Abstract: A method for forming a gas-enriched fluid is provided. The method includes a step of providing a mixing chamber having a first inlet, a second inlet, and an outlet. A first fluid is delivered into the mixing chamber via the first inlet and flows vertically. A second fluid having a liquid phase supersaturated with a gas is delivered to the mixing chamber via the second inlet to mix with the first fluid and from the gas-enriched fluid.

Abstract: A fluid pump used to circulate and oxygenate blood, the fluid pump having an electrical or pneumatic motor having a motor shaft, a gas exchange assembly connected to one end of the motor shaft, and a hollow venturi that defines a venturi inlet opening, a venturi exhaust opening, and a venturi suction opening, wherein the venturi suction opening is fluidly connected to the gas exchange assembly to aspirate carbon dioxide rich gas.

Abstract: An aortic balloon occlusion cannula for the occlusion of the aorta ascendens during cardiac surgery including a cannula containing several lumina that are separated from one another. The cannula carriers two dilatable occlusion balloons positioned at a distance from each other, one of the balloons being neighbored to the distal end of the cannula which faces away from the heart and each of the balloons being connected to its own lumen which enables its dilation in independence from the other balloon. The cannula is insertable through the lefthand ventricle of the heart and through the valvula aortae and includes at least one further lumen. The further lumen being connected on the distal side, facing the body, of the distal occlusion balloon to the lumen of the aorta and is adapted to be connected to an extracorporal blood supply device. An additional separate lumen is provided in the cannula and forms a return conduit for liquid and opens on the proximal side of the proximal occlusion balloon.

Abstract: A device for producing a gas-supersaturated fluid is provided. The device includes a chamber having a first inlet to receive a gas and a second and a third inlets to receive a fluid; and an outlet for removal of the produced gas-supersaturated fluid. The gas is received from a gas supply that maintains pressure within the chamber at a predetermined level. An atomizer nozzle is coupled to the third inlet to create fine droplets of fluid within the chamber into which gas diffuses to create the gas-supersaturated fluid. The device also includes a first valve coupled to the outlet of the chamber and a second valve coupled to the second inlet, the third inlet and an actuator assembly to control delivery of the fluid from the piston assembly into the chamber. The fluid is delivered into the chamber through the second inlet when the second valve is open and the fluid is delivered through the third inlet when the second valve is closed.

Abstract: A centrifugal spectrometer has a solid rotor (10) formed within which there are cavities or blades (12). In use, each blade is filled with a buffer solution, and a sample to be separated is placed in a sample well (32) at the end of a separation channel (24). The rotor is spun at a controlled velocity and, at the same time, a controlled potential difference is applied along the length of the blade. The blade shape causes the resultant electric field to vary as a function of radial distance. The sample separates out into bands, which move along the channel (24) under the combined influence of the centrifugal force and the varying electric field. The bands focus at differing equilibrium points according to their charge/mass ratios. The band positions are determined by a readout head (36). The dynamic range of the device may be controlled by altering the rotational velocity and the voltages that are applied.

Abstract: An apparatus and method for blood oxygenation are provided. The apparatus advantageously comprises a liquid-to-liquid oxygenation assembly. The liquid-to-liquid oxygenation assembly includes a pressurizable chamber having inlets for a first gas-supersaturated fluid and a second fluid, such as blood. The inlets are advantageously positioned on the mixing chamber in such a way that the first fluid and the second fluid enter the mixing chamber normally to each other to promote mixing and liquid-to-liquid gas transfer. The mixed fluid exits the chamber via an outlet for delivery to a patient.

Abstract: An apparatus and method for blood oxygenation are provided. The apparatus includes a chamber having a first inlet to receive a gas-supersaturating fluid, e.g., physiologic saline; a second inlet to receive a gas, e.g., oxygen, from a gas supply; and an outlet coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet creates within the chamber fine droplets of fluid into which the gas diffuses to create the gas-supersaturated fluid, which is removed via the outlet. The removed gas-supersaturated fluid mixes with blood within a liquid-to-liquid oxygenation assembly to form oxygenated blood for delivery to a patient. Alternately, the blood may be provided by the pump to a high pressure hollow fiber or other type membrane oxygenator within which oxygen diffuses across the membranes(s) and into the blood to form oxygenated blood, again for delivery to a patient or other site.

