Fluid removal systems and methods for removing fluid from a tissue site are presented. The system includes a semi-permeable inbound conduit, which is fluidly coupled to a treatment-fluid delivery unit, for placement proximate to the tissue site, and a semi-permeable outbound conduit, which is fluidl
Fluid removal systems and methods for removing fluid from a tissue site are presented. The system includes a semi-permeable inbound conduit, which is fluidly coupled to a treatment-fluid delivery unit, for placement proximate to the tissue site, and a semi-permeable outbound conduit, which is fluidly coupled to the inbound conduit and to a treatment-fluid collector, for placement proximate to the tissue site of a patient. The treatment-fluid collector receives a treatment fluid and a recruited fluid from the tissue site. A recruited-fluid determination unit may be coupled to the treatment-fluid collector to determine a volume of fluid recruited from the patient. The treatment fluid is any fluid (including a gas) that pulls fluid from the interstitial and intracellular space. A reduced-pressure treatment subsystem may also be included, among other things, for removing ascites and other fluids from a body cavity.
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1. A fluid removal system for removing fluid from a tissue site in a body cavity, the system comprising: a semi-permeable inbound conduit for placement proximate to the tissue site;a treatment fluid that is hyperosmotic with respect to the tissue site, wherein the treatment fluid comprises a dry gas
1. A fluid removal system for removing fluid from a tissue site in a body cavity, the system comprising: a semi-permeable inbound conduit for placement proximate to the tissue site;a treatment fluid that is hyperosmotic with respect to the tissue site, wherein the treatment fluid comprises a dry gas;a treatment-fluid delivery unit fluidly coupled to the inbound conduit for delivering the treatment fluid to the inbound conduit;a semi-permeable outbound conduit for placement proximate to the tissue site wherein the outbound conduit is fluidly and physically coupled to the inbound conduit to form a closed fluid path such that the treatment fluid does not leave the semi-permeable inbound conduit and the semi-permeable outbound conduit;wherein the inbound conduit and the outbound conduit comprise a biocompatible, osmotic material;wherein the treatment fluid is disposed within the semi-permeable inbound conduit and the semi-permeable outbound conduit and is operable to recruit water from the body cavity by creating an osmotic gradient across the semi-permeable inbound conduit and the semi-permeable outbound conduit;a treatment-fluid collector fluidly coupled to the outbound conduit for receiving the treatment fluid and a recruited fluid from the tissue site; anda conduit interface for coupling the semi-permeable inbound conduit and the semi-permeable outbound conduit, wherein the conduit interface comprises a plurality of tributary conduits sized for a patient's abdominal cavity. 2. The system for removing fluid from a tissue site of claim 1, further comprising a recruited-fluid determination unit coupled to the treatment-fluid collector for determining a volume of the recruited fluid. 3. The system for removing fluid from a tissue site of claim 1, further comprising: a volume transducer for developing a signal indicative of a volume of the treatment fluid and recruited fluid; anda treatment controller, the treatment controller comprising: a microprocessor,a memory device associated with the microprocessor,an input device associated with the microprocessor for receiving input signals,the volume transducer coupled to the input device,an output means associated with the microprocessor for delivering output signals, andwherein the microprocessor and memory device are operable to receive an input signal from the volume transducer and to determine a recruited-fluid volume, and to develop a control signal to deliver to the output means whereby the treatment-fluid delivery unit may be controlled in response to the control signal. 4. The system for removing fluid from a tissue site of claim 3 wherein the microprocessor and memory device are further operable to develop a control signal to adjust a flow rate in the treatment-fluid delivery unit. 5. The system for removing fluid from a tissue site of claim 3 wherein the treatment-fluid delivery unit further comprises a heating element and wherein the system further comprises an inbound conduit temperature transducer coupled to the treatment controller and wherein the treatment controller is further operable to receive an input signal from the temperature transducer and to develop a control signal for delivery to the treatment-fluid delivery unit to adjust the heating element. 6. The system for removing fluid from a tissue site of claim 1 wherein the inbound conduit comprises a first portion having a distal end and a proximal end, and a second portion having a distal end and a proximal end, wherein the distal end of the first portion of the inbound conduit and proximal end of the second portion of the inbound conduit are coupled by a first coupler. 7. The system for removing fluid from a tissue site of claim 6, wherein the outbound conduit comprises a first portion having a distal end and a proximal end, and a second portion having a distal end and a proximal end, wherein the distal end of the first portion of the outbound conduit and proximal end of the second portion of the outbound conduit are coupled by a second coupler. 8. The system for removing fluid from a tissue site of claim 1 further comprising an open-cavity, reduced-pressure subsystem for removing fluids from the body cavity of the patient. 9. The system for removing fluid from a tissue site of claim 8 wherein the open-cavity, reduced-pressure subsystem comprises: a treatment device comprising: a fenestrated non-adherent drape,a plurality of encapsulated leg members coupled to the non-adherent drape, each having an interior portion with a leg manifold member and formed with fenestrations operable to allow fluid flow into the interior portion, anda central connection member fluidly coupled to the plurality of encapsulated leg members, the central connection member having a first side and a second, patient-facing side;a manifold for disposing proximate the first side of the central connection member and operable to manifold reduced pressure to the central connection member;a sealing member for disposing on a portion of an epidermis of the patient and operable to form a pneumatic seal over the body cavity;a reduced-pressure delivery conduit; anda reduced-pressure interface for coupling to the sealing member and operable to fluidly couple the reduced-pressure delivery conduit to the manifold. 