RU2422160C1 - Disposable hemosorption column temos-ks - Google Patents

Abstract

FIELD: medicine, pharmaceutics.

SUBSTANCE: invention relates to medical equipment. Column contains case, upper and lower lids, connecting pipes, caps, hemosorbent and filters. In upper lid installed is air-duct, whose one end is connected with upper lid, external end being provided with connecting pipe. Lower lid, whose internal part is made cylindrical, contains passing through it branch pipe, on whose upper surface lock element is located. Lower part of branch pipe is provided with inlet connecting pipe. Hole is hermetically closed by elastic puncture-proof material Outlet connecting pipe is located on periphery of lower lid. All connecting pipes interact with detachable caps by means of sealing connection Luer-lock. Outlet filter is installed into internal cylindrical part of lower lid and is made from material, which has open-cell elastic polyhedral three-dimensional structure with porosity to 98%, size of whose pores is less than size of sorbent granules. Branch pipe passes through said filter. In case installed is interaction with it membrane, located between upper lid and butt end of upper part of branch pipe and having at least one hole, whose size is smaller than size of sorbent granules. Sorbent is located between membrane and outlet filter and is in column in moisturised state in air medium, which has humidity from 90% to 100%, or under layer of liquid.

EFFECT: invention makes it possible to reduce hydrodynamic resistance and increase safety.

18 cl, 1 dwg

Description

The invention relates to medical equipment and can be used in devices for extracorporeal detoxification of blood, plasma, lymph and other biological fluids.

Known disposable hemosorption column containing a housing, covers, fittings with caps and filters located between the housing and the covers. The column contains hemosorbent in physiological saline (Nikolaev V.G. "The method of hemocarboperfusion in the experiment and the clinic", Kiev: "Naukova Dumka", 1984, p. 68-69).

The column has a complex structure with many connections. There is a high likelihood of leaks in the connections of the housing with the covers, as well as the conical parts of the housing to each other, which reduces the safety of its use.

Also known is a disposable tubular filter element, closed on one side, in which the filter is made of non-woven material and is located at an angle to the direction of blood flow (AS USSR No. 1524902, class A61M 1/36, 1989).

Due to the use of non-woven material, the device has a high hemodynamic resistance.

The closest in technical essence and the achieved result is a disposable hemosorption column containing a mass exchanger housing with expanded parts at the ends, covers, seals, inlet and outlet capillary filters and a hemosorbent located between them (Utility Model Patent of the Republic of Belarus BY No. 800 U, A61M 1 / 36, 2003 - prototype).

The disadvantages of this device is due to the use of capillary filters, high hydrodynamic resistance, causing rapid thrombosis, low mass transfer efficiency of the column, reducing the quality of detoxification.

The technical result achieved by using the proposed column is to reduce the hydrodynamic resistance, reduce the number of filters, as well as improve the conditions and safety of the detoxification procedure.

The named technical result is achieved in that in a disposable hemosorption column containing a housing, upper and lower covers, fittings, caps, hemosorbent and filters, an air duct with a fitting is installed in the upper cover, the lower cover, the inside of which is made cylindrical, contains a pipe passing through it , on the upper part of which a locking element is located, and the lower part of the nozzle is equipped with an inlet fitting, an opening hermetically sealed with elastic self-tightening material, the outlet fitting is located located on the periphery of the lower cover, a filter mounted in the inner cylindrical part of the lower cover. The filter is made of a material having an open-cell elastic polyhedral volumetric structure with porosity up to 98%, the pore size of which is smaller than the sorbent granules, and the pipe passes through this filter. All fittings interact with removable caps by means of a Luer-lock sealing connection. A membrane interacting with it is installed in the housing, located between the top cover and the end face of the upper part of the pipe and having at least one hole smaller than the size of the sorbent granules. The sorbent is located between the membrane and the filter and is in the column in a humidified state in an air environment having a humidity of 80% to 100%, or under a layer of liquid.

It is also proposed to equip the duct with a non-return valve or a hydrophobic air filter, each of which interacts with removable caps through the Luer-lock sealing connection. It is useful to make the duct from an elastic tube and install a clamp on it that covers the duct.

It is proposed to use a non-return valve, in particular a Bunsen valve, or a filter, the pores of which are smaller than the sorbent granules, or an elastic open-cell polyhedral structure, placing it inside the upper part of the pipe, as a shut-off element of the pipe. It is also useful to place the nozzle in the center of the bottom cover and direct it along the axis of the housing, install the end of the nozzle above the level of the sorbent or above the layer of liquid covering the sorbent, the inside of the nozzle should be made in the form of a solid tube, and the lower part should be in the form of an elastic tube.

It is proposed to connect the outlet fitting to the bottom cover through an elastic tube.

It is also proposed that the output filter be made in the form of a disk with an opening for a nozzle whose diameter is equal to or less than the outer diameter of the nozzle, and the diameter of the disk is greater than or equal to the diameter of the inner cylindrical part of the lower cover into which this filter is installed, and the thickness of the disk should be at least the order is larger than the pore size of this disk.