Abstract: A total condensed circuit for cardiopulmonary bypass and cardioplegia are provided, as well as methods of using the same. The total circuit includes a cardiopulmonary bypass portion including tubing and components which together have a substantially short path length and priming volume preferably under 800 ml. Thus, the opportunity for an inflammatory response caused by blood contacting plasticizers is minimized. The bypass circuit includes a shunt which bypasses a blood reservoir of the total circuit. The cardioplegia circuit infuses cardioplegia fluid into blood pulled from an oxygenator of the bypass circuit. According to the method, either or both of heart-lung bypass and cardioplegia can be performed with only minimal or no isotonic priming solution circulated into the patient. In addition, use of the shunt and reservoir together eliminate the possibility of air entering the circulation system upon kinking of the circuit.

Abstract: A method for gas-supersaturating fluids, e.g., physiologic saline, includes providing a chamber having a first inlet to receive the fluid; a second inlet to receive a gas, e.g., oxygen, from a gas supply that maintains pressure within the chamber at a predetermined level, advantageously about 600 psi; and an outlet advantageously coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet advantageously creates within the chamber fine droplets of fluid into which gas diffuses to create the gas-supersaturated fluid, which collects within the chamber below the atomizer nozzle for removal via the outlet.

Abstract: Apparatus for oxygenating and pumping blood includes a housing defining a blood flow path including, in series, a gas collection plenum, a pump space and a blood oxygenation element. A pump disposed in the pump space is configured to draw blood from the gas collection plenum and propel blood from the pump space through a heat exchanger and the blood oxygenation element. The heat exchanger includes a heat exchange plate and a coolant space.

Abstract: A disposable, integrated extracorporeal blood circuit employed during cardiopulmonary bypass surgery performs gas exchange, heat transfer, and microemboli filtering functions in a way as to conserve volume, to reduce setup and change out times, to eliminate a venous blood reservoir, and to substantially reduce blood-air interface. Blood from the patient or prime solution is routed through an air removal device that is equipped with air sensors for detection of air. An active air removal controller removes detected air from blood in the air removal device. A disposable circuit support module is used to mount the components of the disposable, integrated extracorporeal blood circuit in close proximity and in a desirable spatial relationship to optimize priming and use of the disposable, integrated extracorporeal blood circuit. A reusable circuit holder supports the disposable circuit support module in relation to a prime solution source, the active air removal controller and other components.

Abstract: A disposable, integrated extracorporeal blood circuit employed during cardiopulmonary bypass surgery performs gas exchange, heat transfer, and microemboli filtering functions in a way as to conserve volume, to reduce setup and change out times, to eliminate a blood reservoir, and to substantially reduce blood-air interface. Blood from the patient or prime solution is routed through an air removal device that is equipped with air sensors for detection of air. An active air removal controller removes detected air from blood in the air removal device. A disposable circuit support module is used to mount the components of the disposable, integrated extracorporeal blood circuit in close proximity and in a desirable spatial relationship to optimize priming and use of the disposable, integrated extracorporeal blood circuit. A reusable circuit holder supports the disposable circuit support module in relation to a prime solution source, the active air removal controller and other components.

Abstract: A self-contained pack assembly includes all of the disposable components of an extracorporeal support circuit for cardiac bypass surgery. The pack assembly comprises a blood reservoir, a blood oxygenator, and a carrier for vertically mounting the blood reservoir and blood oxygenator. Trays may be releasably attached to the carrier to serve as containers for coiled tubing used in the support circuit.

Abstract: Apparatus and method for blood oxygenation are provided. The apparatus includes a chamber having a first inlet to receive a fluid, e.g., physiologic saline; a second inlet to receive a gas, e.g., oxygen, from a gas supply; and an outlet coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet creates within the chamber fine droplets of fluid into which the gas diffuses to create a gas-supersaturated fluid, which is removed via the outlet. The removed gas-supersaturated fluid mixes with blood within a liquid-to-liquid oxygenation assembly to form oxygenated blood for delivery to a patient. Alternately, the blood may be provided by a pump to a high pressure hollow fiber or other type membrane oxygenator within which oxygen diffuses across the membrane(s) and into the blood to form oxygenated blood, again for delivery to a patient or other site.

