Constant ocular pressure active infusion system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61M-031/00
A61M-001/00
출원번호
US-0316851
(1999-05-21)
발명자
/ 주소
Bui,Hai
출원인 / 주소
Buivision
대리인 / 주소
Blakely Sokoloff Taylor &
인용정보
피인용 횟수 :
31인용 특허 :
31
초록▼
An irrigation system for a medical device. The irrigation system may include a pump that can pump irrigation fluid from a reservoir through an irrigation line. The system may further have a controller coupled to the pump and an accumulator pressure sensor that senses the pressure of the irrigation l
An irrigation system for a medical device. The irrigation system may include a pump that can pump irrigation fluid from a reservoir through an irrigation line. The system may further have a controller coupled to the pump and an accumulator pressure sensor that senses the pressure of the irrigation line. The controller can vary the speed of the pump in response to a change in the line pressure to control the irrigation line pressure. Additionally, the controller can monitor the fluidic resistance of the system by determining the pump speed and corresponding flowrate of the pump. The controller can provide one or more safety output signals if the fluidic resistance exceeds a threshold value(s).
대표청구항▼
What is claimed is: 1. An irrigation system for a medical device, comprising: an irrigation line; a valve to control a flow of fluid through said irrigation line; an irrigation reservoir providing fluid to the irrigation line, the irrigation reservoir operating as a first source of fluid for the me
What is claimed is: 1. An irrigation system for a medical device, comprising: an irrigation line; a valve to control a flow of fluid through said irrigation line; an irrigation reservoir providing fluid to the irrigation line, the irrigation reservoir operating as a first source of fluid for the medical device; a pump coupled to said irrigation line; an accumulator operating as a secondary source of fluid for the medical device, said accumulator including a first chamber, a second chamber, and a flexible membrane that separates said first chamber from said second chamber and deflects in response to a change in an amount of fluid pressure in the irrigation line, said first chamber of said accumulator providing a reservoir for pressurized fluid and supplying said pressurized fluid to said irrigation line in response to reduced speed of said pump and without adjustment of said valve; and, a controller including a pressure transducer in fluid communication with said second chamber to detect a change of fluid pressure in said second chamber caused by the deflection of the flexible membrane and to adjust said valve and control a flow rate of fluid passing through said irrigation line to counteract the change in the amount of fluid pressure in the irrigation line by varying a speed of said pump. 2. The irrigation system of claim 1, wherein said controller can determine a flowrate generated by said pump. 3. The irrigation system of claim 2, wherein said controller determines an actual fluidic resistance from the flowrate and provides an output signal if the actual fluidic resistance is greater than a threshold value. 4. The irrigation system of claim 2, wherein said controller determines an actual volume of irrigation fluid pumped by said pump from the flowrate and provides an output signal if the actual volume of irrigation fluid is greater than a threshold value. 5. The irrigation system of claim 1, further comprising a valve coupled to said irrigation line and said controller. 6. The irrigation system of claim 1, wherein said controller activates an indicator to provide a warning to replace said irrigation reservoir. 7. The irrigation system of claim 1, wherein said controller varies said pump speed in response to a variation in the irrigation line pressure sensed by said pressure transducer that rises above a desired range of pressures. 8. A medical system, comprising: an irrigation system that includes an irrigation reservoir storing fluid, an irrigation pump that is coupled to said irrigation reservoir to control an output rate of the fluid from the irrigation reservoir, an irrigation line coupled to said irrigation reservoir, an accumulator providing fluid different than the fluid provided by the irrigation reservoir as a secondary source, said accumulator being directed coupled to said irrigation line and including a first chamber in fluid communication with said irrigation line, a second chamber, and a flexible membrane that separates said first chamber from said second chamber and deflects in response to a change in an amount of fluid pressure in the irrigation line, said first chamber of said accumulator providing a reservoir of pressurized fluid and supplying said pressurized fluid to said irrigation line in response to reduced speed of said pump; and, a controller including a pressure transducer in fluid communication with said second chamber and to control the pressure within said irrigation line through monitoring a change of fluid pressure within said second chamber of said accumulator; and an aspiration system that includes an aspiration pump, an aspiration line coupled to said aspiration pump, and an aspiration pressure sensor that senses a vacuum pressure within said aspiration line. 9. The medical system of claim 8, wherein said controller can determine a flowrate generated by said irrigation pump. 10. The medical system of claim 9, wherein said controller determines an actual fluidic resistance from the flowrate and provides an output signal if the actual fluidic resistance is greater tan a threshold value. 11. The medical system of claim 10, wherein said controller provides an output signal that is used to control power of a medical device that is coupled to said irrigation line and said aspiration line if the actual fluidic resistance is greater than a device threshold value. 12. The medical system of claim 10, wherein said controller changes a speed of said aspiration pump if the actual fluidic resistance is greater than a threshold resistance value. 