Osmotic pump with remotely controlled osmotic pressure generation
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61K-009/22
A61K-009/00
A61M-005/142
A61M-005/145
A61M-005/172
A61N-001/08
출원번호
US-0302449
(2005-12-13)
등록번호
US-9028467
(2015-05-12)
발명자
/ 주소
Hood, Leroy E.
Ishikawa, Muriel Y.
Jung, Edward K. Y.
Langer, Robert
Tegreene, Clarence T.
Wood, Jr., Lowell L.
Wood, Victoria Y. H.
출원인 / 주소
The Invention Science Fund I, LLC
대리인 / 주소
Suiter Swantz pc llo
인용정보
피인용 횟수 :
0인용 특허 :
156
초록▼
Embodiments of a system including a remotely controlled osmotic pump device and associated controller are described. Methods of use and control of the device are also disclosed. According to some embodiments, an osmotic pump device is placed in an environment in order to pump a material into the env
Embodiments of a system including a remotely controlled osmotic pump device and associated controller are described. Methods of use and control of the device are also disclosed. According to some embodiments, an osmotic pump device is placed in an environment in order to pump a material into the environment or into an additional fluid handling structure within the osmotic pump device. Exemplary environments include a body of an organism, a body of water, or an enclosed volume of a fluid. In selected embodiments, a magnetic field, an electric field, or electromagnetic control signal may be used.
대표청구항▼
1. An osmotic pump system comprising: a body structure configured for placement in an environment;a delivery reservoir configured to contain a delivery fluid to be delivered into the environment;an osmotic chamber;an osmotic pressure-generating material contained within the osmotic chamber, the gene
1. An osmotic pump system comprising: a body structure configured for placement in an environment;a delivery reservoir configured to contain a delivery fluid to be delivered into the environment;an osmotic chamber;an osmotic pressure-generating material contained within the osmotic chamber, the generation of osmotic pressure by the osmotic pressure-generating material controllable by an electromagnetic field control signal;a pressure-responsive movable barrier separating the osmotic chamber from the delivery reservoir, the pressure-responsive barrier being substantially impermeable to the osmotic pressure-generating material and configured to move in response to a change in pressure in the osmotic chamber to produce a change in at least one of pressure or volume in the delivery reservoir;a semi-permeable membrane separating the osmotic chamber from an osmotic fluid source, the semi-permeable membrane being substantially permeable by fluid from the osmotic fluid source but substantially impermeable to the osmotic pressure-generating material; anda plurality of interaction sites for the osmotic pressure-generating material within the osmotic chamber, the likelihood of interaction of the osmotic pressure-generating material with the interaction sites controllable by the electromagnetic field control signal, wherein interaction of the osmotic pressure-generating material with the interaction sites causes a change in osmotic pressure within the osmotic chamber. 2. The osmotic pump system of claim 1, including a remotely activatable control element responsive to the electromagnetic field control signal to control the generation of osmotic pressure by the osmotic pressure-generating material. 3. The osmotic pump system of claim 1, including a downstream fluid handling structure in fluid communication with the delivery reservoir and configured to receive fluid ejected from the delivery reservoir in response to the change in at least one of pressure or volume in the delivery reservoir. 4. An osmotic pump system, comprising: a body structure configured for placement in an environment;a delivery reservoir configured to contain a delivery fluid to be delivered into the environment;an osmotic chamber;an osmotic pressure-generating material contained within the osmotic chamber, the generation of osmotic pressure by the osmotic pressure-generating material controllable by an electromagnetic field control signal;a pressure-responsive movable barrier separating the osmotic chamber from the delivery reservoir, the pressure-responsive barrier being substantially impermeable to the osmotic pressure-generating material and configured to move in response to a change in pressure in the osmotic chamber to produce a change in at least one of pressure or volume in the delivery reservoir;a semi-permeable membrane separating the osmotic chamber from an osmotic fluid source, the semi-permeable membrane being substantially permeable by fluid from the osmotic fluid source but substantially impermeable to the osmotic pressure-generating material; anda secondary material within the osmotic chamber, the secondary material having at least one characteristic modifiable by the electromagnetic field control signal, wherein the concentration of the osmotic pressure-generating material is modifiable by a change in the at least one characteristic of the secondary material. 5. A remote controller for an osmotic pump device, comprising: an electromagnetic signal generator configured to produce an electromagnetic signal sufficient to activate a remotely activatable control element of an osmotic pump device located in an environment to change a concentration of an osmotic pressure-generating material within an osmotic chamber of the osmotic pump device;an electromagnetic signal transmitter configured to wirelessly transmit the electromagnetic signal to the remotely activatable control element; anda signal input adapted for receiving a feedback signal from the osmotic pump device, wherein the electromagnetic signal is produced based at least in part upon the feedback signal sensed from the osmotic pump device. 6. A remote controller for an osmotic pump device, comprising: an electromagnetic signal generator configured to produce an electromagnetic signal sufficient to activate a remotely activatable control element of an osmotic pump device located in an environment to change a concentration of an osmotic pressure-generating material within an osmotic chamber of the osmotic pump device;an electromagnetic signal transmitter configured to wirelessly transmit the electromagnetic signal to the remotely activatable control element; anda signal input adapted for receiving a feedback signal sensed from the environment, wherein the electromagnetic signal is produced based at least in part upon the feedback signal sensed from the environment. 7. The osmotic pump system of claim 2, wherein the remotely activatable control element includes at least one of a magnetically active material, an electrically active material, a permanently magnetizable material, a ferromagnetic material, a ferrimagnetic material, a ferrous material, a ferric material, a dielectric material, a ferroelectric material, a piezoelectric material, a diamagnetic material, a paramagnetic material, an antiferromagnetic material, a shape memory material, a shape memory polymer, a shape memory metal, a bimetallic structure, a polymer, a ceramic, a metal, a hydrogel, a ferrogel, or a combination of a polymer and a magnetically or electrically active component. 