Abstract: A disposable, integrated extracorporeal blood circuit employed during cardiopulmonary bypass surgery performs gas exchange, heat transfer, and microemboli filtering functions in a way as to conserve volume, to reduce setup and change out times, to eliminate a venous blood reservoir, and to substantially reduce blood-air interface. Blood from the patient or prime solution is routed through an air removal device that is equipped with air sensors for detection of air. An active air removal controller removes detected air from blood in the air removal device. A disposable circuit support module is used to mount the components of the disposable, integrated extracorporeal blood circuit in close proximity and in a desirable spatial relationship to optimize priming and use of the disposable, integrated extracorporeal blood circuit. A reusable circuit holder supports the disposable circuit support module in relation to a prime solution source, the active air removal controller and other components.

Abstract: A total condensed circuit for cardiopulmonary bypass and cardioplegia are provided, as well as methods of using the same. The total circuit includes a cardiopulmonary bypass portion including tubing and components which together have a substantially short path length and priming volume preferably under 800 ml. Thus, the opportunity for an inflammatory response caused by blood contacting plasticizers is minimized. The bypass circuit includes a shunt which bypasses a blood reservoir of the total circuit. The cardioplegia circuit infuses cardioplegia fluid into blood pulled from an oxygenator of the bypass circuit. According to the method, either or both of heart-lung bypass and cardioplegia can be performed with only minimal or no isotonic priming solution circulated into the patient. In addition, use of the shunt and reservoir together eliminate the possibility of air entering the circulation system upon kinking of the circuit.

Abstract: Apparatus for processing blood in an extracorporeal circuit with automatic flow control is provided in which error conditions are sensed and system operation is modulated responsive to the error conditions. The apparatus comprises an extracorporeal blood processing system, at least one sensor to sense the presence of gas or to monitor venous pressure, and a controller operably coupled to the blood processing system to selectively reduce pump speed or reconfigure flow paths the blood processing system responsive to the sensor output.

Abstract: A device for oxygenating blood in an extracorporeal circuit includes a first structure suitable to delimit a portion of space-containing capillaries made of microporous membrane. The capillaries convey oxygen and are wet externally by blood flowing through a portion of space between an intake connector, which is connected to a venous line of the extracorporeal circuit, and a delivery connector. The device includes a second structure monolithically connected and contiguous to the first structure. The second structure is suitable to contain blood filtration means that divide the portion of space delimited thereby into a blood distribution chamber, provided with an air vent and connected to the delivery connector of the first structure, and a blood collection chamber provided with a delivery connector connected to the arterial line of the extracorporeal circuit.

Abstract: An apparatus for blood oxygenation and delivery is provided. The apparatus advantageously comprises a liquid-to-liquid oxygenation assembly with a pressurizable chamber having inlets for a first gas-supersaturated fluid and a second fluid, such as blood. The inlets are advantageously positioned on the mixing chamber in such a way that the first fluid and the second fluid enter the mixing chamber normally to each other to promote mixing and liquid-to-liquid gas transfer. The apparatus also includes a delivery system coupled to the blood oxygenation assembly. The delivery system includes a generally tubular elongated member having a proximal end portion, a distal end portion, and a transition portion located between the proximal end portion and the distal end portion. The transitional portion is relatively flexible compared to the proximal end portion and is relatively stiff compared to the distal end portion.

Abstract: A system and method for increasing gas concentration in blood which has use as a generalized extracorporeal system and method to treat hypoxemic blood from a patient by mixing the blood with an oxygen supersaturated solution to generate hyperoxemic blood to be infused back to the patient. The extracorporeal system comprises an extracorporeal tubing through which blood from the patient is circulated, a blood pump for withdrawing blood from and delivering blood to the patient, at least one channel for delivering oxygen-supersaturated fluid and a mixing region for introducing supersaturated fluid without bubble formation. By infusing the oxygen-supersaturated fluid into the hypoxemic or normoxemic blood from the patient, hyperoxemic blood is thereby produced. The hyperoxemic blood is then returned to a central vein, right heart or artery of the patient with the blood pump at approximately the same volume delivery rate as blood volume withdrawal rate.

Abstract: Apparatus and methods for pumping and oxygenating blood are provided that include a gas removal system. An integrated blood processing unit is provided in which a gas removal/blood filter, pump and blood oxygenation element are mounted within a common housing. The gas removal system includes a sensor mounted on the housing to sense the presence of gas, and a valve is operably coupled to the sensor to evacuate gas from the system when the sensor detects an accumulation of gas.