13. The medical system of claim 9, wherein said controller determines an actual volume of irrigation fluid pumped by said irrigation pump from the flowrate and provides an output signal if the actual volume of irrigation fluid is greater than a threshold value. 14. The medical system of claim 8, wherein said controller maintains an intraocular pressure by varying a speed of said irrigation pump and a flowrate through said irrigation line. 15. The medical system of claim 14, wherein said controller varies said speed of said irrigation pump in response to a variation in fluid pressure in said first chamber of said accumulator as sensed by said pressure transducer. 16. An apparatus comprising: an irrigation pump; an irrigation line controlled in the irrigation pump and providing a first fluid path; a fluid reservoir to supply a fluid to the irrigation line over the first fluid path; a first pressure sensor in fluid communication with the irrigation line; and a first accumulator located between the irrigation line and the first pressure sensor and providing a second fluid path that is separate from the first fluid path and feeds into the first fluid path, the first accumulator including a first chamber in fluid communication with the irrigation line temporarily to provide stored pressurized fluid in addition to the fluid supplied by the fluid reservoir in response to dislodgment of an occlusion of an aspiration line after the occlusion has already caused a substantially reduced speed of the irrigation pump, a second chamber in fluid communication with the first pressure sensor and a flexible membrane which separates the first and the second chamber. 17. The apparatus of claim 16 further comprising: an aspiration line; a second pressure sensor in fluid communication with the aspiration line; an aspiration pump in fluid communication with the aspiration line; and, a controller coupled with the first and the second pressure sensors to sense a differential pressure between the irrigation line and the aspiration line and to vary a speed of the irrigation pump in efforts to maintain a flow rate in the irrigation line substantially in proportion to the flow rate in the aspiration line. 18. The apparatus of claim 17, wherein the controller is further to determine that an occlusion of the aspiration line has occurred if the differential pressure increases. 19. The apparatus of claim 16 wherein the first accumulator is sized to maintain an intraocular pressure of an eye into which the medical device is to be inserted. 20. An irrigation system for a medical device, comprising: a pump; an irrigation line coupled to said pump; a controller that varies a speed of said pump to adjust a flowrate of fluid passing through said irrigation line over a first fluid path; and an accumulator including (i) a first chamber operating as a reservoir to store pressurized fluid separately from fluid passing through said irrigation line, (ii) a second chamber in fluid communication with said controller, and (iii) a flexible membrane that separates said first chamber from said second chamber, said accumulator provides said pressurized fluid from said first chamber to said irrigation line over a second fluid path separate and distinct from the first fluid path, said pressurized fluid being provided in addition to other fluid passing through said irrigation line to maintain intraocular pressure of an eye. 21. The irrigation system of claim 20 further comprising an irrigation reservoir coupled to said irrigation line. 22. The irrigation system of claim 21, wherein said pressurized fluid from said first chamber is provided to said irrigation line to mitigate transit latency of fluid from said irrigation reservoir. 23. The irrigation system of claim 21, wherein said controller activates an indicator to provide a warning to replace said irrigation reservoir. 24. The irrigation system of claim 20, wherein said flexible membrane of said accumulator is deflected in response to a change in fluid pressure in said irrigation line and causes a change in fluid pressure in said second chamber. 25. The irrigation system of claim 24, wherein said controller including a pressure transducer in fluid communication with said second chamber to detect the change of fluid pressure in said second chamber caused by deflection of said flexible membrane and to adjust a flowrate of said fluid passing through said irrigation line to counteract the change in fluid pressure in said irrigation line by varying the speed of said pump. 26. An irrigation system for a medical device comprising: an irrigation line; a valve to control a flow of fluid through said irrigation line; a pump coupled to said irrigation line to control a flow of fluid through said irrigation line; an accumulator including a first chamber, a second chamber, and a flexible membrane that separates said first chamber from said second chamber and deflects in response to a change in an amount of fluid pressure in said irrigation line, said first chamber of said accumulator operating as a reservoir to store fluid separately from fluid passing through said irrigation line, said fluid stored by said accumulator is provided from said first chamber to said irrigation line separately from said fluid flowing through said irrigation line under control by said pump and without adjustment of said valve; and, a controller including a pressure transducer in fluid communication with said second chamber, said controller to detect a change of fluid pressure in said second chamber caused by the deflection of the flexible membrane and to adjust a flowrate through said irrigation line to counteract a change in the amount of fluid pressure in said irrigation line by varying a speed of said pump. 27. The irrigation system of claim 26 further comprising an irrigation reservoir coupled to said irrigation line. 28. The irrigation system of claim 27, wherein said fluid from said first chamber is provided to said irrigation line to account for a delay of additional fluid being provided from said irrigation reservoir.