It is advisable to make the output filter composite, i.e. assembled from two or more adjacent discs. Moreover, the disk in contact with the sorbent provides selectivity and has smaller pores and a smaller thickness than the lower disk, which acts as a substrate.

It is also proposed that the output filter be made of a hydrophilic material, and as a liquid filling the column, use a 0.9% isotonic sodium chloride solution or distilled water.

It is convenient to make the column body transparent and apply a scale of the volume of filling with sorbent and liquid on it.

In addition, it is proposed that the membrane interacting with the housing be made of an elastic material and installed with the possibility of moving along the housing and self-fixing at a given level.

The introduction of the duct into the top cover allows you to quickly fill the column with liquid and remove by displacement the air entering it from the extracorporeal circuit when filling, as well as the air released in the form of bubbles from the liquid and accumulating in the column during the detoxification procedure. The presence of residual air in the column reduces safety and increases the thrombogenicity of the blood detoxification procedure.

Installing a non-return valve or a hydrophobic air filter with standard pores of 1.2 μm on the duct retains the sterility of the column when removing air from it, as it prevents the possibility of external air entering the column. The presence of an elastic duct tube and a clamp on it allows you to quickly block the duct at the end of filling. All this improves the conditions of the procedure and increases its safety.

The use of the Luer-lock cone-screw sealing connection, made according to the ISO standard for fittings with removable caps, eliminates the need for additional seals.

The presence of a nozzle in the bottom cover, through which liquid enters the upper part of the column, allows us to abandon the inlet filter of the sorbent granules, restrict ourselves to a single outlet filter, and thereby significantly reduce the column hydrodynamic resistance, since it is the filters that create the greatest obstacle to the flow.

The installation in the upper part of the nozzle of a shut-off element made in the form of a check valve or filter with pores that are smaller than the sorbent granules, or of an elastic open-cell polyhedral structure self-fixing inside the nozzle, prevents the sorbent granules from entering the nozzle and, therefore, into the extracorporeal circuit, thereby increasing safety detoxification procedures.

If a Bunsen valve is installed in the upper part of the nozzle, which is an elastic tube closed at one end and having at least two slotted symmetrical slots located along the axis of the tube, then the liquid will enter the column with symmetrical flows, thereby improving the mass transfer characteristics of the column.

The hole in the bottom cover, hermetically sealed with elastic self-tightening material, allows you to repeatedly inject drugs and an anticoagulant into the column during the detoxification procedure with a needle and syringe, while maintaining the sterility and integrity of the column. Using a syringe with a needle, it is also possible to extract fluid samples from the column and judge the degree of detoxification from them. These features allow you to monitor the parameters of the procedure, correct them in time and prevent, for example, early thrombosis. The controllability of the procedure improves and its safety increases.

Installing the nozzle in the center of the bottom cover, its axial location and finding the end of the nozzle above the liquid allows you to evenly distribute the liquid over the sorbent, and the presence of a layer of liquid covering the sorbent prevents the collision of the sorbent granules and the formation of dust particles.

The design of the inlet fitting of the nozzle and the outlet fitting of the bottom cover in the form of elastic tubes facilitates the connection of the column to the extracorporeal circuit.

The filter installed in the bottom cover and made of a material having an open-cell elastic polyhedral volumetric structure, has a maximum porosity among the known filters, reaching up to 98%, and a minimum hydrodynamic resistance. In addition, the sorbent granules adjacent to the filter pores, having mainly a dodecahedral mesh structure consisting of 12 faces, can physically overlap a small number of faces, leaving most of the faces free for liquid flow. The latter properties, coupled with the hydrophilicity of the material, provide the minimum hydrodynamic resistance of a pair of sorbent granules - filter.

It is technologically simple to make the filter in the form of a disk with a hole in the middle and install it in the bottom cover of the column. Moreover, if the hole size is less than the outer diameter of the nozzle, and the diameter of the disk is larger than the diameter of the cylindrical part of the lower cover, then due to the elasticity of the material, the filter is reliably fixed by surprise. Sorbent granules cannot penetrate the outlet nozzle even with intense transport shaking.

A composite filter, consisting, for example, of two adjacent disk filters, has high selectivity with respect to the sorbent granules and low hydrodynamic resistance, if the filter adjacent to the sorbent has smaller pores and small thickness compared to the second disk filter acting as the substrate.

The elastic properties of the porous material of the disk filter allow, when it is installed in a compressed state in the lower cover, to reduce the pore size up to 3 times due to the fact that its diameter is larger than the inner diameter of the lower cover. It becomes possible to reliably hold both large and small sorbent granules using the same material for the manufacture of filters of different pore sizes. Filling the column with a sorbent with fine granules increases its sorption capacity. The range of particle size distribution of sorbents with which the same column can be filled without a significant increase in its hydrodynamic resistance and the breakthrough of small sorbent granules into the extracorporeal circuit is expanding.