Abstract: A device for oxygenating blood in an extracorporeal circuit includes a first structure suitable to delimit a portion of space-containing capillaries made of microporous membrane. The capillaries convey oxygen and are wet externally by blood flowing through a portion of space between an intake connector, which is connected to a venous line of the extracorporeal circuit, and a delivery connector. The device includes a second structure monolithically connected and contiguous to the first structure. The second structure is suitable to contain blood filtration means that divide the portion of space delimited thereby into a blood distribution chamber, provided with an air vent and connected to the delivery connector of the first structure, and a blood collection chamber provided with a delivery connector connected to the arterial line of the extracorporeal circuit.

Abstract: A compliant blood gas exchanger is provided including a housing having a first end cap, a second end cap, and an elastomeric sidewall or sleeve extending there between forming a chamber. A hollow fiber assembly is disposed in the chamber. The hollow fiber assembly has a first mounting collar, a second mounting collar and a plurality of hollow fibers disposed there between. The first end cap is disposed in communication with the first mounting collar and the second end cap is disposed in communication with the second mounting collar. The end caps are connected to a gas inlet and a gas outlet. The chamber is in communication with a blood inlet and a blood outlet. The elastomeric sidewall is responsive to internal and external pressures affecting the chamber. The first chamber can also be placed adjacent to a second chamber and both chambers placed within a rigid outer housing. Thus, a dual-chamber pulsatile blood gas exchanger can be provided.

Abstract: Apparatus and methods for pumping and oxygenating blood are provided that include a gas removal system and a pump impeller with a single piece metal insert. An integrated blood processing unit is provided in which a gas removal/blood filter, pump and blood oxygenation element are mounted within a common housing. The gas removal system includes a sensor mounted on the housing to sense the presence of gas, and a valve is operably coupled to the sensor to evacuate gas from the system when the sensor detects an accumulation of gas.

Abstract: An apparatus for exchanging gases in a liquid is provided. Preferably, the apparatus comprises a housing, a first inlet, a gas exchange medium, a separator, a first outlet, and a second inlet and outlet. The apparatus may further comprise a circumferential collection gap that collects liquid from the gas exchange medium and directs it toward the first outlet. Also, the apparatus may further comprise a compliant chamber positioned near the first inlet. The compliant chamber reduces the overall impedance of the apparatus. The apparatus is particularly well-suited for use as an implantable, artificial lung. In this embodiment, the liquid comprises blood and the apparatus exchanges supplied oxygen for waste carbon dioxide.

Abstract: A device generates a gas-enriched physiologic fluid and combines it with a bodily fluid to create a gas-enriched bodily fluid. The device may take the form of a disposable cartridge. The cartridge may include a fluid supply chamber for delivering physiologic fluid under pressure to an atomizer. The atomizer delivers fluid droplets into a gas-pressurized atomization chamber to enrich the physiologic fluid with the gas. The gas-enriched physiologic fluid is delivered to a mixing chamber in the cartridge where the gas-enriched physiologic fluid is mixed with a bodily fluid, such as blood, to create a gas-enriched bodily fluid.

Abstract: Apparatus and methods for pumping and oxygenating blood are provided that include a gas removal system. An integrated blood processing unit is provided in which a gas removal/blood filter, pump and blood oxygenation element are mounted within a common housing. The gas removal system includes a sensor mounted on the housing to sense the presence of gas, and a valve is operably coupled to the sensor to evacuate gas from the system when the sensor detects an accumulation of gas.

Abstract: A gas-enriched fluid is provided by the combination of a first fluid, such as a patient's blood, with a second gas-supersaturated fluid, such as an oxygen supersaturated fluid. In this example, a catheter assembly includes a portion that receives the patient's blood from a pump and that receives the oxygen supersaturated fluid from an appropriate fluid source. The oxygen supersaturated fluid is advantageously combined with the blood in an area of laminar flow, and then this gas-enriched fluid is delivered to the patient through an appropriate lumen coupled to the portion of the catheter assembly.

