JP2020120737A - Artificial lung device - Google Patents

Abstract

To provide an artificial lung device that can facilitate routing of a tube for connecting a blood inflow port and a blood outflow port with the device.SOLUTION: The artificial lung device is equipped with a gas exchanger for performing gas exchange for touched blood and with a housing. The housing includes: a box-shaped housing body in which the gas exchanger is housed; a blood inflow port which is formed in the housing body for flowing blood into the housing body for the purpose of performing gas exchange with the gas exchanger; a cylindrical blood outflow port for discharging the blood inside the housing body; and a fitting part for installing the blood outflow port. The base end side of the blood outflow port is installed to the fitting part in a rotatable manner around the axis line. The blood outflow port is designed so that the tip side part is curved to form a prescribed angle relative to the axis line of the base end side part.SELECTED DRAWING: Figure 2

Description

The present invention relates to an oxygenator that removes carbon dioxide contained in blood and adds oxygen.

In operations such as cardiac surgery performed after the patient's heart is stopped moving, an artificial cardiopulmonary circuit is used to replace the stopped function of the heart and lungs. In this artificial heart-lung circuit, the artificial lung plays a role of the lung, and as the artificial lung, for example, one described in Patent Document 1 is known.

The artificial lung described in Patent Document 1 includes a housing and a gas exchanger. A blood inlet port is formed on the bottom of the housing, and a blood outlet port is formed on the outer peripheral surface of the housing. Further, a gas exchanger is housed in the housing, and oxygen is added to blood flowing in the housing by the gas exchanger. In addition, a venous blood tube and an arterial tube are attached to each port in order to allow blood to flow in and out. In the artificial lung configured as described above, blood is guided from the venous tube into the housing through the blood inlet port. The conducted blood is discharged from the blood outlet port to the arterial tube through a gas exchanger in the housing, and oxygen is added to the blood as it passes through the gas exchanger.

Japanese Patent No. 5418274

In the artificial lung described in Patent Document 1, a suspending portion is formed on the upper part of the housing, and the artificial lung is used by suspending it by hanging the suspending portion on a suspending device or the like. The artificial lung thus configured constitutes a part of the artificial heart-lung circuit, and the venous tube and the arterial tube attached to each port are connected to the corresponding devices for use. In the artificial heart-lung circuit, since blood flows in the circuit, the blood flow path of the circuit is filled with a replacement fluid as a preliminary preparation, but the patient's blood is diluted by the amount of the replacement fluid. The amount of blood varies depending on individual factors such as the weight and physique of the patient, but if there is a large amount of fluid replacement for the amount of blood, blood will be diluted and the required concentration of blood components will not be maintained, so blood transfusion will be used to supplement the blood components. There is a need. Therefore, in order to reduce the blood volume to be transfused, it is necessary to make the length of the blood flow path of the artificial lung circuit as short as possible, and this can be realized by shortening the length of the tube, for example.

On the other hand, the length of the tube is increased due to the trade-off of the arrangement depending on the arrangement relationship between the artificial lung and each device. For example, if the blood inlet port does not face the device connected to it, but faces the opposite direction, it is necessary to change the direction of the venous tube toward the device by folding it back in a U-shape, etc. The tube becomes longer. In this regard, in Patent Document 1, the intravenous tube is made as short as possible by rotating the suspension part with respect to the suspension device to change the direction of the blood inlet port so that the intravenous tube does not have to be folded back. doing.

Similarly, it is preferable to shorten the arterial tube as much as possible, but in the case of the artificial lung of Patent Document 1, the following occurs. That is, in the artificial lung of Patent Document 1, the blood inlet port and the blood outlet port extend in opposite directions, so that no matter how many times the artificial lung is rotated with respect to the suspension device, the two ports face the same direction. There is no such thing. Therefore, when the device to be connected to each of the blood inlet port and the blood outlet port is arranged on the same side with respect to the oxygenator, at least one of the tubes attached to the blood inlet port and the blood outlet port is also used. It is necessary to fold it back, and the tube on that side becomes longer. Further, when the tube is folded back, if the degree of folding back is large, the flow path resistance increases at that portion. Then, the blood pressure in the tube may rise or the blood flow may stop. Therefore, it is necessary to devise the handling of the two tubes.

Therefore, it is an object of the present invention to provide an artificial lung device that can facilitate the handling of a tube connecting a blood inflow port and a blood outflow port to a device.

The artificial lung device of the present invention is a gas exchanger for exchanging gas with respect to touched blood, a housing, a hollow housing body for accommodating the gas exchanger, and a gas exchange with the gas exchanger. A blood inflow port formed in the housing body so as to allow blood to flow into the housing body, a cylindrical blood outflow port for discharging blood in the housing body, and a mounting portion to which the blood outflow port is attached. And a housing having, and a proximal end portion of the blood outflow port is attached to the attachment portion so as to be rotatable about an axis thereof, and the blood outflow port has a distal end portion thereof. It is bent so as to form a predetermined angle with respect to the axis of the base end side portion.

According to the present invention, since the blood outflow port is bent and rotatably provided in the housing body, the blood outflow port can be rotated by rotating the blood outflow port regardless of the orientation of the housing body and the blood inflow port. The orientation of can be changed. As a result, it is possible to prevent the position and orientation of the artificial lung device from being limited, and facilitate the handling of the tube that connects the blood inflow port and the blood outflow port to the device.

Further, in the above artificial lung device, the attachment portion is formed in a substantially cylindrical shape, and has an engagement portion on an inner peripheral surface thereof, and a proximal end portion of the blood outflow port is attached to the attachment portion. , And may have an engaged portion that engages with the engaging portion in the attached state.

The blood inflow port receives a load such that it can be detached from the mounting portion from the blood flowing therein or the blood guided therein, but the engaging portion and the engaged portion are engaged with each other as in the above configuration. By doing so, it is possible to prevent the blood inflow port from easily coming off the attachment portion.

Further, in the artificial lung device, one of the engaging portion and the engaged portion is constituted by a plurality of engaging pieces arranged at intervals in the circumferential direction, and the engaging piece is arranged upward. It is formed in a taper shape so as to project radially inward as it advances, and the other of the engaging portion and the engaged portion is formed so as to correspond to the position of the engaging piece and project outward in the radial direction. The engagement pieces may be engaged with the plurality of engagement pieces while being positioned above the plurality of engagement pieces.

With this configuration, when the blood outflow port is attached to the attachment portion, the engaged portion can be guided by the plurality of tapered engagement pieces. Thereby, the blood inflow port can be easily attached, and the artificial lung device can be easily manufactured.

The artificial lung device further includes a first seal member and a second seal member for sealing between an outer peripheral surface of the proximal end side portion and an inner peripheral surface of the mounting portion, wherein the first seal member is The outer peripheral surface of the base end side portion of the blood outflow port may be disposed closer to the base end side than the second seal member, and the second seal member may have a higher crushing rate than the first seal member.