8. The osmotic pump system of claim 2, wherein the remotely activatable control element includes at least one of a heating element, a cooling element, an expanding element, or a contracting element. 9. The osmotic pump system of claim 1, wherein the pressure-responsive movable barrier includes at least one of a flexible membrane or a piston. 10. The osmotic pump system of claim 1, wherein the osmotic pressure-generating material includes at least one of an ionic or non-ionic water-attracting or water absorbing material, a non-volatile water-soluble species, a salt, a sugar, a polysaccharide, a polymer, a hydrogel, an osmoopolymer, a hydrophilic polymer, or an absorbent polymer. 11. The osmotic pump system of claim 1, the osmotic pressure-generating ability of the osmotic pressure-generating material depends on at least one of the solubility of the osmotic pressure-generating material in the osmotic fluid or the concentration of the osmotic pressure-generating material in the osmotic fluid. 12. The osmotic pump system of claim 1, wherein the concentration of the osmotic pressure-generating material in the osmotic fluid is modifiable by a change in solubility of the osmotic pressure-generating material in response to an electromagnetic field control signal, a change in the volume of the osmotic chamber in response to the electromagnetic field control signal, or a change in the osmotic fluid in response to an electromagnetic field control signal. 13. The osmotic pump system of claim 12, including an electromagnetic field activated heating or cooling element configured to change the temperature in the osmotic fluid, wherein the osmotic pressure-generating material has a solubility in the osmotic fluid that changes in response to a change in temperature of the osmotic fluid. 14. The osmotic pump system of claim 13, wherein the electromagnetic field activated heating or cooling element includes a ferrous, ferric, ferromagnetic or dielectric material, or a thermoelectric element. 15. The osmotic pump system of claim 1, including a body structure adapted for positioning in an environment selected from a body of an organism, a body of water, or a contained fluid volume, an industrial fluid volume, an agricultural fluid volume, a swimming pool, an aquarium, a drinking water supply, or an HVAC system cooling water supply. 16. The osmotic pump system of claim 1, wherein at least a portion of the osmotic chamber containing the interaction sites is responsive to an electromagnetic field control signal by a change in the surface area of the portion of the osmotic chamber, the change in surface area modifying at least one of the number of interaction sites or likelihood of interaction of the osmotic pressure-generating material with the interactions sites, wherein the change of surface area is produced by at least one of stretching or unfolding of the portion of the osmotic chamber. 17. The remote controller of claim 5 wherein the electromagnetic signal generator includes at least one of electrical circuitry or a microprocessor. 18. The remote controller of claim 5 wherein the electromagnetic signal is produced based on at least one of a pre-determined activation pattern or a model-based calculation. 19. The remote controller of claim 6, wherein the feedback signal corresponds to at least one of the osmolality or the pH of the environment, the concentration or chemical activity of a chemical in the environment, or a temperature or pressure of the environment. 20. The remote controller of claim 5, wherein the feedback signal corresponds to at least one of the osmolality or the pH within or around the osmotic pump device, the concentration or chemical activity of a chemical within or around the osmotic pump device, a temperature or pressure within or around the osmotic pump device, or the pumping rate of the osmotic pump device. 21. The remote controller of claim 5, wherein the electromagnetic signal has signal characteristics sufficient to produce a change in dimension, temperature, conformation, orientation or position of the remotely activatable control element. 22. The remote controller of claim 5, wherein the electromagnetic signal generator includes at least one electromagnet, electrically-polarizable element, permanent magnet, or electret. 23. The remote controller of claim 5, wherein the electromagnetic signal has signal characteristics sufficient to produce a change in dimension, temperature, shape, volume, surface area or configuration of the remotely activatable control element, the change in dimension, temperature, shape, volume, surface area or configuration of the remotely activatable control element causing a change in the concentration of the osmotic pressure-generating material within the osmotic chamber of the osmotic pump device. 24. The remote controller of claim 5, wherein the electromagnetic signal has signal characteristics sufficient to produce a change in shape in a remotely activatable control element including at least one of a shape memory material, a bimetallic structure, or a polymeric material. 25. The remote controller of claim 5, including an electromagnetic signal generator configured to generate a static or quasi-static electrical field control signal, a static or quasi-static magnetic field control signal, a radio-frequency electromagnetic control signal, a microwave electromagnetic control signal, an infrared electromagnetic control signal, a millimeter wave electromagnetic control signal, an optical electromagnetic control signal, or an ultraviolet electromagnetic control signal sufficient to activate the remotely activatable control element to control the concentration of the osmotic pressure-generating material within the osmotic chamber in a desired manner. 26. An osmotic pump system comprising: a body structure configured for placement in an environment;a delivery reservoir configured to contain a delivery fluid to be delivered into the environment;an osmotic chamber;an osmotic pressure-generating material contained within the osmotic chamber, the generation of osmotic pressure by the osmotic pressure-generating material controllable by an electromagnetic field control signal;a pressure-responsive movable barrier separating the osmotic chamber from the delivery reservoir, the pressure-responsive barrier being substantially impermeable to the osmotic pressure-generating material and configured to move in response to a change in pressure in the osmotic chamber to produce a change in at least one of pressure or volume in the delivery reservoir;a remotely activatable valve element coupled to the delivery reservoir, the remotely activatable valve element responsive to the electromagnetic field control signal to regulate flow of fluid out of delivery reservoir; anda semi-permeable membrane separating the osmotic chamber from an osmotic fluid source, the semi-permeable membrane being substantially permeable by fluid from the osmotic fluid source but substantially impermeable to the osmotic pressure-generating material.