Abstract: A method and device for intentionally inducing whole-body hyperthermia or hypothermia in a patient for medical treatment while protecting the central nervous system from damage includes a tub for immersing the patient's body in a solution with a temperature greater than or less than normal body temperature to thereby increase or decrease the patient's body temperature. The patient's cerebral spinal fluid is circulated and maintained at temperatures less drastically altered from normal temperatures by a pump and a heater and cooler connected to the patient's spine through catheters. The patient's central nervous system blood is separated from the rest of the circulatory system and circulated and maintained at temperatures less drastically altered from normal temperatures by pumps and a heater and cooler. The remaining blood in the patient's body is circulated and temperature controlled through pumps and a heater and cooler.

Abstract: An apparatus and method for blood oxygenation is provided, advantageously comprising an extracorporeal circuit for the preparation and delivery of hyperoxic or hyperbaric blood. In one embodiment, an apparatus for gas-supersaturating fluids, e.g., physiologic saline, includes a chamber having a first inlet to receive the fluid; a second inlet to-receive a gas, e.g., oxygen, from a gas supply that maintains pressure within the chamber at a predetermined level, advantageously about 600 p.s.i.; and an outlet advantageously coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet advantageously creates within the chamber fine droplets of fluid into which gas diffuses to create the gas-supersaturated fluid, which collects within the chamber below the atomizer nozzle for removal via the outlet.

Abstract: An apparatus and method for blood oxygenation is provided, advantageously comprising an extracorporeal circuit for the preparation and delivery of hyperoxic or hyperbaric blood. In one embodiment, an apparatus for gas-supersaturating fluids, e.g., physiologic saline, includes a chamber having a first inlet to receive the fluid; a second inlet to receive a gas, e.g., oxygen, from a gas supply that maintains pressure within the chamber at a predetermined level, advantageously about 600 p.s.i.; and an outlet advantageously coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet advantageously creates within the chamber fine droplets of fluid into which gas diffuses to create the gas-supersaturated fluid, which collects within the chamber below the atomizer nozzle for removal via the outlet.

Abstract: The efficiency of a hollow fiber wound oxygenator is improved by varying the packing density of the fiber bundle in a direction longitudinal and/or circumferential of the core.

Abstract: An apparatus and method for blood oxygenation is provided, advantageously comprising an extracorporeal circuit for the preparation and delivery of hyperoxic or hyperbaric blood. In one embodiment, an apparatus for gas-supersaturating fluids, e.g., physiologic saline, includes a chamber having a first inlet to receive the fluid; a second inlet to receive a gas, e.g., oxygen, from a gas supply that maintains pressure within the chamber at a predetermined level, advantageously about 600 p.s.i.; and an outlet advantageously coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet advantageously creates within the chamber fine droplets of fluid into which gas diffuses to create the gas-supersaturated fluid, which collects within the chamber below the atomizer nozzle for removal via the outlet.

Abstract: The equipment comprises an impulsion pump (5-5′) with a displaceable piston (7), that adopts a bellows shape, located in the inside of the same, the chamber of the pump receiving the patient's venous blood from a reservoir (4). In the communication (16) between the reservoir and the chamber a float valve (17) has been provided for, a valve that closes the passage when the piston (7) impels the blood through a nozzle (15), passing through a valve (22), then through a heat exchanger (28) and then through an oxygenator (29) from which the oxygenated blood is sent once again to the patient. The shaft (9) of the nozzle (7) is operated by a mechanism (14) that transforms the rotating and alternate movements of a servomotor (12) into linear movements, the operation of this servomotor (12) being controllable by means of a computerized console, permitting a pulsatile blood flow to be provided with adjustable flow and frequency.

Abstract: An oxygenator capable of a small priming volume includes a housing defining an interior cavity. The interior cavity of the housing is subdivided into at least two chambers by a membrane. One of the chambers is a blood chamber and the other chambers are gas chambers. The oxygenator also includes an inlet tube passing through the housing and piercing the membrane to deliver blood directly into the blood chamber.

Abstract: A device generates a gas-enriched physiologic fluid and combines it with a bodily fluid to create a gas-enriched bodily fluid. The device may take the form of a disposable cartridge. The cartridge may include a fluid supply chamber for delivering physiologic fluid under pressure to an atomizer. The atomizer delivers fluid droplets into a gas-pressurized atomization chamber to enrich the physiologic fluid with the gas. The gas-enriched physiologic fluid is delivered to a mixing chamber in the cartridge where the gas-enriched physiologic fluid is mixed with a bodily fluid, such as blood, to create a gas-enriched bodily fluid.