In this case, since the second seal member has a higher crushing rate than the first seal member, even if blood leaks from the first seal member, the second seal member can prevent the blood from leaking to the outside. Further, by reducing the crushing rate of the first seal member, it is possible to suppress an increase in sliding resistance when rotating the blood outflow port.

Further, in the artificial lung device, a proximal end portion of the blood inflow port protrudes from the housing body in one of the up and down directions, and a distal end portion of the blood inflow port is connected to the proximal end portion via a bent portion. The blood outflow port is formed in the bent portion so as to project from the bent portion in one of the up and down directions, and is inclined radially outward so as to be directed in the up and down direction with respect to the base end side portion. You may have a holding part.

With such a configuration, the blood inflow port can be easily rotated by the grip portion. Further, since the grip portion is formed so as to project, the grip portion functions as a rib, and the rigidity of the blood inflow port can be improved. Furthermore, when the oxygenator is dropped with the blood inflow port on the lower side, the grip portion can be applied to the floor or the like. Thereby, the impact at the time of dropping can be applied in the axial direction of the base end side portion. Since the base end side portion is formed along the axial direction thereof, it has high rigidity. Therefore, it is possible to suppress damage to the blood inflow port by landing from the gripping portion when dropped.

According to the present invention, it is possible to facilitate the handling of the tube that connects the blood inflow port and the blood outflow port to the device.

It is a front view which shows the external fitting of the oxygenator of this embodiment. It is sectional drawing which saw the artificial lung device of FIG. 1 cut. It is an expanded sectional view which expands and shows the area|region X1 of FIG. FIG. 3 is a cross-sectional view showing a state where the tip of the blood outflow port is directed to the right side of the drawing with respect to the artificial lung device of FIG. 2. It is a front view which shows the state which turned the blood outflow port in various directions about the oxygenator of FIG. 1, (a) shows the front end of the blood outflow port toward this side, (b) is a blood outflow port. It is a front view showing the state where the tip was turned to the back side. It is an expanded sectional view which expands and shows the blood outflow port vicinity in the oxygenator of other embodiment.

Hereinafter, an artificial lung device 1 according to an embodiment of the present invention will be described with reference to the drawings. In addition, the concept of the direction used in the following description is used for convenience of description, and the direction of the configuration of the invention is not limited to the direction. The artificial lung device 1 described below is merely one embodiment of the present invention. Therefore, the present invention is not limited to the embodiments, and additions, deletions, and changes can be made without departing from the spirit of the invention.

In an operation performed after stopping the movement of a patient's heart, such as a cardiac surgery operation, an artificial lung device 1 as shown in FIG. 1 is used in order to substitute the function of the patient's lungs. The artificial lung device 1 has a gas exchange function of removing carbon dioxide contained in the blood of a patient and adding oxygen thereto. The artificial lung device 1 also has a heat exchange function to adjust the temperature of blood together with gas exchange. The oxygenator 1 having such a function is a so-called horizontal type oxygenator, and includes a housing 2, a heat exchanger 3, a gas exchanger 4, and a filter member 5 as shown in FIG. I have it.

The housing 2 is formed in a substantially hollow cylindrical shape, and has an internal space 2a for accommodating the two exchangers 3 and 4 therein. More specifically, the housing 2 mainly has a housing main body 11, a suspending portion 13, and two cap portions 14 and 15. The housing body 11 is formed in a substantially cylindrical shape, and accommodates the above-described two exchangers 3 and 4 therein. Further, a hanging portion 13 is provided on the outer peripheral surface of the housing body 11. The hanging portion 13 is arranged in the central portion of the housing body 11 in the axial direction, and extends from the outer peripheral surface of the housing body 11 to the outside in the radial direction. Further, the hanging portion 13 is formed in, for example, a substantially columnar shape, and a tip end side portion thereof is attached to a hanging device (not shown) so as to be hung. That is, the housing body 11 can be hung via the hanging portion 13, and the hung housing body 11 is configured such that its axis L1 extends in the horizontal direction. .. In the housing main body 11 arranged in this way, the hanging portion 13 is arranged on the upper portion of the outer peripheral surface thereof, and the open end portions located on both sides in the axial direction are closed by the two cap portions 14 and 15.

The two cap portions 14 and 15 are formed in a substantially disc shape. The first cap portion 14 closes one opening end portion of the housing body 11, and the second cap portion 15 is the other opening portion of the housing body 11. It blocks the end. That is, the first cap portion 14 constitutes one end portion of the housing 2, and the second cap portion 15 constitutes the other end portion of the housing 2. A blood inflow port 16 is formed in the first cap portion 14 near its central axis (that is, near the axis L1). The blood inflow port 16 is formed in a substantially cylindrical shape, and projects obliquely downward from below the central axis of the first cap portion 14. A venous blood tube (not shown) is connected to the blood inflow port 16 having such a shape, and venous blood is guided into the housing main body 11 via the venous blood tube and the blood inflow port 16. .. Further, a blood outflow port 17 is formed on the outer peripheral surface of the housing body 11 at a lower portion thereof (that is, on the opposite side of the hanging portion 13 ). The blood outflow port 17 is formed in a substantially cylindrical shape, projects downward, and is bent obliquely downward at the tip. An arterial blood tube (not shown) is connected to the blood outflow port 17 having such a shape, and the arterial blood generated by the artificial lung device 1 is discharged to the arterial blood tube.

A gas suction port 18 is formed in the first cap portion 14 as shown in FIG. The gas suction port 18 is formed in a substantially cylindrical shape, and projects in the axial direction from near the outer peripheral edge of the first cap portion 14. The gas intake port 18 having such a shape is open to the atmosphere and takes in a gas containing oxygen (that is, air) from the atmosphere into the housing 2. On the other hand, the second cap portion 15 is formed with a gas discharge port 19 as shown in FIG. The gas discharge port 19 is formed in a substantially cylindrical shape, and projects in the axial direction from the vicinity of the outer peripheral edge of the second cap portion 15. The gas exhaust port 19 having such a shape exhausts gas from the gas intake port 18 into the housing 2 to the atmosphere. A gas concentration measuring device may be connected to the gas discharge port 19 via a tube or the like to measure the carbon dioxide concentration of the discharged gas.

Further, the second cap portion 15 has two ports 20 and 21 formed therein. The two ports 20 and 21 are provided in the second cap portion 15 near the central axis (that is, the axis L1) of the second cap portion 15 and vertically separated with the central axis interposed therebetween. Note that the two ports 20 and 21 do not necessarily have to be separated vertically, and may be separated left and right (front side and rear side of the paper surface), or may be separated obliquely. The two ports 20 and 21 are formed in a substantially cylindrical shape and project from the second cap portion 15 in the axial direction, but may project in the axial crossing direction. The medium inflow port 21, which is one of the two ports 20 and 21, is connected to a medium supply tube (not shown) and can guide a medium such as hot water or cold water into the housing 2. The medium outflow port 20, which is the other port 21, is connected to the medium outflow tube, and the medium in the housing 2 is exhausted to the outside of the housing 2 via the medium outflow tube. In the housing 2 in which the plurality of ports 16 to 21 are formed in this way, as shown in FIG. 2, a heat exchanger 3 is provided to adjust the temperature of venous blood introduced therein.

