JP2002136854A - Device for incorporating gas in liquid - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device for incorporating a gas in a liquid such as for incorporating oxygen in a liquid, which is capable of efficiently incorporating oxygen in the liquid supplied to a part of a body such as an organ. SOLUTION: The device for incorporating oxygen in the liquid by allowing the liquid to bring into contact with oxygen is constituted so as to include a plurality of hollow fibers (5), a housing (1) housing the hollow fibers, a cap (2) having a liquid flow-in port (2a), a cap (3) having a liquid flow-out port (3a) and an oxygen supply port (4) and the incorporation of oxygen is performed by allow the liquid to flow in the hollow fiber form the liquid flow-ion port the(2a) and to flow-out through the hollow part of the hollow fiber from the liquid flow-out port (3) and supplying oxygen to the housing (1) from the oxygen supply port (4) to allow the liquid to bring into contact with oxygen through a membrane of the hollow fiber (5).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for bringing a liquid into a gas state by bringing the liquid into contact with a gas, that is, an apparatus for gasifying a liquid, and in particular, an apparatus for oxygenating (or oxygenating) a liquid. And / or a device for carbonation (or carbonation), particularly in the medical field, for the purpose of minimizing the amount of bleeding when performing surgical procedures on a subject such as an organ, for example. The present invention relates to a liquid gas adding device that can be used in combination with a bloodless treatment device used to supply a liquid to a body.

[0002]

2. Related Art In the medical field, reducing the amount of bleeding has become an important issue when performing a surgical procedure on an object such as an organ. Therefore, various attempts have been made to solve the problem. The present applicant has also conducted various studies, and as a result, suppressed the blood flow in the blood vessels flowing into the subject of the surgical procedure, and instead specified water-based specific liquid (eg, Ringer's solution, Ringer's lactate solution, etc.) It has been found that the above problem can be solved by a bloodless treatment of supplying a solution. The fluid supplied to a subject instead of blood in a bloodless procedure is called a rehydration fluid. Since bloodless treatment devices are generally performed with the subject cooled, replacement fluid is used instead of blood to prevent blood clotting. By adjusting the replacement fluid to a predetermined temperature and supplying it to the target, the target can be set to a desired temperature.

[0003] Applicants have used bloodless treatment devices used in the surgical treatment of such subjects, comprising: A) a unit for supplying replacement fluid to the subject, and B) a unit for discharging replacement fluid from the subject. Has already been published in International Publication WO0
No. 0/47251. This bloodless treatment device can be used, for example, in combination with a catheter with a balloon, inserts the catheter with a balloon into a blood vessel flowing into the subject, suppresses the inflow of blood to the subject by inflating the balloon, and replaces blood with replacement fluid. Is intended to reduce the amount of bleeding by supplying blood to the blood vessels.

[0004] The term "surgical treatment" is a broad concept including treatment, treatment, examination, and the like involving an act of damaging a part of the body, and includes, for example, surgery. A "subject" is a body part (e.g., an organ such as a limb, face, head, brain, liver, or a part thereof) that is an object on which a surgical procedure is to be performed. For example, an organ having cancer cells). The term "bloodless" is used to mean that the amount of bleeding is substantially smaller than when bloodless treatment is not performed.

[0005]

DISCLOSURE OF THE INVENTION As a result of further studies to improve the above-described bloodless treatment apparatus, oxygenation of a replacement fluid supplied to a subject reduces tissue damage of the subject and improves safety to the body ( In particular, it has been found that it is preferable in terms of prevention of ischemic injury when the temperature is returned from the low temperature state to the normal temperature (body temperature) (that is, when the temperature is restored). In this specification, “adding oxygen to a liquid” means that the liquid takes a state in which oxygen is taken, and in a state in which the liquid takes up oxygen, molecules or atoms constituting the liquid are oxygen molecules or oxygen atoms. And a state in which oxygen is physically taken into a liquid without a chemical bond (a so-called dissolved state).