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이 특허에 인용된 특허 (31)
Fox Martin (New York NY), Apparatus and method for reverse flow irrigation and aspiration of interior regions of the human eye.
Helfgott Maxwell A. (5640 Bradley Blvd. Bethesda MD 20014) Helfgott Gerald N. (5513 Uppingham St. Chevy Chase MD 20015), Apparatus and process for aspirating and evacuating a surgical site.
Widran Jerrold (60 Estate Dr. Glencoe IL 60022) Krebs Helmut (4849 N. Kenneth Chicago IL 60630), Continuous flow urological endoscopic apparatus and method of using same.
Scheller Gregg D. (Ballwin MO) Lucas R. Bruce (University City MO) Yefet Gideon (St. Louis MO) Dallam David (Pittsford NY), Control system for ophthalmic surgical instruments.
Voss Gregory I. (Solana Beach CA) Butterfield Robert D. (Poway CA) Baura Gail D. (San Diego CA) Barnes Casper W. (Murrieta CA), Fluid flow impedance monitoring system.
Rogers Wayne W. (Napa CA) Rogers Daniel D. (Berkeley CA) Wang Carl C. T. (Piedmont CA) Wang Andrew C. C. (Piedmont CA) Lian Fu-Ming (Berkeley CA), Multimedia apparatus for driving powered surgical instruments.
Drews Robert C. (St. Louis MO) Meyer Danny D. (St. Louis MO) Shalon Tadmor (St. Louis MO) Pasternak Eliezer (St. Louis MO), Ophthalmic aspirator/irrigator and cystotome.
Barwick ; Jr. Billie John (85 Hull St. Beverly MA 01915) Little James H. (6601 S. Country Club Dr. Oklahoma City OK 73159), Phacoemulsification system having ultrasonic power controlled by aspiration vacuum sensor.
Raney, Rob; Claus, Michael J.; Gerg, James; Wong, Wayne S.; King, David A.; Staggs, James W.; Lee, Fred, Automatically pulsing different aspiration levels to an ocular probe.
Raney, Rob; Claus, Michael J.; Gerg, James; Wong, Wayne S.; King, David A.; Staggs, James W.; Lee, Fred, Automatically switching different aspiration levels and/or pumps to an ocular probe.
Raney, Robert G.; Claus, Michael J.; Gerg, James; Wong, Wayne S.; King, David A.; Staggs, James W.; Lee, Fred, Automatically switching different aspiration levels and/or pumps to an ocular probe.
Raney, Robert G.; Claus, Michael J.; Gerg, James; Wong, Wayne S.; King, David A.; Staggs, James W.; Lee, Fred, Automatically switching different aspiration levels and/or pumps to an ocular probe.
Ross, Mark W.; Gerg, James B.; Lynn, Kyle E.; Hickey, Lauren M., Device, system and method for assessing attitude and alignment of a surgical cassette.
Spohn, Michael A.; Haury, John A., Flow based pressure isolation and fluid delivery system including flow based pressure isolation and flow initiating mechanism.
Spohn, Michael A.; Haury, John A., Flow based pressure isolation and fluid delivery system including flow based pressure isolation and flow initiating mechanism.
Callan, Gerald W.; Pedraza, Luis A.; Kwo, Jennie; Zirps, Christopher T.; Beaulieu, Roderick H., Fluid delivery system including a valve and a pressure transducer.
Trombley, III, Frederick W.; Reilly, David M.; Hirschman, Alan D.; Griffiths, David M.; Callan, Gerald W.; Pedraza, Luis A.; Kwo, Jennie; Zirps, Christopher T.; Beaulieu, Roderick H., Fluid path containing a pressure isolation valve.
Oruklu, Meriyan; Ruchti, Timothy L.; Kotnik, Paul T.; Belkin, Anatoly S., Infusion system which utilizes one or more sensors and additional information to make an air determination regarding the infusion system.
Trombley, III,Frederick W.; Schmidt,Robert M.; Reilly,David M.; Hirschman,Alan D.; Griffiths,David M.; Callan,Gerald W.; Pedraza,Luis A.; Kwo,Jennie; Zirps,Christopher T.; Beaulieu,Roderick H., Injector system and fluid control device providing sharp bolus injection.
Friedland, Beth; Korb, Donald R.; Grenon, Steve; Jans, John; Gausmann, Keith; Willis, Timothy R., Methods, apparatuses, and systems for reducing intraocular pressure as a means of preventing or treating open-angle glaucoma.
Callan, Gerald W.; Pedraza, Luis A.; Kwo, Jennie; Zirps, Christopher T.; Beaulieu, Roderick H., Pressure isolation mechanisms, method of use thereof and fluid delivery systems including pressure isolation mechanisms.
Ruchti, Timothy L.; Khair, Mohammad M., System for monitoring and delivering medication to a patient and method of using the same to minimize the risks associated with automated therapy.
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