The heat exchanger 3 is formed in a substantially cylindrical shape, and has a tubular core 31, a tube group 32, a casing portion 33, and a medium inflow/outflow portion 34. The tubular core 31 is formed in a substantially cylindrical shape, and projects from the inner side surface of the first cap portion 14 toward the second cap portion 15 along the axis L1. A tube group 32 is inserted and arranged in the tubular core 31. The tube group 32 is formed in a substantially columnar shape, and has a pair of tube supports 32a, 32a and a plurality of heat transfer tubes 32b. Both of the pair of tube supports 32a, 32a are formed in a substantially disc shape, and the outer diameter thereof is substantially the same as the inner diameter of the tubular core 31. The pair of tube supports 32a, 32a thus formed are respectively inserted into the open ends on both sides of the tubular core 31 in a state where a seal is achieved. In addition, a plurality of through holes penetrating in the direction along the axis L1 are radially arranged around the axis L1 in the pair of tube supports 32a, 32a. Each of the through holes is associated with one formed on the one tube support 32a and one formed on the other tube support 32a, and the heat transfer tubes 32b are respectively inserted into the corresponding through holes. There is.

The heat transfer tube 32b is a long and minute cylindrical tube made of a material having a high thermal conductivity such as stainless steel, and blood can be flown therein. Further, the heat transfer tube 32b has both ends thereof inserted into corresponding through holes in the pair of tube supports 32a, 32a, respectively, and thereby is bridged over the pair of tube supports 32a, 32a. Further, the corresponding two through holes are opposed to each other in the axial direction, and the heat transfer tubes 32b inserted therein are arranged so as to extend in the axial direction. As a result, in the tube group 32, the plurality of heat transfer tubes 32b extend in the axial direction and are arranged, for example, radially, and the tube group 32 is formed in a substantially columnar shape. The tube group 32 having such a shape is housed in the tubular core 31 in a state where the open ends on both sides of the tubular core 31 are sealed by the pair of tube supports 32a, 32a.

Further, the tubular core 31 is provided on the inner side surface of the first cap portion 14 and around the central axis of the first cap portion 14 so that their axes are substantially coincident with each other. The portion around the center of the first cap portion 14 constitutes a bulging portion 14a that bulges outward in the axial direction with respect to the remaining portion. The bulging portion 14a is formed so as to correspond to the open end of the tubular core 31, and the blood inflow port 16 is formed therein. A blood inflow space 14b is formed in the bulged portion 14a thus formed, and the blood introduced into the blood inflow port 16 flows into the blood inflow space 14b. .. Further, one end of the tube group 32 housed in the tubular core 31 faces the blood inflow space 14b, and the blood in the blood inflow space 14b passes through a plurality of heat transfer tubes 32b and is on the other end side of the tube group 32. Be led to. On the other hand, the blood inflow space 14b is separated from the inside of the tubular core 31 by the one tube support 32a, and the blood in the blood inflow space 14b is in the space inside the tubular core 31 around the tube group 32. It is not guided. A medium is introduced into the tubular core 31 instead of blood, and the temperature of blood flowing through the plurality of heat transfer tubes 32b can be adjusted by the medium. Further, the first cap portion 14 is provided with a casing portion 33 for guiding the medium into the tubular core 31.

The casing portion 33 is formed in a substantially cylindrical shape, and its inner diameter is formed to be larger than the outer diameter of the tubular core 31. The casing portion 33 having such a shape is provided on the inner surface of the first cap portion 14 such that the axis thereof coincides with the axis L1 of the housing body 11, and the inner surface of the first cap portion 14 extends to the second cap portion 14. It extends toward the axis 15 along the axis L1. The casing portion 33 having such a shape is formed to have substantially the same length as the tubular core 31 in the axial direction. Further, a flange 31d protruding outward in the radial direction is formed at an open end portion which is an end portion of the tubular core 31 on the second cap portion 15 side. The flange 31d is formed over the entire circumference of the tubular core 31 in the circumferential direction, and the outer peripheral edge thereof extends to the opening end portion of the casing portion 33. Further, the casing portion 33 is formed to have a diameter larger than that of the tubular core 31, as described above, and they are arranged to be separated from each other in the radial direction. As a result, a closed substantially annular inner annular space 37 is formed between them. A pair of partition walls (not shown) are arranged in the inner annular space 37 thus formed.

The pair of partition walls are arranged at equal intervals in the inner annular space 37, that is, 180 degrees apart in the circumferential direction. The pair of partition walls are provided in the inner annular space 37 so as to bridge from the outer peripheral surface of the tubular core 31 to the inner peripheral surface of the casing portion 33, and divide the inner annular space 37 into two passages 37a and 37b. That is, between the cylindrical core 31 and the casing portion 33, two passages 37a and 37b (that is, the medium inflow passage 37a and the medium outflow passage 37b) separated from each other by the pair of partition walls are formed. Further, in order to connect the two passages 37a, 37b and the inner space 31a of the tubular core 31, a pair of communicating portions 31b, 31b are formed on the outer peripheral surface of the tubular core 31.

Each of the pair of communication portions 31b, 31b is formed on the outer peripheral surface of the tubular core 31 in correspondence with the medium inflow passage 37a and the medium outflow passage 37b. In addition, in the present embodiment, the pair of communication portions 31b and 31b are arranged on the outer peripheral surface of the tubular core 31 at equal intervals in the circumferential direction, that is, 180 degrees apart from each other, like the pair of partition walls. It faces the medium inflow passage 37a and the medium outflow passage 37b. The communication portion 31b arranged in this manner has a plurality of communication holes 31c. The plurality of communication holes 31c are formed so as to pass through the tubular core 31 in the radial direction, and the medium inflow passage 37a and the medium outflow passage 37b are provided in the inner space 31a of the tubular core 31 via the plurality of communication holes 31c. It is designed to communicate with. That is, the medium inflow passage 37a and the medium outflow passage 37b are connected via the pair of communicating portions 31b, 31b and the inner space 31a. Further, the second cap portion 15 is provided with a medium inflow/outflow portion 34 for supplying the medium to the medium inflow passage 37a and causing the medium to flow out from the medium outflow passage 37b.