[0006] Based on such findings, the use of an artificial lung used for oxygenating blood was examined as a device for oxygenating replacement fluid. Commercially available artificial lungs generally used for oxygenating blood have a structure in which hollow fibers are arranged in a housing, so that oxygen passes through the hollow fibers and blood passes through the outside of the hollow fibers inside the housing. It has become. Then, the oxygen and the blood come into contact via the hollow fiber, whereby the blood is oxygenated. In an artificial lung, blood is not passed through a hollow fiber. This is due to the fact that the blood has a high viscosity and is difficult to pass through the hollow fiber, and that blood coagulation occurs in the hollow fiber and blood may not be able to pass. However, in such a contact mode, the ratio of oxygen to blood (that is, the liquid passing outside the hollow fiber) is insufficient, and the blood (or liquid) in the entire housing may not be sufficiently oxygenated.

[0007] The artificial lung often has heating means such as a pipe-shaped heat exchanger made of aluminum or stainless steel so that oxygenated blood can be heated and returned to the body. Due to the presence of such heating means, the weight and size of the oxygenator are increased, and it is not always easy to handle the oxygenator. Thus, a commonly used artificial lung is not always suitable for oxygenating a liquid other than blood, for example, a replacement fluid used in bloodless treatment, in terms of oxygenation efficiency and handleability.

[0008] Oxygenation of liquids is also effective in hypothermia. Hypothermia refers to performing a necessary treatment in a state where the subject is kept at a low temperature by supplying a cooled fluid to the subject or cooling the subject or the whole body. In this hypothermia therapy, not only oxygenation of the replacement fluid but also carbonation can effectively prevent the tissue of the treatment target (for example, brain) from necrosis,
It has also been found that oxygen utilization efficiency in the subject (eg, brain) is improved.

The present invention has been made based on a new concept of adding oxygen to a subject and optionally adding carbon dioxide to a subject when performing a surgical procedure on a subject in a bloodless manner. Provided is a liquid gas adding device that can be preferably used to realize the idea, and a bloodless treatment device incorporating the liquid gas adding device.

[0010] In a first aspect, the present invention is a liquid gas adding apparatus for adding a liquid by bringing the liquid into contact with a gas, wherein (1) a plurality of hollow fibers; (2) a hollow fiber is accommodated. (3) a cap having a liquid inflow port provided at one end of the housing; (4) a cap having a liquid outflow port provided at the other end of the housing; and (5) a gas supply port. The liquid flows into the hollow fiber from the liquid inflow port, flows out of the liquid outflow port via the hollow portion of the hollow fiber, the gas is supplied into the housing from the gas supply port, and the liquid flows into the hollow fiber membrane. To provide a liquid gasification device that is gasified by contact with a gas via a liquid gasification device.

In this device, the liquid passes through the hollow fiber and gas exists around the hollow fiber, or in some cases, the gas passes between small holes formed in the side wall surface of the hollow fiber. The contact efficiency between the two is improved, and the gasification of the liquid is further promoted.

The term "adding a liquid to a gas" refers to a state in which a liquid takes in a gas. In a state in which a liquid takes in a gas, molecules or atoms constituting the liquid are converted into molecules of the gas or the molecules of the molecule. And a state where a gas is physically taken into a liquid without a chemical bond (a so-called dissolved state).

The liquid to be gasified by the apparatus is preferably of a low viscosity so that it can pass through the hollow fiber smoothly. Specifically, the liquid is pressurized, a saccharide, a protein amino acid preparation, blood Substitutes, artificial kidney dialysis agents,
Enzyme preparations, blood preparations, Ringer's solution (including Ringer's solution containing lactate Ringer's solution and low molecular weight dextrin), physiological saline, electrolyte solution, sodium bicarbonate solution, drugs (eg, anticancer agents), and enteral nutrition are suitable. Among them, a blood substitute, Ringer's solution or physiological saline is used as a replacement fluid supplied to a subject in a bloodless treatment. A solution of baking soda (eg, an aqueous solution) is used to adjust the pH of the liquid supplied to the subject.