10. The system for removing fluid from a tissue site of claim 9 wherein the central connection member has a connection manifold member and wherein each leg manifold member is in fluid communication with the connection manifold member. 11. The system for removing fluid from a tissue site of claim 9 wherein the outbound conduit and inbound conduit are coupled to at least one of the plurality of encapsulated leg members. 12. The system for removing fluid from a tissue site of claim 9, further comprising a volume transducer for developing a signal indicative of a volume of the treatment fluid and recruited fluid, and a treatment controller, the treatment controller comprising: a microprocessor,a memory device associated with the microprocessor,an input device associated with the microprocessor for receiving input signals,the volume transducer coupled to the input device;an output device associated with the microprocessor for delivering output signals, andwherein the microprocessor and memory device are operable to receive an input signal from the volume transducer and to determine a recruited-fluid volume, and to develop a control signal to deliver to the output device whereby the treatment-fluid delivery unit may be controlled in response to the control signal. 13. The system for providing reduced-pressure treatment of claim 12 wherein the microprocessor and memory device are further operable to develop a control signal to adjust a flow rate in the treatment-fluid delivery unit. 14. The system for providing reduced-pressure treatment of claim 13 wherein the treatment-fluid delivery unit further comprises a heating element and wherein the system further comprises an inbound conduit temperature transducer coupled to the treatment controller and wherein the treatment controller is further operable to receive an input signal from the temperature transducer and to develop a control signal for delivery to the treatment-fluid delivery unit to adjust the heating element. 15. The system for providing reduced-pressure treatment of claim 9 wherein each encapsulated leg member of the plurality of encapsulated leg members comprises: a fenestrated first leg encapsulating member;a fenestrated second leg encapsulating member;wherein the leg manifold member has a first side, a second side, a first lateral edge, and a second lateral edge;wherein the first leg encapsulating member is disposed proximate the first side of the leg manifold member, the second leg encapsulating member is disposed proximate the second patient-facing side of the leg manifold member, and the first leg encapsulating member and second leg encapsulating member are coupled proximate the first lateral edge and second lateral edge of the leg manifold member to form the first encapsulated leg member.
Errede Louis A. (North Oaks MN) Stoesz James D. (St. Paul MN) Winter ; deceased George D. (late of St. Paul MN by Jenny Upton ; personal representative), Composite wound dressing.
Hengstberger Maria (Vienna ATX) Hengstberger Herbert (Vienna ATX) Mnch Harry (Knittlingen DEX), Device for performing examinations and interventions in the abdominal cavity of a patient.
Ohmstede, Volkert Simon, Drainage system to be used with an open wound, an element which is used thereby for placing a drainage tube or hose, and a method of using said drainage system.
Treu Dennis M. ; Burbank Jeffrey H. ; Brugger James M., Flow-through peritoneal dialysis systems and methods with on-line dialysis solution regeneration.
Kerwin Michael J. (11108 Fairborough Ct. St. Louis MO 63146) Yam Jacky S. (1752 Legend La. St. Louis MO 63146) Korte Keith G. (106 E. Main St. Damiansville IL 62215) Klefisch ; Jr. Theodore J. (12349, Fluid collection and disposal system.
Kramer George C. (Galveston TX) Rocha-e-Silva Mauricio (Sao Paulo BRX) Velasco Irineu T. (S. Paulo CA BRX) Wade Charles E. (Sausalito CA), Hypertonic isochloremic formulations for treatment of hypovolemic and circulatory shock.
Todd Robert J. (Salt Lake City UT) Yagge Jaime E. (Salt Lake City UT) Lowe James E. (Durham NC) Wonder Terry M. (Salt Lake City UT), Medical suction apparatus.
Ferdman Ariel (12 Hillside Ave. Melrose MA 02176) Kuo Jing-wen (Boxboro MA) Miller David (Brookline MA) Pinsky Vladimir (Brighton MA) Richards William D. (Medway MA) Swann David (Cambridge MA), Method and device for wound closure.
Moriuchi Yousuke (Fujinomiya JPX) Ishida Toshinobu (Fujinomiya JPX) Kousai Tadashi (Fujinomiya JPX), Method of securing a catheter body to a human skin surface.
Mishra Pravin (3303 W. Reservoir Blvd. Peoria IL 61615) Lehmann John (486 Church Rd. Devon PA 19333) Nair Somnath (5 Oakwood Pl. Voorhees NJ 08043), Microdialysis probes and methods of use.
Luheshi Abdul B. N. (Hull GB3) Smalley Robert K. (Urmston GB3) Kennewell Peter D. (Okus GB3) Westwood Robert (Kingston Bagpuize GB3), Process for the preparation of azabicyclo compounds.
Kashmer James S. (Budd Lake NJ) Klimbach John K. (Wayne NJ) Vendetti Randall P. (Lincoln Park NJ), Suction canister with unitary shut-off valve and filter features.
Richmond James W. (Kalamazoo MI) Tice Robert G. (Portage MI) Booth ; III William M. (Paw Paw MI), Vacuum wound drainage system and lipids baffle therefor.
McNeil Charles B. (5960 Arbour Ave. Edina MN 55436) McEvoy Thomas J. (13103 Baker Trail Minnetonka MN 55343), Wearable, variable rate suction/collection device.
Lock Peter M. (327 Lordswood La. Petrosa ; Walderslade ; Chatham ; Kent GB2) Webb David R. (9 Lambourn Way Lordwood ; Chatham ; Kent GB2), Wound dressing materials.
Beard, Mark Stephen James; Locke, Christopher Brian; Hall, Colin John; Whyte, David George; Sealy, James Joseph; Hardman, Ian James; Robinson, Timothy Mark, Open-cavity, reduced-pressure treatment devices and systems.
Heaton, Keith Patrick; Hardman, Ian James; Coward, Christopher Guy; Hall, Colin John, Reduced-pressure, wound-closure and treatment systems and methods.
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