The medium inflow/outflow portion 34 is provided in the second cap portion 15 so as to protrude from the inner surface of the second cap portion 15 toward the tubular core 31. More specifically, the medium inflow/outflow portion 34 is arranged around the central axis of the second cap portion 15 and is formed in a generally dome shape. That is, the dome internal space 39 is formed in the medium inflow/outflow portion 34, and the dome internal space 39 communicates with the medium inflow port 20 and the medium outflow port 21 formed in the second cap portion 15. .. Further, a partition plate 34a is arranged in the dome internal space 39 of the medium inflow/outflow portion 34. The partition plate 34a is formed in a substantially plate shape, and is arranged in the dome internal space 39 so as to separate the dome internal space 39 into two spaces, a medium inflow space 39a and a medium outflow space 39b. Further, the partition plate 34a is arranged in the dome inner space 39, and partitions the spaces 39a and 39b so that the medium inflow space 39a is connected to the medium inflow port 20 and the medium outflow space 39b is connected to the medium outflow port 21. ing. Further, the medium inflow/outflow portion 34 is provided with a pair of erected portions 40 so as to bridge the flange 31d. The pair of erected portions 40 are arranged, for example, at positions displaced by 180 degrees from each other, and each have an inflow side passage 40a and an outflow side passage (not shown) formed therein. The inflow side passage 40a connects the medium inflow space 39a and the medium inflow passage 37a, and the outflow side passage connects the medium outflow passage 37b and the medium outflow space 39b.

In the heat exchanger 3 configured as above, the medium is supplied to the medium inflow port 20 via the medium supply tube. The supplied medium is guided to the medium inflow passage 37a via the medium inflow space 39a and the inflow side passage 40a, and further to the inner space 31a of the tubular core 31 via the one communication portion 31b. As described above, the plurality of heat transfer tubes 32b are arranged in the inner space 31a, and the medium flows between them and flows toward the other communicating portion 31b. At this time, the medium exchanges heat with the blood flowing in the heat transfer tube 32b (specifically, heat is applied to the blood in the case of hot water, and heat is removed from the blood in the case of cold water). Thereby, the temperature of the blood flowing through the heat transfer tube 32b is adjusted to a predetermined temperature. The medium that has undergone heat exchange flows out from the inner space 31a to the medium outflow passage 37b via the communication portion 31b, and is further guided to the medium outflow port 21 via the outflow side passage and the medium outflow space 39b. After that, the medium is discharged to the outside of the housing 2 through the medium discharge tube, specifically, is returned to the medium supply device, and after the temperature is adjusted again, the medium is returned to the medium inflow port 20 through the medium supply tube. .. As described above, in the heat exchanger 3, the medium circulates between the inner space 31a and the medium supply device, and the blood flowing in the heat transfer tube 32b, that is, the tube group 32 is exchanged with this medium. Heat exchange takes place. Thereby, the temperature of blood is adjusted. In this way, the blood is guided to the other end through the tube group 32 while adjusting the temperature.

The other end of the tube group 32 is arranged in the axial direction away from the medium inflow/outflow section 34, and the pair of erected sections 40 are arranged in the circumferential direction away from each other. As a result, between the tube group 32 and the medium inflow/outflow portion 34, a pair of radial passages 41 extending radially outward (upward and downward in this embodiment) from the center are formed. Blood flows out from the other end of the tube group 32 to the outside in the radial direction of the casing 33 through the pair of radial passages 41. The outer diameter of the casing part 33 is smaller than the inner diameter of the housing body 11, and a substantially annular outer annular space 42 is formed between the casing part 33 and the housing body 11. An annular passage 43 is formed as a part of the outer annular space 42, and the blood flowing out from the radial passage 41 is guided to the annular passage 43. The gas exchanger 4 is housed in the outer annular space 42.

The gas exchanger 4 has a function of removing carbon dioxide contained in blood and adding oxygen. More specifically, the gas exchanger 4 is formed in a substantially cylindrical shape, and is composed of two seal members 45 and 46 and a hollow fiber body 47. The two seal members 45 and 46 are both formed in a substantially annular shape, and are arranged in the outer annular space 42 so as to be separated from each other in the axial direction. That is, the first seal member 45 seals between the casing portion 33 and the housing body 11 on the first cap portion 14 side of the outer annular space 42 over the entire circumference in the circumferential direction. The first seal member 45 is arranged away from the inner surface of the first cap portion 14 toward the second cap portion 15 side, and forms a gas inflow space 48 between the first seal member 45 and the first cap portion 14. .. In addition, the second seal member 46 seals between the casing portion 33 and the housing body 11 on the second cap portion 15 side of the outer annular space 42 over the entire circumference in the circumferential direction. Further, the second seal member 46 is arranged away from the inner surface of the second cap portion 15 toward the first cap portion 14 side, and forms a gas outflow space 49 with the second cap portion 15. .. Further, the two seal members 45 and 46 are arranged apart from each other in the axial direction as well, and are separated from the two spaces 48 and 49 in the outer annular space 42 between the two seal members 45 and 46. The above-mentioned annular passage 43 is formed. A hollow fiber body 47 is provided in the annular passage 43 formed in this way.

The hollow fiber body 47 is formed in a substantially cylindrical shape, and is composed of a plurality of hollow fibers. More specifically, the hollow fiber body 47 is formed by winding a mat-shaped hollow fiber membrane (bundle), which is formed by stacking a plurality of hollow fibers so as to cross each other, on the outer peripheral surface of the casing 33. There is. The hollow fiber membrane is wound until the thickness of the hollow fiber body 47 substantially matches the distance between the casing portion 33 and the housing body 11. That is, the outer peripheral surface of the hollow fiber body 47 is in contact with the inner peripheral surface of the housing body 11 over the entire circumference, and is formed along the inner peripheral surface of the housing body 11. In the hollow fiber body 47 thus configured, one end side portion thereof penetrates the first seal member 45, and the other end side portion thereof penetrates the second seal member 46. That is, the two spaces 48 and 49 communicate with each other through the inner holes of the plurality of hollow fibers forming the hollow fiber body 47.

Further, in the hollow fiber body 47, a gap is formed between each of the plurality of hollow fibers constituting the hollow fiber body 47, and blood flows through this gap. That is, the blood guided to the annular passage 43 flows to one side in the axial direction (that is, from the second cap portion 15 to the first cap portion 14) through the gap in the hollow fiber body 47. Further, the blood can be brought into contact with the hollow fibers by causing the blood to flow through the gap. The inner hole of the hollow fiber is connected to the two spaces 48 and 49 as described above. The gas inlet port 18 formed corresponding to the gas inlet space 48 is connected, and the gas is guided through the gas inlet port 18. The introduced gas flows out into the gas outflow space 49 through the plurality of hollow fibers. Further, the gas outflow space 49 is connected to a gas exhaust port 19 formed corresponding to the gas outflow space 49 so that the gas flowing out from the hollow fiber is released to the atmosphere via the gas exhaust port 19.