The gas supplied to the liquid by the liquid gas adding apparatus of the present invention is selected appropriately according to the treatment target, and is generally oxygen. In hypothermia, especially in hypothermia for brain trauma, the fluid supplied to the brain is preferably added to carbon dioxide in addition to oxygenation, in which case the liquid gasifier of the present invention uses oxygen and carbon dioxide. Is preferably supplied to the liquid. Alternatively, the liquid gasification device of the present invention may be a liquid carbonation device for supplying only carbon dioxide to a liquid. The liquid carbon dioxide adding device can be used, for example, when a sufficiently oxygenated liquid is further carbon dioxide added.

The liquid gas adding apparatus of the present invention may be supplied with only the gas to be taken in by the liquid. Alternatively, a mixed gas of such a gas and another gas may be supplied. For example, in the case where oxygen is added to a liquid, a mixed gas obtained by mixing oxygen and air is added to the liquid and oxygen is added. In this case, a mixed gas obtained by mixing oxygen and carbon dioxide and air may be supplied. When a liquid is added to carbon dioxide, a mixed gas obtained by mixing carbon dioxide and air may be supplied. Or
If the liquid is oxygenated and / or carbon dioxide added, only air may be supplied to the liquid gasifier.

[0016] The liquid gasifier of the present invention is preferably used in combination with a bloodless treatment device used in surgical treatment of a subject. Therefore, according to the second aspect, the present invention provides (A) a replacement fluid supply unit for measuring and injecting replacement fluid into a blood vessel flowing into a subject, and (B) measuring and deriving replacement fluid passing through the subject from a blood vessel flowing out of the subject. Provided is a blood-free treatment device including a rehydration derivation unit and (C) a liquid gasification device of the present invention for gasifying a replacement fluid to be injected.

In the bloodless treatment apparatus of the present invention, “measurement / injection” means supplying a predetermined amount or flow rate to a blood vessel, and “measurement / delivery” means
This means removing a predetermined amount or flow rate from a blood vessel. The rehydration fluid may also include components that have a favorable effect on the subject and / or the surgical procedure.
For example, the replacement fluid is usually based on water and may include electrolytes, nutrients, stabilizers and the like. Particularly preferred replacement fluids are stable at 20 to 50 ° C. For example, it is preferable to use Ringer's solution, Ringer's lactate solution, Ringer's solution containing low-molecular-weight dextrin (for example, containing 5%), particularly the L-form type as a replacement fluid.

The bloodless treatment apparatus of the present invention is particularly preferably used for performing hypothermia for brain injury.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The liquid gas adding apparatus of the present invention may have basically the same structure as a dialyzer (dialyzer). In that case, gasification of the liquid can be performed by supplying a liquid instead of blood and a gas instead of dialysate. However, the specifications of the hollow fiber, the housing, and the like are appropriately changed so as to be optimal for gas supply of the liquid.

The hollow fiber constituting the liquid gas adding apparatus of the present invention is a tubular yarn formed of a porous wall (or a porous membrane) defining a tubular hollow portion. The contact between the liquid in the hollow fiber and the gas located outside the hollow fiber is ensured. Specifically, the hollow fiber is polysulfone, polymethyl methacrylate, polyacrylonitrile, ethylene vinyl alcohol, polyamide or polyester polymer alloy, polyethylene-urethane-polyethylene, polyethylpentene, polypropylene, dimethylsiloxane, polypropylene-siloxane, or It is made of polypropylene-fluorine and has a wall thickness (or film thickness) of about 5 to 100 μm and an inner diameter of 100 to 30.
About 0 μm and a pore diameter of 3 nm communicating with the hollow part
It is preferable that a large number of pores (small holes) of 100 nm are formed on the wall so as to have a porosity of 20 to 60%. In the liquid gas addition apparatus of the present invention, for example, the trade name CA
PIOX II (manufactured by Terumo), trade name QUADROX
(JOSTRA) can be used. In addition to those listed here, for example, hollow fibers used in artificial lungs and dialyzers can be appropriately used.

The number of hollow fibers arranged in one housing is selected such that the liquid is oxygenated at the desired flow rate through the liquid gasifier. Generally, when injecting a replacement fluid into a blood vessel flowing into a subject in order to perform a surgical procedure on the subject in a bloodless manner, the replacement fluid is preferably supplied and discharged at a flow rate of about 0.05 to 1 liter / minute. . In order to secure such a flow rate in the liquid gas addition device, an appropriate number of hollow fibers are selected according to the thickness of the hollow fiber so that the membrane area in one housing is about 0.3 to 2.5 m ^2. Preferably, the thread is located in the housing.