Abstract: Blood mixing in fiber-wound oxygenators is improved by inserting at least one layer of a planar apertured mat between selected layers of wound gas-exchange fibers.

Abstract: A device for producing a gas-supersaturated fluid is provided. The device includes a chamber having a first inlet to receive a gas and a second and a third inlets to receive a fluid; and an outlet for removal of the produced gas-supersaturated fluid. The gas is received from a gas supply that maintains pressure within the chamber at a predetermined level. An atomizer nozzle is coupled to the third inlet to create fine droplets of fluid within the chamber into which gas diffuses to create the gas-supersaturated fluid. The device also includes a first valve coupled to the outlet of the chamber and a second valve coupled to the second inlet, the third inlet and an actuator assembly to control delivery of the fluid from the piston assembly into the chamber. The fluid is delivered into the chamber through the second inlet when the second valve is open and the fluid is delivered through the third inlet when the second valve is closed.

Abstract: A system and method for increasing gas concentration in blood which has use as a generalized extracorporeal system and method to treat hypoxemic blood from a patient by mixing the blood with an oxygen supersaturated solution to generate hyperoxemic blood to be infused back to the patient. The extracorporeal system comprises an extracorporeal tubing through which blood from the patient is circulated, a blood pump for withdrawing blood from and delivering blood to the patient, at least one channel for delivering oxygen-supersaturated fluid and a mixing region for introducing supersaturated fluid without bubble formation. By infusing the oxygen-supersaturated fluid into the hypoxemic or normoxemic blood from the patient, hyperoxemic blood is thereby produced. The hyperoxemic blood is then returned to a central vein, right heart or artery of the patient with the blood pump at approximately the same volume delivery rate as blood volume withdrawal rate.

Abstract: An apparatus and method for blood oxygenation are provided. The apparatus advantageously comprises a liquid-to-liquid oxygenation assembly. The liquid-to-liquid oxygenation assembly includes a pressurizable chamber having inlets for a first gas-supersaturated fluid and a second fluid, such as blood. The inlets are advantageously positioned on the mixing chamber in such a way that the first fluid and the second fluid enter the mixing chamber normally to each other to promote mixing and liquid-to-liquid gas transfer. The mixed fluid exits the chamber via an outlet for delivery to a patient.

Abstract: A method for a bubble-free oxygenated blood delivery is provided. The method includes a step of selecting a delivery system having a tubular elongated member with a lumen. The selecting step comprises determining an effective diameter of the lumen needed to achieve a bubble-free delivery of the oxygenated blood based on a specified oxygenated blood flow rate and a desired target oxygen partial pressure in the oxygenated blood. The delivery system includes a generally tubular elongated member having a proximal end portion, a distal end portion, and a transition portion located between the proximal end portion and the distal end portion. The transitional portion is relatively flexible compared to the proximal end portion and is relatively stiff compared to the distal end portion. In another embodiment, the delivery system includes a generally tubular elongated member having a proximal end portion and a distal end portion with a plurality of holes.

Abstract: A circulatory support system and method for circulatory support are described for performing cardiopulmonary bypass using differential perfusion and/or isolated segmental perfusion of the circulatory system. The circulatory support system includes one or more venous cannulae for draining blood from the venous side of the patient's circulatory system, one or more arterial cannulae for perfusing the arterial side of the patient's circulatory system, and one or more blood circulation pumps connected between the venous cannulae and the arterial cannulae. The arterial cannulae and the venous cannulae of the circulatory support system may take one of several possible configurations. The circulatory support system is configured to segment a patient's circulatory system into one or more isolated circulatory loops.

Abstract: An apparatus and method for blood oxygenation is provided, advantageously comprising an extracorporeal circuit for the preparation and delivery of hyperoxic or hyperbaric blood. In one embodiment, an apparatus for gas-supersaturating fluids, e.g., physiologic saline, includes a chamber having a first inlet to receive the fluid; a second inlet to receive a gas, e.g., oxygen, from a gas supply that maintains pressure within the chamber at a predetermined level, advantageously about 600 p.s.i.; and an outlet advantageously coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet advantageously creates within the chamber fine droplets of fluid into which gas diffuses to create the gas-supersaturated fluid, which collects within the chamber below the atomizer nozzle for removal via the outlet.

