The present invention generally relates to a device for oxygenating blood. More specifically, the invention pertains to an oxygenator unit and an oxygenator apparatus for use in heart surgery.
An oxygenator apparatus is used during heart surgery and is typically positioned in an extracorporeal circuit. The apparatus performs oxygenation of the blood extracted from a patient. The oxygenator apparatus comes in various types based on, for example, the type of oxygenator, the type of pump, and the difference in mounting position of the pump. The oxygenator apparatus generally includes a reservoir (blood reservoir), an oxygenator, a heat exchanger, a pump, and a plurality of tubes establishing connection between the various components.
to render the oxygenator apparatus usable, an arrangement operation of the reservoir (blood reservoir), the oxygenator, the heat exchanger and the pump is required as is a connection operation of the components. During heart surgery requiring an oxygenator apparatus, urgency may be demanded. Further, even when urgency is not demanded, it is desirable that the preparation operation be quickly completed.
Japanese Patent No. 3738211 (Patent Document 1) proposes an extracorporeal circuit system. The extracorporeal circuit system is a packed unit of an extracorporeal circuit system including an extracorporeal circuit system packed in one package. The extracorporeal circuit system has a venous reservoir, an oxygenator, an arterial filter, a reservoir holder for holding the venous reservoir, an oxygenator holder for holding the oxygenator, and a filter holder for holding the arterial filter. The venous reservoir and the oxygenator are connected with a first tube. The oxygenator and the arterial filter are connected to a second tube. A circulation pump for supplying the blood in the venous reservoir to the oxygenator is connected to the first tube. A blood extraction tube connection part capable of connecting a blood extraction tube to the venous reservoir is provided. A blood supply tube connection part capable of connecting a blood supply tube to the arterial filter is provided. The filter holder is rotatably connected to the side part of the reservoir holder. The filter holder is rotated such as to be along the side of the reservoir during storage, and such as to extend to the side part of the reservoir holder during use.
Conventionally, the arrangement of a venous reservoir, an oxygenator, a pump and the like in an extracorporeal circuit has not been unified or standardized according to the arrangement of devices in an operating room, the habit of the operator, and the like. Thus, the arrangement of the components may often vary depending upon the hospital and the operator. However, some uses of the pump oxygenator apparatus require urgency as described above.
An oxygenator unit disclosed here includes a venous reservoir, a pump and heat exchange unit-equipped oxygenator and the centrifugal pump are connected by the first connection part, and the centrifugal pump and the heat exchange unit-equipped oxygenator are connected by the second connection part. Further, the unit includes the unit frame. In addition, the venous reservoir is disposed at the reservoir disposition part and is held by the unit frame; the centrifugal pump is disposed at the pump disposition part and is held by the unit frame; and the heat exchange function-equipped oxygenator is disposed at the oxygenator disposition part and is held by the unit frame, thereby resulting in a unit.
With this disclosed construction, the positions of the venous reservoir, the oxygenator, and the pump cannot be changed arbitrarily. However, these pieces are set in a unit by the unit frame, and are arranged in a usable state. Accordingly, the setting operation of the extracorporeal circuit does not require disposing or positioning the venous reservoir, the oxygenator, and the pump. This allows a relatively quick preparatory use of the extracorporeal circuit.
According to another aspect, an oxygenator unit comprises a venous reservoir enclosing an interior, wherein the venous reservoir comprises a reservoir side blood inlet communicating with the interior and a reservoir side blood outlet communicating with the interior, with the reservoir side blood inlet being positioned vertically higher than the reservoir side blood outlet, a centrifugal pump comprising a pump side blood inlet by which blood enters the pump and a pump side blood outlet by which blood exits the pump, and an oxygenator comprising a housing, a gas inlet extending from the housing through which gas is introduced into the oxygenator to effect oxygenation of blood introduced into the oxygenator, a gas outlet extending from the housing through which gas exits the oxygenator, an oxygenator side blood inlet extending from the housing through which blood flows into the oxygenator to be oxygenated, and an oxygenator side blood outlet by which oxygenated blood flows out of the oxygenator. The reservoir side blood outlet is in fluid communication with the pump side blood inlet, and the pump side blood outlet is in fluid communication with the oxygenator side blood inlet. The oxygenator unit also comprises a reservoir receiving frame part in which the venous reservoir is separate from and mounted on the reservoir receiving frame part, a pump receiving frame part in which the pump is separate from and mounted on the pump receiving frame part, and an oxygenator receiving frame part, wherein the oxygenator is separate from and mounted on the oxygenator receiving frame part. The reservoir receiving frame part, the pump receiving frame part, and the oxygenator receiving frame part are unitarily formed in one piece from a common material.