The hollow fiber preferably has a sufficient length so that a liquid passing through the hollow fiber at a predetermined speed can be sufficiently gassed. If the hollow fiber used has the aforementioned dimensions and the liquid flow rate through the liquid gasifier is maintained at 0.03 to 1 liter / min,
The length of the hollow fiber is preferably about 100 to 300 mm. In addition, the length of the hollow fiber referred to here means an effective length corresponding to a portion of the hollow fiber where the liquid and the gas in the hollow fiber come into contact with each other via the hollow fiber membrane. Does not include ends (including potting parts).

In the housing, the hollow fibers exist in a bundle shape in which a plurality of hollow fibers are bundled. Then, in the bundled hollow fiber, a potting portion is formed at an end on the side where the liquid flows, using a suitable potting material so that the liquid passes only inside the hollow fiber. The potting portion can be formed by using a potting material and a method which are conventionally adopted when manufacturing a filter (for example, a dialyzer) using a hollow fiber as a filter material. As the potting material, the same material as that used in manufacturing the dialyzer can be used, and for example, polyurethane or silicone rubber is preferable. The length of the potting portion can be appropriately selected according to the dimensions of the housing and the like, and may be formed, for example, so that the length is 20 to 50 mm. A similar potting portion is also formed at the end of the hollow fiber on the side from which the liquid flows. As a result, the position of the hollow fiber is fixed, and the liquid can smoothly flow out from the liquid outflow port described later.

The housing for accommodating the hollow fibers accommodates the hollow fibers and forms a space defined around the hollow fibers. The gas is sent into the space, and comes into contact with the liquid passing through the hollow fiber via the membrane constituting the hollow fiber.

The housing is preferably formed of, for example, a resin such as polycarbonate, polypropylene, or polyethylene. The housing is preferably a tubular body having a hollow portion so that a large number of hollow fibers in a bundled state can be accommodated, and the hollow fibers are uniformly arranged,
Further, it is particularly preferable that the hollow fiber has a cylindrical shape so that gas can be uniformly present around the hollow fiber. However, the shape of the housing is not particularly limited as long as the hollow fiber can be accommodated and a cap described later can be connected to both ends, and other shapes may be used in consideration of the purpose of use and handleability.

Further, it is preferable that the housing has a size capable of accommodating a plurality of hollow fibers in a bundled state and supplying a sufficient amount of gas. For example, length 30-400mm, diameter 20-80mm (thickness 3-20mm)
It is preferable that the hollow fiber can be arranged inside thereof.

In the liquid gas adding apparatus of the present invention, a cap having a liquid inflow port is provided at one end of the housing, and a cap having a liquid outflow port is provided at the other end of the housing. The cap having the liquid inflow port is a member for flowing the liquid into the hollow fiber, and the cap having the liquid outflow port is a member for taking out the gas-added liquid. The liquid inlet port is connected to, for example, a liquid supply source by a conduit (for example, a tube or the like). The liquid outlet port is connected to a tube used to supply a liquid to a required point.

The two caps are preferably attached so as to be liquid-tight with the hollow fiber potting portion in order to prevent leakage of the liquid. For this purpose, the cap may be fixed for example with an adhesive.

A gas supply port is provided for sending gas into the housing. This port can be integrally formed when the housing is formed. Alternatively, an opening may be provided on the side surface of the housing, and a gas supply port may be connected to the opening as a separate member. In any case, the gas supply port is preferably provided near the end of the housing provided with the cap having the liquid inflow port. Specifically, it is preferably provided near the end point of the potting portion (boundary portion between the potting portion and a portion other than the potting portion).

The gas supply port is connected to a gas supply source using a suitable conduit (for example, a tube or the like). The gas is supplied into the housing through the tube and the gas supply port, and contacts the liquid passing through the hollow fiber through the hollow fiber membrane to gasify the liquid.