The gas taken in from the gas intake port 18 contains a large amount of oxygen. Therefore, when blood having a high concentration of carbon dioxide is brought into contact with the hollow fiber, gas exchange is performed between the blood and the hollow fiber. That is, carbon dioxide is removed from blood and oxygen is added. As a result, the concentration of carbon dioxide in blood decreases and the concentration of oxygen increases. In this way, the blood flows in the annular passage 43 in one axial direction while the gas exchange is performed by the gas exchanger 4. Further, the downstream side of the annular passage 43, more specifically, the axially one side portion of the outer annular space 42 (that is, the portion on the first cap portion 14 side) is expanded radially outward as compared with the remaining portion. There is.

More specifically, as shown in FIG. 3, a recess 50 that is recessed radially outward is formed on the inner peripheral surface of the housing body 11. The recess 50 is formed over the entire circumference in the circumferential direction so as to approach the first cap portion 14 on the inner peripheral surface. The portion of the recess 50 on the other side in the axial direction is tapered toward the other side in the axial direction, and is formed in a tapered shape. On the other hand, the recess 50 is formed parallel to the axis L1 from the axially intermediate portion to the portion on one side, and the first seal member 45 is arranged in the central portion. The recess 50 thus configured forms a substantially annular outer peripheral space 52 between the outer peripheral surface of the hollow fiber body 47 and the inner peripheral surface of the housing body 11, and the blood flowing through the annular passage 43 is surrounded by the outer peripheral space 52. Guided to 52. Further, in the outer peripheral space 52, the hollow fiber body 47 is not interposed, and the filter member 5 is arranged to remove foreign matter contained in blood.

The filter member 5 is formed in a substantially truncated cone shape and has a filter 54. The filter 54 is permeable to blood, but is configured to remove foreign substances contained in blood (for example, blood clumps). That is, the filter member 5 is adapted to remove foreign matter from the blood passing therethrough.

The filter member 5 configured in this manner is arranged in the outer peripheral space 52 as described above, and the outer peripheral space 52 is divided into two regions of the bubble storage space 55 and the discharge passage 56 by being arranged. .. That is, the outer peripheral space 52 is a bubble storage space 55 that is the upstream side region of the filter member 5 and faces the hollow fiber body 47, and a downstream side region thereof (that is, a region outside the bubble storage space 55 in the radial direction). It is divided into a discharge passage 56. Therefore, the blood introduced from the annular passage 43 to the outer peripheral space 52 first enters the bubble storage space 55 and then passes through the filter member 5 to the discharge passage 56.

Such flowing blood may carry bubbles when being guided from the blood inflow port 16 to the housing 2, and the bubbles ride on the flow of blood and pass through the heat transfer tube 32b and the radial passage 41 to form an annular passage. It is carried to 43. As will be described later, air bubbles are basically taken in by the hollow fiber bodies 47, but not all of them can be taken in. Therefore, the bubbles that cannot be taken in are carried to the bubble storage space 55 by the blood. Further, blood advances from the bubble storage space 55 through the filter member 5 to the discharge passage 56, but most of the bubbles carried cannot pass through the filter member 5 because of the fine opening of the filter member 5. Be blocked by. That is, the air bubbles are stopped before the filter member 5 and float along the filter member 5. The air bubbles that have floated up gather around the highest part of the bubble storage space 55, that is, around the top 59a and collect. In this way, the bubbles are captured in the bubble storage space 55. In addition, it is difficult for the filter member 5 to prevent the permeation of all bubbles, and the bubbles may pass through unexpectedly. Such bubbles are collected around the top 59a, which is the highest portion of the recess 50. A first air bleeding port 57 and a second air bleeding port 58 are formed in the upper part of the housing body 11 in order to discharge the air bubbles thus collected.

The first air bleeding port 57 has a substantially cylindrical shape, and the inner hole of the first air bleeding port 57 opens near the top 59a. A tube (not shown) is connected to the first air bleeding port 57, and the tube is provided with a pinch or a cock that can be opened and closed in the middle of the tube. By removing this pinch or opening the cock, almost all of the air bubbles accumulated around the top portion 59a can be discharged from the first air bleeding port 57. The second air bleeding port 58 is substantially cylindrical like the first air bleeding port 57, and the inner hole of the second air bleeding port 58 opens near the top 50b. A tube (not shown) is connected to the second air bleeding port 58, and the tube is provided with a pinch or a cock that can be opened and closed in the middle of the tube. By removing this pinch or opening the cock, almost all of the air bubbles accumulated around the top portion 50b can be discharged from the second air bleeding port 58. The blood thus separated from the bubbles flows downward along the discharge passage 56. In order to discharge the blood separated in this way to the outside of the housing 2, the housing body 11 is provided with a blood outflow port 17 at the lower portion of the outer peripheral surface thereof and at a position corresponding to the discharge passage 56. Thereby, the blood flowing downward along the discharge passage 56 is discharged to the blood discharge tube via the blood outflow port 17. Hereinafter, the configuration of the blood outflow port 17 will be described in more detail with reference to FIG.

As described above, the blood outflow port 17 is provided in the lower portion of the outer peripheral surface of the housing body 11, and the port attachment portion 22 is integrally provided in the lower portion of the outer peripheral surface of the housing body 11 to provide the blood outflow port 17. It is provided. The port attachment portion 22 is formed in a substantially cylindrical shape and projects downward from the housing body 11. The port attachment portion 22 does not necessarily have to extend vertically downward, and may extend downward and may be inclined in any of front, rear, left, and right directions. Further, in the port attachment portion 22, both the outer peripheral surface and the inner peripheral surface of the tip end side portion 22c are expanded in diameter with respect to the base end side portion 22b, and between the base end side portion 22b and the tip end side portion 22c. A tapered portion 22d is formed. The tapered portion 22d has a diameter that increases from the base end side portion 22b side toward the tip end side portion 22c side, and the base end side portion 22b and the tip end side portion 22c are smoothed by the tapered portion 22d on both the outer peripheral surface and the inner peripheral surface. Connected to. The blood outflow port 17 is inserted into the port attachment portion 22 formed in this way.

The blood outflow port 17 has a substantially cylindrical shape and is formed to be bent, and is bent at a bent portion 17b which is an intermediate portion thereof. That is, in the blood outflow port 17, the lower portion 17c which is a portion on the distal side of the bent portion 17b (that is, the distal end side portion) is the upper portion which is a portion on the proximal end side of the bent portion 17b (that is, the proximal end portion). An angle α is formed with respect to the portion 17d. Here, the angle α is, for example, 30 degrees or more and 120 degrees or less, and is 60 degrees in the present embodiment. In the blood outflow port 17, the angle α is set to 30 degrees or less in order to prevent the tube from bending when the artificial lung apparatus 1 is placed on the floor or placed close to it, and is located at the tip of the blood outflow port 17. The angle α is set to 120 degrees or less in order to prevent the tube from being attached due to the outlet 17a coming too close to the housing body 11.