Referring initially to
An oxygenator apparatus 1 disclosed here includes, as shown in
The oxygenator unit 1 includes, as shown in
The unit frame 5 includes, as shown in
The venous reservoir 2 is separate from the reservoir disposition part 52 (i.e., the venous reservoir 2 is not integrally formed in one piece with the reservoir disposition part 52) and is disposed or received at the reservoir disposition part 52 of the unit frame and is held by the unit frame 5. The centrifugal pump 3 is separate from the pump disposition part 53 (i.e., the centrifugal pump 3 is not integrally formed in one piece with the pump disposition part 53) and is disposed or received at the pump disposition part 53 of the unit frame and is held by the unit frame 5. In addition, the heat exchange function-equipped oxygenator 4 is separate from the oxygenator receiving part 54 (i.e., the heat exchange function-equipped oxygenator 4 is not integrally formed in one piece with the oxygenator receiving part 54) and is disposed or received at the oxygenator receiving part 54 of the unit frame and is held by the unit frame 5. As a result, these components (the venous reservoir 2, the centrifugal pump 3, and the heat exchange function-equipped oxygenator 4) are integrated together as a single unit, by way of the unit frame 5.
The oxygenator unit holder 7 includes, as shown in
In the example of the oxygenator unit 1 shown in
Referring to
The venous reservoir 2 includes, as shown in
The reservoir disposition part 52 of the unit frame 5 includes, as shown in
The unit frame 5 includes, as shown in
The unit frame 5 includes, as shown in
With the venous reservoir 2 disposed at the reservoir receiving part 52, the blood outlet 22 of the reservoir 2 is situated above the pump receiving part 53 of the extended frame part 56. The oxygenator receiving part 54 is situated under the reservoir receiving part 52, and is situated behind the pump receiving part 53.
The oxygenator unit 1 includes the cover member 8 covering the top surface of the venous reservoir 2. The cover member 8 includes an engagement part (not shown) which engages an engagement projection 59a provided at the upper end holding part 59 of the unit frame 5. This engagement inhibits in an auxiliary manner the disengagement of the reservoir from the unit frame 5. Further, on the top surface of the cover member 8, a groove-shaped tube mounting part 8a is provided.
The oxygenator unit may also be an oxygenator unit 10 shown by way of example in
In the oxygenator unit 10, the heat exchange medium inlet port 46, the heat exchange medium outlet port 47, and the oxygen-containing gas inlet port 48 are curved or bent so that their respective openings face the front surface side of the oxygenator unit 10. In addition, the unit frame 5a includes openings for allowing the heat exchange medium inlet port 46, the heat exchange medium outlet port 47, and the oxygen-containing gas inlet port 48 to be placed therein. Specifically, the unit frame 5a includes a plate part 98 having openings for allowing the heat exchange medium inlet port 46, the heat exchange medium outlet port 47, and the oxygen-containing gas inlet port 48 to be placed therein. Further, the blood outlet port 42 provided at the central part of the tube-shaped housing of the heat exchange function-equipped oxygenator 4 is also configured to face outwardly from the front surface side of the oxygenator unit 10.
With such a configuration, the tube connection surfaces to the oxygenator unit in use are on the same plane, and the disposing positions of the port parts are concentrated. This further facilitates the tube connection operation.
The oxygenator unit may also be an oxygenator unit 70 illustrated by way of example in
The heat exchange medium inlet port 46, the heat exchange medium outlet port 47, and the oxygen-containing gas inlet port 48 in the oxygenator unit are curved or bent such that their respective openings face in the vertical direction of the oxygenator unit 70 and downwardly. In the example shown, the heat exchange medium inlet port 46, the heat exchange medium outlet port 47, and the oxygen-containing gas inlet port 48 are arranged parallel to each other, and in a linear (straight-line) manner.