The gas supply port is provided with a cap so that one port is assigned to each gas when the liquid is gasified with two or more gases, for example, when oxygen addition and carbon dioxide addition are performed simultaneously. May be provided in plurality. Alternatively, if there is one gas supply port, one tube of the Y-shaped tube is connected to the gas supply port, and the two tubes are respectively connected to a gas supply source (for example, an oxygen supply source and a carbon dioxide supply source). Then, the gas mixed in the Y-tube may be supplied from the gas supply port into the housing.

The liquid gas adding apparatus of the present invention may be one in which only the gas supply port is provided in the housing and there is no port corresponding to the outlet from which the gas is discharged. When using such a liquid gasification device, the amount of gas taken into the liquid during the gasification, that is, the gas corresponding to the amount of gas consumed by gasification of the liquid is continuously reduced. Preferably, the delivery and the predetermined amount of gas are present in the housing. In order to maintain the amount of gas in the housing at a predetermined amount, for example, a pressure gauge may be mounted in the housing and the gas may be continuously supplied so that the pressure gauge indicates a constant value. Alternatively, the gas may be supplied only when the pressure becomes lower than a predetermined value, in which case the supply of the gas is intermittent.

The liquid gas adding apparatus of the present invention may include a gas discharge port. When using such a liquid gasifier, gas is supplied into the housing from a gas supply port and is continuously discharged from a discharge port to form a "flow". The amount of gas discharged corresponds to the amount obtained by subtracting the amount of gas taken into the liquid during gas addition (that is, the amount of gas consumed by gas addition). That is, the gas not taken into the liquid is discharged from the gas discharge port. The discharged gas may be returned to the gas supply port for reuse.

When liquid is added by the liquid gas adding apparatus of the present invention, the partial pressure of the gas to be taken into the liquid in the housing is appropriately selected according to the type of the liquid, the object to which the liquid is supplied, and the like. For example, when oxygenation and / or carbon dioxide is added to a replacement fluid in a bloodless treatment, the partial pressure of oxygen and / or the partial pressure of carbon dioxide in the housing is 1.3 × 10 ^{2 to} 8.0 × 10 ³ Pa (1 ~ 60
mmHg).

In the liquid gasification apparatus of the present invention having the above configuration, the liquid to be gasified passes through the hollow fiber having a large specific surface area, so that the gasification efficiency of the liquid is improved.
Therefore, according to the present invention, it is possible to obtain a liquid oxygenator having a smaller overall size than a conventional oxygenator that allows a liquid to pass outside the hollow fibers. In addition, if the temperature of the supplied gas is adjusted to be the same as the temperature of the liquid passing through the hollow fiber while performing the gas addition by the apparatus of the present invention, it is possible to suppress the temperature change of the liquid, Can be adequately controlled even when the temperature control is required. Further, since the gas flow acts as a kind of heat insulating material together with the housing, the liquid passing through the hollow fiber is hardly affected by the temperature outside the housing.

FIG. 1 shows a side view of an example of a liquid oxygenator which is an embodiment of the liquid gas supplier of the present invention, and FIG. 2 shows a cross-sectional view in the longitudinal direction. As shown in FIG. 1, the liquid oxygenator includes a housing (1), a joint-shaped tubular liquid inflow port (2a).
And a cap (3) having a joint tubular liquid outflow port (3a), and an oxygen supply port (4) formed integrally with the housing.
As shown in FIG. 2, a plurality of hollow fibers (5) are arranged in a bundle in a housing (1), and upper and lower ends thereof are solidified by a potting material to form a potting portion (5a). are doing. The liquid to be oxygenated flows into the hollow fiber (5) via the liquid inflow port (2a), and flows out of the liquid outflow port (3a). Oxygen is supplied from the oxygen supply port (4) into the housing (1). Accordingly, the liquid is contacted with oxygen via the membrane of the hollow fiber (5) in the region indicated by A in FIG. 2 to be oxygenated.
The illustrated device is capable of continuously supplying an amount of oxygen corresponding to the amount of oxygen taken into the liquid by adding oxygen, and does not include an oxygen discharge port.