In the blood outflow port 17 having such a shape, the upper portion 17d is inserted into the port mounting portion 22 and is configured to be rotatable about the axis L2 of the upper portion 17d. That is, the blood outflow port 17 is rotatably attached to the port attachment portion 22, and by rotating the blood outflow port 17, the outlet 17a of the blood outflow port 17 can be oriented in various directions. Further, the inner hole 22a of the port attachment portion 22 communicates with the outer peripheral space 52 (more specifically, the discharge passage 56) via the communication passage 11a formed in the housing body 11. Therefore, the blood flowing downward along the discharge passage 56 enters the blood outflow port 17 through the communication passage 11a, and is further discharged from the outlet 17a to the arterial blood tube.

As described above, the blood outflow port 17 configured as described above is inserted and attached to the port attachment portion 22 so as to be rotatable, that is, is configured separately from the housing body 11. Therefore, it is necessary to take measures against the leakage of blood between the blood outflow port 17 and the port mounting portion 22 and the blood outflow port 17 coming off the port mounting portion 22. The blood outflow port 17 is configured as follows to take these measures.

The blood outflow port 17 has a seal mounting portion 61 near the upper end of the upper portion 17d so that blood does not leak out. The seal attachment portion 61 is formed over the entire circumference in the circumferential direction of the upper end portion 17e, and projects outward in the radial direction from the remaining portion. Two seal grooves 61a and 61b are formed in the seal mounting portion 61 having such a shape. The two seal grooves 61a and 61b are separated from each other in the direction along the axis L2, that is, in the vertical direction in the present embodiment, and extend over the entire circumference in the circumferential direction of the seal mounting portion 61. That is, the two seal grooves 61a and 61b are formed in an annular shape, and the seal members 62 and 63 are housed therein. The seal members 62 and 63 are, for example, O-rings, and are housed in the seal grooves 61a and 61b in a compressed state. As a result, the seal members 62 and 63 are interposed between the outer peripheral surface of the blood outflow port 17 and the inner peripheral surface of the port mounting portion 22, and the seal members 62 and 63 seal between them.

The two seal grooves 61a and 61b have different radial lengths, that is, depths. More specifically, the first seal groove 61a located on the upper side (that is, the base end side) is formed deeper than the second seal groove 61b located on the lower side (that is, the tip end side). On the other hand, the two seal members 62 and 63 having substantially the same size are adopted. Therefore, when the blood outflow port 17 is attached to the port attachment portion 22, the second seal member fitted in the second seal groove 61b is different from the first seal member 62 fitted in the first seal groove 61a. 63 has a higher crushing rate. That is, the second seal member 63 can achieve higher hermeticity than the first seal member 62, and such a second seal member 63 can be arranged on the opening side of the port attachment portion 22. Thereby, even if blood leaks from the space between the first seal member 62 and the port mounting portion 22 to the opening side of the port mounting portion 22, the second sealing member 63 prevents the blood from leaking to the opening side. it can. Further, since the crushing rate of only one of the two seal members 62 and 63 is increased, it is possible to suppress an increase in sliding resistance due to the seal member when the blood outflow port is rotated. In the present embodiment, the crushing rates of the two seal members 62 and 63 are different depending on the depths of the two seal grooves 61a and 61b, but such a configuration is not necessarily required. For example, the two seal members 62 and 63 may have different sizes and different crush rates, or the two seal members 62 and 63 may have different shapes and different crush rates. Further, the crushing rates may be set to be approximately the same.

Further, the blood outflow port 17 is formed with two flanges 64, 65 in the remaining portion other than the seal attachment portion 61 in the upper portion 17d so as not to come off from the port attachment portion 22. The two flanges 64 and 65 are both formed over the entire circumference in the outer peripheral surface of the upper portion 17d, and project outward in the radial direction from the outer peripheral surface of the upper portion 17d. Further, the two flanges 64, 65 are arranged vertically apart from each other, and the first flange 64 arranged on the upper side of the two flanges 64, 65 is located at a position slightly lower than the seal mounting portion 61. Is formed in. Further, the first flange 64 is arranged so as to be located below the tapered portion 22d of the port attachment portion 22 when the blood outflow port 17 is attached to the port attachment portion 22. In addition, an engagement portion 23 is formed on the inner peripheral surface of the port attachment portion 22 at a position corresponding to the first flange 64.

The engaging portion 23 engages the first flange 64 to prevent the blood outflow port 17 from coming off from the port attaching portion 22. In this embodiment, the engaging portion 23 includes a pair of engaging pieces 22e and 22e. Has been done. The pair of engagement pieces 22e, 22e are arranged at equal intervals in the circumferential direction, that is, separated from each other by about 180 degrees, and extend in the circumferential direction on the inner peripheral surface of the port attachment portion 22. Further, the pair of engagement pieces 22e, 22e are formed in a taper shape so as to protrude radially inward from the inner peripheral surface of the port attachment portion 22 and to have a protruding amount increasing from the lower side toward the upper side. .. That is, the inner peripheral surface of the port mounting portion 22 is reduced in diameter from the lower side to the upper side in the portion where the pair of engaging pieces 22e, 22e are engaged. Therefore, when the blood outflow port 17 is inserted from the opening of the port attachment portion 22 to attach the blood outflow port 17 to the port attachment portion 22, the first flange 64 eventually causes the inner surface of the pair of engagement pieces 22e, 22e, that is, the tapered surface. It will hit 22f and 22f. Further, when the blood outflow port 17 is pushed upward to be attached to the port attaching portion 22, the first flange 64 slides on the tapered surface 22f while pushing the pair of engaging pieces 22e, 22e outward. Therefore, the blood outflow port 17 can be further inserted to the proximal end side of the port attachment portion 22. In addition, in the first flange 64, the outer peripheral edge on the upper side of the first flange 64 is largely chamfered so that the first flange 64 can easily slide on the tapered surface 22f. By doing so, it is possible to bend the first flange 64 downward and slide it on the tapered surface 22f, and push the blood outflow port 17 toward the proximal end side of the port attachment portion 22.

When pushed in, the entire first flange 64 eventually reaches the base end side from the upper surfaces of the pair of engaging pieces 22e, 22e, that is, the entire first flange 64 gets over the pair of engaging pieces 22e, 22e. Then, the first flange 64 elastically recovers and expands, and the first flange 64 is mounted on the upper surfaces of the pair of engagement pieces 22e, 22e and engaged. By engaging the first flange 64 with the pair of engaging pieces 22e, 22e in this manner, the first flange 64 is supported by the pair of engaging pieces 22e, 22e, and is disposed below the blood outflow port 17. Even if a force acts, it can be prevented from coming off from the port mounting portion 22. The blood outflow port 17 receives a downward load from the blood guided through the discharge passage 56, and is constantly pushed downward during use. Since the first flange 64 is supported by the pair of engaging pieces 22e, 22e as described above, it is possible to prevent the blood outflow port 17 from coming off the port attachment portion 22 during use. A pair of windows 66, 66 are formed on the outer peripheral surface of the port mounting portion 22 configured in this manner, more specifically, on the inner peripheral surface of the distal end side portion 22c.