Also with such a configuration, the tube connection surfaces to the oxygenator unit in use are on the same plane, and the positions of the port parts are also concentrated. This helps facilitate the tube connection operation.
The oxygenator unit is preferably subjected to a sterilization treatment after having been stored in a packed body.
Generally, the oxygenator unit is stored in a packed body which allows a sterile gas to enter therein, and then is subjected to gas sterilization. The packed body may also be further stored in a box. Thus, the packed body may be subjected to gas sterilization while being stored in the box.
The oxygenator unit holder 7 includes, as shown in
As shown in
Further, the oxygenator unit holder 7 includes, as shown in
Further, the holder may also be one having a port mounting part as shown in
Also in the holder 80 of this example, the holder main body 81 includes a unit mounting part capable of mounting the oxygenator unit 70 on the top surface part thereof, and a centrifugal pump driving part 75 for rotating an impeller housed in the centrifugal pump 3.
Further, the holder 80 includes a heat exchange medium inlet port mounting part 91 adapted to mount the heat exchange medium inlet port 46 on the top surface of the holder, a heat exchange medium outlet port mounting part 92 adapted to mount the heat exchange medium outlet port 47, and a gas inlet port mounting part 93 adapted to mount the oxygen-containing gas inlet port 48. Specifically, the holder main body 81 includes three concave parts (recessed portions) extending from the top surface in the vertical direction (vertical and downward direction). The concave parts each include a flexible tubular body inserted and fixed thereto. Then, the first concave part and the flexible tube body inserted and fixed in the inside thereof form the heat exchange medium inlet port mounting part 91. Similarly, the second concave part and the flexible tube body inserted and fixed in the inside thereof form the heat exchange medium outlet port mounting part 92. Further, the third concave part and the flexible tube body inserted and fixed in the inside thereof form the gas inlet port mounting part 93.
Further, the holder main body 81 includes a heat exchange medium inlet 94 communicating with the heat exchange medium inlet port mounting part 91. In this example, the heat exchange medium inlet 94 is a protruding part protruding downwardly from the bottom surface of the holder main body 81, and hence it can be connected with the heat medium supply unit with relative ease. Similarly, the holder main body 81 includes a heat exchange medium outlet 95 communicating with the heat exchange medium outlet port mounting part 92. In this example, the heat exchange medium outlet 95 is a protruding part protruding downwardly from the bottom surface of the holder main body 81, and hence it can be connected with the heat medium supply unit with relative ease. Then, the holder main body 81 includes a gas inlet 96 communicating with the gas inlet port mounting part 93. In this example, the gas inlet 96 is a protruding part protruding downwardly from the bottom surface of the holder main body 81, and hence it can be connected with the oxygen-containing gas supply unit with relative ease.
With the oxygenator apparatus of this example, as shown in
The holder 80 of this example includes a temperature sensor 97 attached to the duct between the heat exchange medium inlet port mounting part 91 and the heat exchange medium inlet 94. The temperature sensor may be attached to the duct between the heat exchange medium outlet port mounting part 92 and the heat exchange medium outlet 95, or may be attached to the ducts of both. Fixing the temperature sensor to the holder 80 eliminates the necessity of performing an attachment operation of the temperature sensor to the oxygenator unit. Further, setting of the oxygenator apparatus can be carried out more quickly. Known temperature sensors can be used here. A preferred temperature sensor is one using a thermocouple.
Set forth below is a description of the venous reservoir 2 used in the oxygenator unit 1 disclosed here. As shown in
The cover body 23b is fitted to the upper end of the housing main body 23a to cover the upper opening of the reservoir housing main body 23a. The cover body 23b includes the blood inlet 21 to be connected with a venous line for supplying blood from the venous cannulae inserted into the heart ascending and descending veins of the patient, the blood inlet 24 to be connected with the cardiotomy line for supplying blood from the operating field, and the air discharge port 27 also usable as a rapid priming port.