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Hanover Barry K. (Salt Lake City UT) Jacobsen Stephen C. (Salt Lake City UT) Simon Eric M. (Salt Lake City UT) Petelenz Tomasz (Salt Lake City UT) Mladejovsky Michael G. (Murray UT), Implantable drug delivery system with piston actuation.
Ford Alan D. ; Sims Nathaniel M. ; Mandro Marc A., Infusion pump with an electronically loadable drug library and a user interface for loading the library.
Reinicke Robert H. (Mission Viego CA), Injectable infusion pump apparatus for implanting long-term dispensing module and medication in an animal and method the.
Ayer Atul D. (Palo Alto CA) Eckenhoff James B. (Los Altos CA) Wright Jeremy C. (Los Altos CA) Kuczynski Anthony L. (Palo Alto CA), Long-term delivery device including loading dose.
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Folkman Judah (Brookline MA) Langer ; Jr. Robert S. (Somerville MA) Hsieh Dean S. T. (Cambridge MA), Magnetically modulated polymeric drug release system.
Casper Robert A. (Raleigh NC) McCartney Michael L. (Durham NC) Jochem Warren J. (Cary NC) Parr Alan F. (Cary NC), Medical capsule device actuated by radio-frequency (RF) signal.
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Richards, Amy C.; Santini, Jr., John T.; Cima, Michael J.; Langer, Robert S., Microchip devices for delivery of molecules and methods of fabrication thereof.
Santini, Jr., John T.; Hutchinson, Charles E.; Uhland, Scott A.; Cima, Michael J.; Langer, Robert S.; Ausiello, Dennis, Microfabricated devices for the delivery of molecules into a carrier fluid.
Santini, Jr., John T.; Sheppard, Jr., Norman F.; Young, Chung Chang; Langer, Robert S., Microfabricated devices for the storage and selective exposure of chemicals and devices.
Whitehurst, Todd K.; McGivern, James P.; McClure, Kelly H.; Marnfeldt, Goran N.; Thacker, James R., Monitoring, preventing, and treating rejection of transplanted organs.
Jacobsen Stephen C. (Salt Lake City UT) Hanover Barry K. (Salt Lake City UT) Simon Eric M. (Salt Lake City UT) Petelenz Tomasz (Salt Lake City UT) Mladejovsky Michael G. (Murray UT), Multiple vesicle implantable drug delivery system.
Baumann Hans (Bahnhofstrasse 12a 24223 Raisdorf DEX) Otto Karl-Heinz (AmHochbehalter 13 24146 Kiel DEX) Hinrichs Kai-Jurgen (Holtenauer Strasse 116 24118 Kiel DEX) Graczyk Wolfgang (Randersstrasse 2 , Process for the adjustment of a switchable flow limiting apparatus, and an apparatus operating according to the process.
Acton ; III John J. ; Adams Alan D. ; Hermes Jeffrey D. ; Jones A. Brian ; Parsons William Hugh ; Sinclair Peter J., Pseudopeptide lactam inhibitors of peptide binding to MHC class II proteins.
Hood, Leroy E.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Langer, Robert; Tegreene, Clarence T.; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Remote control of substance delivery system.
Hood, Leroy E.; Ishikawa, Muriel Y.; Jung, Edward K. Y.; Langer, Robert; Tegreene, Clarence T.; Wood, Jr., Lowell L.; Wood, Victoria Y. H., Remote controller for in situ reaction device.
John R. Peery ; Keith E. Dionne ; James B. Eckenhoff ; Felix A. Landrau ; Scott D. Lautenbach ; Judy A. Magruder ; Jeremy C. Wright, Sustained delivery of an active agent using an implantable system.
Peery John R. ; Dionne Keith E. ; Eckenhoff James B. ; Landrau Felix A. ; Lautenbach Scott D. ; Magruder Judy A. ; Wright Jeremy C., Sustained delivery of an active agent using an implantable system.
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