The liquid gas adding apparatus of the present invention may use, for example, a dialyzer as it is. In this case, the liquid may be supplied from the port through which blood flows, and the gas may be supplied to the port through which dialysate is supplied. Alternatively, the liquid gas adding apparatus of the present invention can be assembled using a dialyzer or plasma separator assembly line by using a part of the members used for the dialyzer or plasma separator. No special equipment is required, and therefore it can be manufactured at low cost.

The liquid gas adding apparatus of the present invention is a bloodless treatment apparatus used for surgical treatment of a subject, and comprises (A) a replacement fluid supply unit for measuring and injecting replacement fluid into a blood vessel flowing into the subject, and (B) It can be used in combination with a bloodless treatment device having a replacement fluid deriving unit that measures and derives replacement fluid that has passed through a subject from a blood vessel flowing out of the subject. In the bloodless treatment apparatus, the liquid gasifier of the present invention is used to gasify replacement fluid to be injected into a subject. Therefore, it is preferable that the liquid gas adding device be disposed at a position where the replacement fluid can be added before the replacement fluid that has passed through the supply unit is injected into the blood vessel flowing into the subject.

FIG. 3 schematically shows a blood-free treatment apparatus incorporating a liquid oxygenator according to one embodiment of the present invention. The bloodless treatment device includes a rehydration container (1) as a rehydration supply unit (12).
4) and a rehydration fluid supply pump (16) for supplying rehydration fluid to the target organ (30) (with the function of measuring and adjusting the volume of fluid delivered), and a rehydration derivation unit that is a part of the body (32) It has a rehydration pump (20) for deriving a rehydration fluid that has passed through the object from a blood vessel (36) flowing out from the (30). The liquid oxygenator (10) of the present invention is provided between the replacement fluid supply unit (12) and the object (30), and the oxygenated liquid is supplied to the object (30) via the blood vessel (34). Is to be injected. The components are connected by an appropriate conduit (for example, a silicone tube, a PVC tube, or the like).

The bloodless treatment apparatus shown in the drawings is schematic, and is used together with other elements not shown in actual use. For example, a heat exchanger may be provided between the replacement fluid supply pump and the liquid gas adding device of the present invention so that the temperature of the replacement fluid can be adjusted. Further, a drip chamber for removing the foam of the replacement fluid may be provided between the replacement fluid container and the replacement fluid supply pump. The detailed description of the bloodless treatment apparatus is described in detail in the specification and the drawings of International Publication WO00 / 47251, and the contents described in the specification and the drawings form a part of the present specification by reference.

The liquid gas adding apparatus of the present invention may be used in combination with two or more in a bloodless treatment apparatus. For example, in the case of adding oxygen and carbon dioxide to a liquid, one liquid gas adding device is used as a liquid oxygen adding device, and one liquid gas adding device is used as a liquid carbon dioxide adding device. After oxygenating the liquid, the liquid flowing out of the liquid outflow port of the liquid oxygenator is introduced into the liquid inflow port of the liquid carbonizer, carbon dioxide is added, and the liquid added with oxygen and carbon dioxide is added. The liquid may be discharged from the liquid discharge port of the carbon dioxide adding device.

In the above description, an example was shown in which the liquid gas-supplying device of the present invention was incorporated into a bloodless treatment device. However, the gas-supplying device of the present invention cannot be used only in bloodless treatment. Auxiliary), heart drive control (pulse output control), and organ transplantation can be conveniently used.

[0043]

As described above, the liquid gasifier according to the present invention has a structure in which the liquid to be gasified passes through the hollow fiber and the gas exists around the hollow fiber. Can be efficiently contacted with each other, and has high gas capacity. Therefore, if the liquid gasification device of the present invention is used as a liquid oxygenation device, oxygenation can be performed with an efficiency equal to or higher than that of a general oxygenator even if the overall size is reduced. Further, since the liquid gas heating device of the present invention does not incorporate a heating mechanism such as a heat exchanger attached to a general artificial lung, the liquid gas heating device of the present invention is lightweight and easy to handle. . Accordingly, the liquid gasifier of the present invention is an element for gasifying the replacement fluid supplied to the subject, specifically, oxygen, when using a bloodless treatment device for supplying replacement fluid to the subject during a surgical operation on the subject. It can be conveniently used as an additional element.