A blood filter (venous blood filter) 26 is positioned in the housing 23. The blood filter serves as a defoaming member and anti-foaming member for filtrating the blood flowing from the blood inlet port (reservoir side blood inlet) 21. Also located within the housing 23 is a cardiotomy blood filter 29 for filtrating the blood flowing from the blood inlet port 24. The lower end of the blood inlet port 21 extends in the blood reservoir, and is situated in the blood filter 26. All the blood flowing from the blood inlet port 21 passes through the blood filter 26, and then flows into the blood reservoir. Specifically, the blood filter 26 is fixed so that the protruding part of the blood inlet port 21 which protrudes into the blood reservoir is encapsulated in the inner side of the cover body 23b.
The reservoir housing main body 23a includes the protruding part 2b which protrudes downwardly. The lower end of the blood filter 26 extends to the vicinity of the lower end of the protruding part 2b. The blood filter 26 includes a filter member 26a and a defoaming material 26b attached to the entire inner circumference of the upper part of the filter member 26a. Similarly, the cardiotomy blood filter 29 includes a filter member 29a and a defoaming material 29b attached to the entire inner circumference of the upper part of the filter member 29a.
Defoaming materials 26b, 29b, or anti-foaming materials, which can be used preferably include various porous bodies such as foamed products including foamed polyurethane, foamed polyethylene, foamed polypropylene, foamed polystyrene, and the like, and mesh, web, nonwoven fabric, or porous ceramics, and sintered bodies of resins. Particularly preferable are materials having a relatively low air pass resistance (pressure loss). When a foamed product such as foamed polyurethane or other porous materials are used as the material having a low air pass resistance, the pore diameter thereof is preferably 20 μm to 10 mm, and in particular, about 50 μm to 5 mm.
Further, such defoaming materials 26b, 29b preferably carry a defoaming agent which function to break bubbles upon contact therewith. As the defoaming agent, silicone (of a silica-mixed compound type, an oil type, or the like) is preferable. Examples of methods for causing the defoaming members 26b, 29b to carry or be provided with a defoaming agent include a method in which a defoaming member is impregnated in a liquid containing a defoaming agent, a method in which a liquid containing a defoaming agent is applied or sprayed, and dried (for example, at 30° C. for 180 minutes), and other methods.
The filter members 26a, 29a are adapted to remove foreign matters or bubbles in blood. As the material for the filter members 26a, 29a, a porous material having sufficient blood permeability is preferable.
As depicted in
The centrifugal pump 3 is disposed under the venous reservoir 2 as shown in
Set forth below is a description of the use of the centrifugal pump 3 in the oxygenator unit 1 disclosed here.
Referring to
The centrifugal pump driving part 75 mounted in the oxygenator unit holder 7 can be of a known type of driving part. The driving part 75 generally includes a motor, a rotational member (e.g., a rotational plate) fixed to the rotation shaft of the motor, and a permanent magnet attached to the rotational plate. The permanent magnet is provided at the position corresponding to the magnetic member 36 provided in the impeller 34. For this reason, the rotational plate of the driving part 75 is connected by the magnetic attraction force through the housing to the impeller of the centrifugal pump. Then, rotation of the motor causes the rotational plate to rotate. The impeller 34 also rotates following the rotation of the rotational plate. The motor can be, for example, an AC motor, a DC motor, and the like. However, a variable speed motor is preferable. Further, a motor which is easily controlled in flow rate is preferable. For example, a stepping motor which is an AC motor is preferable.
Referring to
The heat exchange function-equipped oxygenator 4 is disposed at a position in the vicinity of the pump side blood outlet of the centrifugal pump 3, specifically, behind the centrifugal pump 3. Stated differently, the heat exchange function-equipped oxygenator 4 is positioned downstream of the centrifugal pump 3 The blood outlet 32 of the centrifugal pump 3 is connected with the blood inlet 41 of the heat exchange function-equipped oxygenator 4 by the second connection part 12, specifically the second connection tube. The tube 12 is preferably a flexible resin tube.
The heat exchange function-equipped oxygenator 4 includes, as shown in
In the heat exchange function-equipped oxygenator 4, the housing 43 includes a tube-shaped (tubular) housing main body, a first header 44 including the gas inlet 48 and the heat medium inlet 46, and the heat medium outlet 47, and a second header 45 having the gas outlet 49. The blood inlet port 42 is provided at a position which is the lower end (lower half) of the central part (central part relative to the length of the housing) of the side surface of the tube-shaped housing main body.