The pair of windows 66, 66 is formed by penetrating the tip side portion 22c in the radial direction, and is arranged so as to correspond to each of the pair of engaging pieces 22e, 22e. That is, the lower end edges of the pair of windows 66, 66 are substantially flush with the upper surfaces of the pair of engaging pieces 22e, 22e, and the height thereof is substantially the same as the height of the first flange 64. Further, the pair of windows 66, 66 extend in the circumferential direction, and the positions of both end edges in the circumferential direction substantially match the positions of both end edges of the corresponding engaging pieces 22e, 22e. The pair of windows 66, 66 formed in this manner can promote deformation around the pair of engaging pieces 22e, 22e in the port attachment portion 22. Thereby, when the blood outflow port 17 is pushed into the port attachment portion 22, the first flange 64 of the blood outflow port 17 can push the pair of engaging pieces 22e, 22e apart to some extent. It becomes easy to push 17 into the port mounting portion 22. Further, since the first flange 64 supported by the pair of engagement pieces 22e, 22e can be seen from the outside through the pair of windows 66, 66, the engagement state of the first flange 64 can be visually recognized from the outside. You can The blood outflow port 17 thus engaged has a structure in which the first flange 64 is placed on the pair of engaging pieces 22e, 22e and engages with each other. The movement may cause the first flange 64 to disengage from one of the pair of engaging pieces 22e, 22e. In order to prevent such a situation, a second flange 65 is formed on the upper portion 17d in addition to the first flange 64.

The second flange 65 is formed near the bent portion 17b of the upper portion 17d, and is inserted into the port attachment portion 22 in a state where the first flange 64 is engaged with the pair of engagement pieces 22e, 22e. .. The outer diameter of the second flange 65 is substantially the same as or slightly smaller than the inner peripheral surface of the tip side portion 22c of the port mounting portion 22. Therefore, when the blood outflow port 17 tries to swing forward, backward, leftward, and rightward with respect to the port mounting portion 22, the second flange 65 contacts the inner peripheral surface of the port mounting portion 22, and the swinging of the blood outflow port 17 is restricted. Thereby, the blood outflow port 17 can be prevented from swinging back and forth with respect to the port mounting portion 22 and the first flange 64 from being disengaged from one of the pair of engaging pieces 22e, 22e.

The inner hole 22a of the port mounting portion 22 is formed to have a diameter larger than that of the communication passage 11a, so that a substantially annular surface 11b is formed around the communication passage 11a. The inner diameter of the blood outflow port 17 is substantially the same as that of the communication passage 11a. Therefore, the blood outflow port 17 is attached to the port attachment portion 22 so that its upper end faces the annular surface 11b, and the upward movement is restricted by the annular surface 11b. In this way, the blood outflow port 17 is rotatably attached to the port attachment portion 22 while its movement in the up, down, left and right directions is restricted. Further, the blood outflow port 17 is integrally provided with a grip portion 67 on the bent portion 17b to rotate the blood outflow port 17 around the axis L2.

The grip portion 67 is configured such that the user can grip it with a finger or the like. The gripping portion 67 configured in this manner is integrally provided on the outer side portion of the outer peripheral surface of the bent portion 17b (the portion on the side having a large radius of curvature in FIG. 3) and outside the outer peripheral surface of the bent portion 17b. It projects obliquely downward (diagonally right downward in FIG. 3) so as to be separated from the portion. Further, the grip portion 67 has not only the bent portion 17b but also both end portions thereof extending to the lower portion 17c and the upper portion 17d, respectively, and is formed in a substantially fan shape. Further, the grip portion 67 is formed in a plate shape, and as described above, the user can grip it with a finger or the like. Further, the blood outflow port 17 can be rotated around the axis L2 by gripping the grip portion 67 and rotating the grip portion 67 around the axis L2.

The grip portion 67 configured in this manner plays a role of a rib by being formed so as to project from the bent portion 17b, and improves the rigidity of the blood outflow port 17. Further, since the grip portion 67 projects downward and extends to the same height level as the lower end of the outlet 17a of the blood outflow port 17, the grip portion 67 is provided when the artificial lung apparatus 1 falls from the suspension device or the like. Can be landed from. The grip portion 67 is a plate-shaped member that extends obliquely downward and has a large rigidity with respect to the load when landing. Therefore, the grip portion 67 is unlikely to be damaged even if it lands from the grip portion 67 when dropped. Further, when landing from the grip 67 when dropped, the landing starts from the lowermost position of the grip 67, and the impact acts upward on the grip 67. That is, the impact upon dropping acts on the blood outflow port 17 in the direction along the axis L2. In the blood outflow port 17, since the upper portion 17d is formed along the axis L2, the blood outflow port 17 has high rigidity against a load acting in the direction along the axis L2. Therefore, it is possible to prevent the blood outflow port 17 from being damaged by landing from the grip portion 67 when dropped.

In the artificial lung device 1 thus configured, the venous blood taken out from the vein flows into the blood inflow space 14b in the housing 2 through the blood inflow port 16. The blood in the blood inflow space 14b flows into the heat transfer tubes 32b of the tube group 32, and passes through the heat transfer tubes 32b to the pair of radial passages 41. When passing through the heat transfer tube 32b, the blood exchanges heat with the medium in the inner space 31a, and the temperature of the blood is adjusted. The temperature-adjusted blood travels through the pair of radial passages 41 to the annular passage 43, and passes through the gap in the hollow fiber body 47 arranged in the annular passage 43 toward the discharge passage 56 on one side in the axial direction. Go further to. A gas containing a large amount of oxygen is flowed in each hollow fiber of the hollow fiber body 47, and carbon dioxide is removed from blood by touching the hollow fiber of the hollow fiber body 47 when blood passes through the gap and Oxygen is added to. As a result, the oxygen concentration of blood can be increased. Then, the blood flows from the bubble storage space 55 through the filter member 5 to the discharge passage 56. The blood thus flowing may also carry foreign substances such as aggregates, and by passing the blood through the filter member 5, such foreign substances are captured before entering the discharge passage 56. Then, the blood in which the foreign matter is captured advances downward along the discharge passage 56, is discharged from the blood outflow port 17 to the blood discharge tube, and is returned to the artery via the blood discharge tube.

In the artificial lung device 1 having such a function, as described above, the blood outflow port 17 is rotatably attached to the port attachment portion 22. Therefore, by rotating the blood outflow port 17, the direction of the blood outflow port 17 (that is, the direction of the outflow port 17a) can be changed regardless of the directions of the housing body 11 and the blood inflow port 16. For example, as shown in FIG. 4, the outlet 17a can be directed to the side opposite to the blood inflow port 16 (that is, the right side). Further, by rotating the blood outflow port 17, the outflow port 17a may be directed to the front side of the drawing with respect to the blood inflow port 16 arranged leftward as shown in FIG. As shown in (a), the outlet 17a can be directed to the back side of the paper. Since the orientation of the outlet 17a can be changed by 360 degrees in this way, the degree of freedom in the arrangement position and orientation of the artificial lung device 1 or the arrangement position and orientation of the device to which the artificial lung device 1 is attached is improved. That is, it is possible to facilitate the handling of the tube connecting the blood inflow port 16 and the blood outflow port 17 to the device.