[Brief description of the drawings]

FIG. 1 is a side view of an example of a liquid oxygenator which is an embodiment of the liquid gas supplier of the present invention.

FIG. 2 is a sectional view of the liquid oxygenator of FIG.

FIG. 3 is a schematic view of an example of the bloodless treatment apparatus of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Housing, 2 ... Cap, 2a ... Liquid inflow port, 3 ... Cap, 3a ... Liquid outflow port, 4 ...
Gas (oxygen) supply port, 5 ... hollow fiber, 5a ... potting section, 10 ... liquid gas adding device (liquid oxygen adding device), 1
2 ... Fluid supply unit, 14 ... Fluid container, 16 ... Fluid supply pump, 20 ... Fluid discharge pump, 30 ... Target, 32 ... Body, 34 ... Blood vessels, 36 ... blood vessels.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) A61M 1/14 580 A61M 1/14 580 B01D 63/02 B01D 63/02 F-term (Reference) 4C077 AA05 BB01 CC02 CC04 DD16 EE02 EE03 EE04 GG08 GG09 HH02 HH06 HH15 JJ02 JJ04 JJ16 KK03 4D006 GA35 HA02 JA15A KE01Q MA01 MB03 MC22 MC23 MC28 MC34 MC36 MC39 MC48 MC53 MC54 MC62 MC65 PA10 PB62 PB63 PC48 4G035 AB05 AE

Claims (9)

[Claims] 1. A liquid gas adding device for adding a liquid by bringing the liquid into contact with a gas, wherein: (1) a plurality of hollow fibers; (2) a housing for accommodating the hollow fibers; (3) one end of the housing. (4) a cap having a liquid outflow port, provided at the other end of the housing; and (5) a gas supply port, wherein the liquid is supplied from the liquid inflow port. The gas flows into the hollow fiber, flows out of the liquid outlet port via the hollow portion of the hollow fiber, and the gas is supplied from the gas supply port into the housing. The liquid contacts the gas through the hollow fiber membrane. Liquid gasifier that is gasified by the 2. The liquid gasification apparatus according to claim 1, wherein an amount of gas corresponding to an amount of gas taken into the liquid is supplied from the gas supply port while the gasification is being performed. 3. A gas discharge port, wherein the gas is continuously supplied from the gas supply port into the housing during the gas addition, and the gas is supplied in an amount corresponding to the amount of gas taken into the liquid. The liquid gas processing apparatus according to claim 1, wherein an amount of gas obtained by subtracting from the amount of supplied gas is continuously discharged from the gas discharge port. 4. The apparatus according to claim 1, wherein the gas contains oxygen and the liquid is oxygenated. 5. The liquid gas addition apparatus according to claim 1, wherein the gas contains carbon dioxide, and the liquid is added with carbon dioxide. 6. The liquid gasification apparatus according to claim 1, wherein the gas contains oxygen and carbon dioxide, and the liquid is added with oxygen and carbon dioxide. 7. The liquid gas adding apparatus according to claim 4, wherein the gas is air. 8. The liquid to be gasified is a pressurizing agent, a saccharide agent,
One or more liquids selected from protein amino acid preparations, blood substitutes, artificial kidney dialysis preparations, enzyme preparations, blood preparations, Ringer's solution, physiological saline, electrolyte solutions, sodium bicarbonate solutions, drugs and enteral nutritional supplements The liquid gas adding device according to any one of claims 1 to 7. 9. A bloodless treatment apparatus used in a surgical treatment of a subject, comprising: (A) a replacement fluid supply unit for measuring and injecting replacement fluid into a blood vessel flowing into the subject; and (B) a fluid replacement unit for measuring the fluid from the blood vessel flowing out of the subject. A bloodless treatment apparatus comprising the liquid replenishment deriving unit for measuring and deriving the replenisher that has passed therethrough, and (C) the gas replenishing device according to any one of claims 1 to 8, for gasifying the replenisher to be injected.