially separated and positioned on said cylindrical body such that said second coil segment is intermediate said first and third coil segments.
- 23. A solenoid according to claim 22, wherein said second length is greater than said first and third lengths.
- 24. A solenoid according to claim 22, wherein said first and third number of windings per unit length are greater than said second number of windings.
- 25. A hyperpolarized gas product container having a gas holding chamber and a capillary stem, said capillary stem having an inner diameter and length configured and sized such that said capillary stem inhibits the movement of said hyperpolarized gas product from said gas holding chamber.
- 26. A container according to claim 25, wherein said capillary stem length is greater than said gas holding chamber length.
- 27. A container according to claim 25, wherein said container is pressurized to above about 5 atmospheres of pressure, and wherein said hyperpolarized gas product comprises hyperpolarized 3He.
- 28. A method of minimizing relaxation of hyperpolarized noble gases due to external electromagnetic interference or stray magnetic fields, comprising the steps of:
capturing a quantity of hyperpolarized gas in a transport unit comprising a gas chamber and operating circuitry; shifting the resonant frequency of the hyperpolarized noble gas out of the frequency range of predetermined electromagnetic interference during transport; and transporting the captured gas.
- 29. A method according to claim 28, wherein said shifting step shifts the resonant frequency of the hyperpolarized gas to a frequency substantially outside the bandwidth of prevalent time-dependent fields associated with electrically powered equipment.
- 30. A method according to claim 28, wherein said shifting step is performed by providing a substantially static magnetic field proximate to the gas chamber holding the hyperpolarized noble gas with a field strength sufficient to shift the resonant frequency of the hyperpolarized gas a predetermined amount, thereby minimizing the depolarization of the hyperpolarized gas attributed to exposure to electromagnetic fields during transport from a first site to a second site remote from the first site.
- 31. A method according to claim 28, further comprising providing a metal enclosure around the hyperpolarized gas, the enclosure having a predetermined skin depth which is sufficient to substantially block the depolarizing effects of predetermined electromagnetic interference or AC fields.
- 32. A method according to claim 28, wherein said hyperpolarized gas comprises 3He said static magnetic field is at least about 7 gauss.
- 33. A method according to claim 28, wherein said hyperpolarized gas comprises 129Xe and said magnetic field is at least about 20 gauss.
- 34. A method according to claim 28, wherein said static magnetic field is substantially homogeneous about a magnetic holding field region.
- 35. A method according to claim 28, wherein said shifting step is applied by generating an electromagnetic field proximate to the hyperpolarized gas during transport, and wherein said electromagnetic field is adjustable during transport.
- 36. A system of extending the polarization lifetime of hyperpolarized gas during transport, comprising the steps of:
introducing a quantity of hyperpolarized gas product into a sealable gas chamber at a production site; capturing a quantity of hyperpolarized gas product in the gas chamber; generating a magnetic holding field from a portable transport unit, thereby defining a substantially homogeneous magnetic holding region therein; positioning a major portion of the gas chamber within the homogeneous holding region; transporting the captured hyperpolarized gas in the gas chamber; and shielding the hyperpolarized gas product to minimize the depolarizing effects of external magnetic fields during said transporting step such that the hyperpolarized gas has a clinically useful polarization level at a site remote from the production site.
- 37. A hyperpolarized gas protection system according to claim 36, wherein said transport unit comprises a metallic enclosure, and wherein said step of shielding is performed by positioning said gas chamber in the metallic enclosure and electrically activating a solenoid disposed in the metallic enclosure.
- 38. A hyperpolarized gas protection system according to claim 36, wherein said shielding step comprises shifting the normal resonant frequency of the hyperpolarized gas outside a predetermined frequency range.
- 39. A hyperpolarized gas protection system according to claim 36, wherein the transport unit is configured to hold a plurality of separate gas chambers therein.
- 40. A method according to claim 36, wherein the transporting step is performed by transporting the gas chamber to a second site remote from the production site.
- 41. A method according to claim 40, wherein the gas chamber is configured as a multi-dose container, and further comprising the step of distributing the transported hyperpolarized gas in the multi-dose container at the second site into a plurality of single-dose containers to provide a suitable amount of hyperpolarized gas product therein.
- 42. A method according to claim 41, further comprising the steps of transporting said plurality of said single dose containers to a third site remote from the second site;
administering the hyperpolarized product held in at least one of said single dose containers to a patient; and obtaining an MR imaging or spectroscopy signal associated with same.
- 43. A method for distributing hyperpolarized noble gas, comprising the steps of:
polarizing noble gas at a polarization site; capturing a quantity of polarized gas in a multi-dose container, the quantity of hyperpolarized gas being sufficient to provide a plurality of doses of a hyperpolarized product; positioning the first multi-dose container within a portable transport unit, the transport unit configured to provide a homogeneous magnetic field proximate to a major portion of the multi-dose container held therein; transporting the transport unit with the multi-dose container to a second site remote from the polarization site; and distributing the hyperpolarized gas held in the multi-dose container into multiple separate second containers at the second site.