In addition, in the artificial lung device 1, the blood outflow port 17 generally has a lower pressure of blood flowing through it than the blood inflow port 16. Therefore, by configuring the blood outflow port 17 to be rotatable, it is possible to more reliably prevent blood leakage than when configuring the blood inflow port 16 to be rotatable. Further, since the blood outflow port 17 is configured to be rotatable, blood leakage can be prevented with the seal structure having low pressure resistance performance, so that the cost of the artificial lung device 1 can be reduced.

<About other embodiments>
In the oxygenator 1 of the present embodiment, the blood outflow port 17 is provided with the two seal members 62 and 63, but it is not always necessary to provide two. For example, only the first seal member 62 may be provided as in the artificial lung device 1A shown in FIG. 6, or the third seal member may be provided. Further, the second flange 65 in the blood outflow port 17 is not always necessary, and a third flange may be newly formed in addition to the two flanges 64 and 65. Further, the engagement portion 23 does not necessarily have to be configured by the pair of engagement pieces 22e and 22e, and like the pair of engagement pieces 22e and 22e, the entire circumferential direction of the inner peripheral surface of the port attachment portion 22. It may be formed by forming a taper shape over.

Further, in the artificial lung device 1 of the present embodiment, the housing body 11 is formed in a substantially cylindrical shape, but it is not always necessary to have such a shape. For example, the housing body 11 may be formed in a substantially rectangular tube shape, and may be of a cylindrical shape and arranged such that its axis is parallel to the substantially horizontal direction during use. The artificial lung device 1 to which the blood outflow port 17 is applied is not limited to the horizontal type of the present embodiment. For example, a vertical type artificial lung device in which both ends of the housing 2 are vertically arranged. Can also be applied to.

Further, in the artificial lung device 1 of the present embodiment, the blood outflow port 17 is inserted into the inner hole 22a of the port attachment portion 22, but it does not necessarily have such a configuration. That is, the base end side portion of the blood outflow port 17 may have an inner hole into which the port mounting portion 22 can be inserted, and the port mounting portion 22 may be inserted into the inner hole. Further, in the artificial lung device 1 of the present embodiment, the port attachment portion 22 is provided on the housing main body 11 so as to extend in the vertical direction, but it is not necessary to have such a configuration. For example, the port attachment portion 22 may be integrally provided on the first cap member 14 so as to extend parallel to the axis L1 of the housing body 11. By doing so, the blood outflow port 17 is arranged so that the base end side portion thereof extends parallel to the axis L1, and the tip end side portion of the blood outflow port 17 is in any one of upper, lower, left, and right directions with respect to the base end side portion. It is inclined at a predetermined angle. Therefore, by rotating the blood outflow port 17 around the axis of the base end side portion thereof, the outflow port 17a can be oriented in any of the up, down, left and right directions.

Further, in the artificial lung device 1 of the present embodiment, the port attachment portion 22 is provided in the lower portion of the housing body 11, but it does not necessarily have such a structure. For example, the port mounting portion 22 is formed in a substantially cylindrical shape and is mounted on one opening end of the housing body 11. An insertion hole or an insertion portion is formed in the port attachment portion 22, and the blood outflow port 17 is rotatably attached thereto. Further, in the artificial lung device 1 of the present embodiment, the blood outflow port 17 is configured to be rotatable, but the blood inflow port 16 may be configured to be rotatable.

Further, in the oxygenator 1 of the present embodiment, the grip portion 67 projects downward and extends to the same height level as the lower end of the outlet 17a of the blood outflow port 17, but is not limited to such an aspect. Instead, the grip portion 67 does not have to project downward and reach the lower end of the outflow port 17a of the blood outflow port 17. Since the grip portion 67 is configured so as to protrude downward, the rigidity of the blood outflow port 17 can be increased, and the resistance against impact when dropped can be increased.

DESCRIPTION OF SYMBOLS 1 Oxygenator 2 Housing 4 Gas exchanger 11 Housing body 16 Blood inflow port 17 Blood outflow port 17b Bent portion 17c Lower part (tip side part)
17d Upper part (base end part)
22 Port mounting part (mounting part)
22a Inner hole 22e Engagement piece 23 Engagement portion 62 First seal member 63 Second seal member 64 First flange (engaged portion)
67 grip

Claims (5)

A gas exchanger that exchanges gas for touched blood,
The housing includes a hollow housing body in which the gas exchanger is housed, and a blood inflow port formed in the housing body to allow blood to flow into the housing body for gas exchange with the gas exchanger. A housing having a cylindrical blood outflow port for discharging blood in the housing body, and an attachment part to which the blood outflow port is attached,
The proximal end portion of the blood outflow port is attached to the attachment portion so as to be rotatable around its axis.
The oxygenator according to claim 1, wherein the blood outflow port has a distal end portion bent to form a predetermined angle with respect to an axis of the proximal end portion. The mounting portion is formed in a substantially cylindrical shape, and has an engaging portion on an inner peripheral surface thereof,
The artificial lung apparatus according to claim 1, wherein a proximal end portion of the blood outflow port has an engaged portion that is attached to the attachment portion and that engages with the engagement portion in the attached state. One of the engaging portion and the engaged portion is composed of a plurality of engaging pieces arranged at intervals in the circumferential direction,
The engagement piece is formed in a taper shape so as to protrude inward in the radial direction as it goes upward,
The other of the engaging portion and the engaged portion is formed in a position corresponding to the engaging piece and protruding outward in the radial direction, and is positioned above the plurality of engaging pieces. The oxygenator according to claim 2, wherein the oxygenator is adapted to engage with the plurality of engaging pieces. Further comprising a first seal member and a second seal member for sealing between the outer peripheral surface of the base end side portion and the inner peripheral surface of the mounting portion,
The first seal member is arranged closer to the base end side than the second seal member on the outer peripheral surface of the base end side portion of the blood outflow port,
The oxygenator according to any one of claims 1 to 3, wherein the second seal member has a higher crushing rate than the first seal member. The base end side portion of the blood inflow port projects from the housing body in one of the up and down directions,
The tip end side portion of the blood inflow port is connected to the base end side portion via a bent portion, and is inclined outward in the radial direction so as to face the base end side portion in one up and down direction,
The oxygenator according to any one of claims 1 to 4, wherein the blood outflow port has a grip portion formed on the bent portion so as to project from the bent portion in one of the vertical directions.

Images