The tube-shaped hollow fiber membrane bundle 15 is wound around the outer surface of the core 67 including a large number of openings 68. Further, the tube-shaped heat exchange unit part 17 is positioned in the inside of the core 67. A blood circulation part 61 (which is also a part of the blood chamber) is located between the inner surface of the core 67 and the outer surface of the tube-shaped heat exchange unit part 17. The blood circulation part 61 communicates with the blood inlet 41 and the blood outlet 42. Heat medium circulation chambers 65, 66 are located in the inside of the tube-shaped heat exchange unit part 17. The heat medium circulation chambers 65, 66 communicate with the heat medium inlet 46 and the heat medium outlet 47.
In the heat exchange function-equipped oxygenator 4, blood flowing from the blood inlet 41 into the oxygenator 4 is subjected to heat exchange while flowing between the inner surface of the core 67 and the outer surface of the tube-shaped heat exchange unit part 17. The blood subjected to heat exchange flows from the openings 68 of the core 67 into the tube-shaped hollow fiber membrane bundle 15 (into the blood chamber). As the blood contacts the hollow fiber membrane, gas exchange in the blood is carried out (i.e., oxygen is added and carbon dioxide is removed). Then, the blood which has passed through the tube-shaped hollow fiber membrane bundle 15 flows into the annular space (which is a part of the blood chamber) formed between the tube-shaped hollow fiber membrane bundle 15 and the inner surface of the tube-shaped housing main body, and flows out of the blood outlet 42.
As the hollow fiber membrane for gas exchange, a porous film is preferably used.
The tube-shaped heat exchange unit part 17 is preferably a so-called bellows type heat exchange part. The bellows type tube-shaped member, which is at least the outer side surface forming member of the tube-shaped heat exchange unit part 17, is formed in the shape of so-called fine bellows with a metal such as stainless steel or aluminum or a resin material such as polyethylene or polycarbonate. A metal such as stainless steel or aluminum is preferred from the viewpoints of the strength and the heat exchange efficiency. In this example, the tube-shaped heat exchange unit part 1 is one including a bellows tube in the shape of a wave including a large number of repeating projections and depressions roughly orthogonal to the axial direction (central axis) of the tube-shaped heat exchange unit part.
The heat exchange unit part 17 includes the bellows type tube-shaped member forming the outer side surface, and an inner side tube-shaped member 63 stored in the inside of the bellows type tube-shaped member. A heat medium chamber is formed between the inner side tube-shaped member and the bellows type tube-shaped member. Further, the inner side tube-shaped member 63 has a bottom surface closed, and has two openings 64a, 64b on the side surface thereof, and the heat medium inlet 46 and the heat medium outlet 47. Further, the inside of the inner side tube-shaped member 63 is divided into two internal chambers 65 and 66. The heat medium inlet 46 communicates with the internal chamber 65, and the heat medium outlet 47 communicates with the second internal chamber 66. With the heat exchange unit part 17, the heat exchange medium flowing from the heat medium inlet 46 flows into the first internal chamber 65, and passes through the opening 64a, and flows between the bellows type tube-shaped member and the inner side tube-shaped member 63. Then, the heat medium flows from the opening 64b into the second internal chamber 66, and flows out of the heat medium outlet 48.
The inner side tube-shaped member is formed of a synthetic resin or a metal such as stainless steel or aluminum. Whereas, the tube-shaped heat exchange unit part 17 is preferably in the shape of a cylinder.
Further, the heat exchange function-equipped oxygenator 4 of this example includes an arterial filter function. Specifically, as shown in
As shown in
It is preferable that the blood contact surfaces of the centrifugal pump and the oxygenator are antithrombogenic surfaces. The antithrombogenic surface formation can be accomplished by the use of a known method.
The principles, embodiments and modes of operation of the oxygenator unit and oxygenator apparatus have been described in the foregoing specification, but the invention which is intended to be protected is not to be construed as limited to the particular embodiments disclosed. The embodiments described herein are to be regarded as illustrative rather than restrictive. Variations and changes may be made by others, and equivalents employed, without departing from the spirit of the present invention. Accordingly, it is expressly intended that all such variations, changes and equivalents which fall within the spirit and scope of the present invention as defined in the claims, be embraced thereby.
Number | Date | Country | Kind |
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2008-001358 | Jan 2008 | JP | national |