- 44. A method according to claim 43, wherein said transporting step comprises shielding said hyperpolarized gas by activating an electromagnet in said portable transport unit.
- 45. A method according to claim 43, further comprising the steps of sub-dividing the hyperpolarized gas in the first multi-dose container at the second site; and processing the sub-divided gas into at least one desired formulation to form a hyperpolarized pharmaceutical product suitable for in vivo administration, the processing step being performed prior to said distributing step.
- 46. A method according to claim 45, further comprising the steps of:
positioning at least one of the multiple separate second containers with the hyperpolarized gas product therein into a second transport unit, the second transport unit being configured to provide a region of homogeneity therefor; and transporting the second transport unit with the at least one multiple separate second container to a third site.
- 47. A method according to claim 46, wherein at least one of the multiple separate second containers comprises a patient dose sized resilient bag.
- 48. A method according to claim 47, further comprising the steps of:
administering said hyperpolarized pharmaceutical product in said second container to a patient; and obtaining clinically useful data associated with the administered hyperpolarized product via one or more of an Magnetic Resonance Imaging or Spectroscopy procedures.
- 49. A method according to claim 45, further comprising the steps of:
positioning a plurality of patient-sized bags filled with the hyperpolarized pharmaceutical product in said second transport unit; and transporting the plurality of patient sized bags to a third site remote from the second site.
- 50. A method according to claim 43, wherein the hyperpolarized gas comprises 3He, and wherein the multi-bolus container is used to polarize a quantity of noble gas therein during said polarizing step at the polarization site.
- 51. A portable transporter for transporting or storing a quantity of hyperpolarized gas product, comprising:
an enclosure having at least one wall with a skin depth of a conductive shielding material configured to provide a shield for a quantity of hyperpolarized gas from externally generated electromagnetic interference during transport from a polarization site to a use site, said enclosure defining a holding volume therebetween; at least one hyperpolarized gas container positioned in said enclosure, said gas container having a major gas holding volume portion, and a magnetic field source positioned in said enclosure, said magnetic field source configured to provide a region of homogeneity proximate to said hyperpolarized gas container; wherein the holding volume is sized and configured to hold said hyperpolarized gas container such that the major volume of said hyperpolarized gas container is spatially separated a predetermined distance from adjacent portions of said at least one wall, and wherein said predetermined distance is sufficient to increase the shielding effectiveness of said enclosure.
- 52. A portable transporter according to claim 51, wherein said at least one wall comprises a pair of opposing longitudinally extending walls.
- 53. A portable transport unit according to claim 51, wherein said magnetic field source is a solenoid.
- 54. A portable transport unit according to claim 51, wherein said predetermined separation distance is at least about 2.0 inches.
- 55. A portable transport unit according to claim 53, wherein said solenoid comprises a conductive material inner surface configured to provide shielding.
- 56. A portable transport unit according to claim 51, wherein said at least one gas container is a plurality of gas containers.
- 57. A portable transport unit according to claim 51, wherein said at least one gas container comprises a container which is also configured as an optical pumping cell for the hyperpolarized gas held therein at a polarization site.
- 58. A portable transport unit according to claim 51, wherein said predetermined separation distance provides a separation ratio of less than about 0.60, the separation ratio being mathematically expressed by the ratio of (a) the linear lateral half-width of the major volume portion of said gas container to (b) the linear minimum separation distance of said at least one wall.
- 59. A portable transport unit according to claim 51, wherein said magnetic field source is a plurality of electromagnetic field sources, at least one each for each of said at least one containers held in said enclosure.
- 60. A portable transport unit according to claim 51, wherein said at least one container comprises a capillary stem.
RELATED APPLICATIONS
[0001] This application claims the benefit of priority from Provisional Application No. 60/089,692, filed Jun. 17, 1998, entitled “Containers for Hyperpolarized Gases and Associated Methods” and Provisional Application No. 60/121,315, filed Feb. 23, 1999, entitled “Hyperpolarized Gas Containers, Solenoids, and Transport and Storage Devices and Associated Transport and Storage Methods.” The contents of these applications are hereby incorporated by reference as if recited in full herein.
Government Interests
[0002] This invention was made with Government support under National Institute of Health Grant No. R43HL62756-01. The United States Government has certain rights in this invention.
Provisional Applications (2)
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Number |
Date |
Country |
|
60089692 |
Jun 1998 |
US |
|
60121315 |
Feb 1999 |
US |
Divisions (1)
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Number |
Date |
Country |
Parent |
09333571 |
Jun 1999 |
US |
Child |
10192359 |
Jul 2002 |
US |
Continuations (1)
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Number |
Date |
Country |
Parent |
09846720 |
May 2001 |
US |
Child |
10192359 |
Jul 2002 |
US |