Abstract: An intravenous oxygenator having hollow, gas-permeable fibers extending between a distal manifold and a proximal manifold that permit diffusion of gases between the blood vessel and interior of the fibers A rotatable support member extends through the proximal manifold and into the distal manifold. The support member has a lumen in communication with the distal manifold so that oxygen-containing gases flow through the support member, distal manifold, fibers, and proximal manifold. An impeller is attached to and rotated by the support member to enhance blood flow around the fibers.

Abstract: A system utilizes an oxygenation device to generate a gas-enriched physiologic fluid and to combine it with a bodily fluid to create a gas-enriched bodily fluid. The oxygenation device may take the form of a disposable cartridge, which is placed within an enclosure. An electronic controller manages various aspects of the system, such as the production of gas-enriched fluids, flow rates, bubble detection, and automatic operation and shut down.

Abstract: A device for producing a gas-supersaturated fluid is provided. The device includes a chamber having a first inlet to receive a gas and a second and a third inlets to receive a fluid; and an outlet for removal of the produced gas-supersaturated fluid. The gas is received from a gas supply that maintains pressure within the chamber at a predetermined level. An atomizer nozzle is coupled to the third inlet to create fine droplets of fluid within the chamber into which gas diffuses to create the gas-supersaturated fluid. The device also includes a first valve coupled to the outlet of the chamber and a second valve coupled to the second inlet, the third inlet and an actuator assembly to control delivery of the fluid from the piston assembly into the chamber. The fluid is delivered into the chamber through the second inlet when the second valve is open and the fluid is delivered through the third inlet when the second valve is closed.

Abstract: A heart-lung machine comprises flexible tubing 2, 4, 6, 8 and 10 integrated in an extracorporeal blood circuit of the heart-lung machine. A pump 5 pumps the blood of a patient through at least portions of the extracorporeal circuit. Furthermore, compressed fluid actuated control members 20, 21 are provided acting on one flexible tube 6, 10 of the tubing from without. A control means 11 controls the supply of compressed fluid to the control members. In accordance with the invention the compressed fluid supplied to the compressed fluid actuated control members has an operating pressure in the range 2 to 10 bar.

Abstract: An autoimmune vaccine is provided for administration to human patients to alleviate the symptoms of autoimmune diseases such as rheumatoid arthritis. The vaccine comprises an aliquot of the patient's blood, containing, inter alia, leukocytes having upregulated expression of various cell surface markers and lymphocytes containing decreased amounts of certain stress proteins. It is produced by subjecting the blood aliquot extracorporeally to certain stressors, namely oxidizing agents, UV radiation and elevated temperature.

Abstract: Apparatus and method for blood oxygenation are provided. The apparatus includes a chamber having a first inlet to receive a fluid, e.g., physiologic saline; a second inlet to receive a gas, e.g., oxygen, from a gas supply; and an outlet coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet creates within the chamber fine droplets of fluid into which the gas diffuses to create a gas-supersaturated fluid, which is removed via the outlet. The removed gas-supersaturated fluid mixes with blood within a liquid-to-liquid oxygenation assembly to form oxygenated blood for delivery to a patient. Alternately, the blood may be provided by a pump to a high pressure hollow fiber or other type membrane oxygenator within which oxygen diffuses across the membrane(s) and into the blood to form oxygenated blood, again for delivery to a patient or other site.

Abstract: An apparatus and method for blood oxygenation are provided. The apparatus includes a chamber having a first inlet to receive a gas-supersaturating fluid, e.g., physiologic saline; a second inlet to receive a gas, e.g., oxygen, from a gas supply; and an outlet coupled to a capillary assembly. An atomizer nozzle coupled to the first inlet creates within the chamber fine droplets of fluid into which the gas diffuses to create the gas-supersaturated fluid, which is removed via the outlet. The removed gas-supersaturated fluid mixes with blood within a liquid-to-liquid oxygenation assembly to form oxygenated blood for delivery to a patient. Alternately, the blood may be provided by the pump to a high pressure hollow fiber or other type membrane oxygenator within which oxygen diffuses across the membrane(s) and into the blood to form oxygenated blood, again for delivery to a patient or other site.