Filling the column with a sorbent in a humidified state and being in an air environment with high humidity from 80% to 100% due to the coalescence of the sorbent granules prevents the formation of fine dusty particles of the sorbent during manipulations with the column and transport shaking. In addition, the weight of the column is reduced.

The presence in the column of a 0.9% isotonic solution of sodium chloride or distilled water reduces the degree of abrasion of the sorbent granules under dynamic loads on the column. Following the leaks, you can visualize the depressurization of the columns, if it occurred after sterilization, transportation and other influences. The selection of usable speakers is simplified.

The transparent material of the case and the scale applied to it allow you to monitor the filling of the column with liquid, air removal, flows of detoxified liquid, as well as control the volume of filling the column with a sorbent.

A membrane installed in the column housing between the top cover and the sorbent and having at least one hole whose diameter is smaller than the size of the sorbent granules prevents these granules from entering the duct and blocking the duct.

The drawing shows a diagram of the column, where 1 is the cap of the duct, 2 is the fitting of the duct, 3 is the duct, 4 is the top cover, 5 is the body, 6 is the membrane, 7 is the hole in the membrane, 8 is the shut-off element, 9 is the fluid, 10 - sorbent, 11 - nozzle, 12 - output filter, 13 - lower cover, 14 - flexible self-tightening material, 15 - hole, 16 - outlet fitting, 17 - nozzle fitting, 18 - nozzle caps, 19 - fluid inlet, 20 - outlet liquids. The arrows indicate the direction of fluid flow.

The column is made of biocompatible, hypoallergenic, pyrogen-free and non-toxic polymeric materials, sterile, single use.

The column operates as part of the extracorporeal circuit of apparatus for detoxifying body fluids as follows. The column is connected to the in-line system of the extracorporeal circuit at a point located between the pump and the air trap. To do this, removing the caps 18, the fitting of the pipe 17 is connected to the fitting of the line supplying fluid from the pump of the device to the column. The outlet outlet 16 is connected to the union of the line of the line that drains the liquid from the column. The column is positioned vertically.

Before the detoxification procedure, the column is filled with a sterile liquid, for example, saline. The column is filled and air is displaced from it as follows. Overlap the line of the line, the discharge fluid from the column. Open the cap 1, turn on the pump of the device and from the container with saline solution, saline solution is first supplied to the highway, then to the column. The liquid displaces the air from the line and the column through the duct 3. When the air from the column is completely removed, close the cap 1 and open the line of the line, the discharge fluid from the column. Continue to displace air from the rest of the extracorporeal circuit. After filling the extracorporeal circuit, the column is washed to drain. When flushing is complete, stop the pump. If blood detoxification is carried out, then with the help of catheters the extracorporeal circuit is connected to the veins, an anticoagulant is introduced and the pump is started. Blood, interacting with the sorbent, moves in a column from top to bottom. When blood passes through the column, toxic substances are extracted from it, which are fixed on the sorbent granules. Detoxified blood is returned to the vein.

If air bubbles accumulate in the column during the procedure, they are removed by opening cap 1. Medicines and, if necessary, an anticoagulant are sterilely introduced into the column by means of a needle and syringe through an elastic self-tightening material covering the hole 15 in the bottom cover 13. Sampling for diagnostic or research purposes are carried out in a similar manner, also using a syringe with a needle. At the same time, the sterility and tightness of the extracorporeal circuit is maintained.

The proposed column reduces the hydrodynamic resistance of the extracorporeal circuit, improves the conditions and increases the safety of detoxification procedures of body fluids.

Claims (18)

1. Disposable hemosorption column comprising a housing, upper and lower covers, fittings, caps, hemosorbent and filters, characterized in that an air outlet is installed in the upper cover, one end of which is connected to the upper cover, and the outer end is provided with a fitting, lower cover, inner the part of which is made cylindrical, contains a pipe passing through it, on the upper part of which a locking element is located, and the lower part of the pipe is equipped with an inlet fitting, a hole tightly closed by elastic self-tightening with the material, an outlet fitting located on the periphery of the bottom cover, all fittings interacting with removable caps by means of a Luer-lock sealing connection, an output filter installed in the inner cylindrical part of the bottom cover and made of a material having an open-cell elastic polyhedral volumetric structure with porosity up to 98%, the pore size of which is smaller than the size of the sorbent granules, and the pipe passes through this filter, a membrane interacting with it is installed in the housing, located laid between the top cover and the end of the upper part of the nozzle and having at least one hole smaller than the size of the sorbent granules, the sorbent is located between the membrane and the outlet filter and is in the column in a humidified state in an air environment having a humidity of 90 to 100%, or under a layer of liquid. 2. The column according to claim 1, characterized in that a check valve is installed at the outer end of the duct interacting with the removable cap by means of a Luer-lock sealing connection. 3. The column according to claim 1, characterized in that a hydrophobic air filter is installed at the outer end of the duct, interacting with a removable cap by means of a Luer-lock sealing connection. 4. The column according to claim 1, characterized in that the duct is made of an elastic tube on which a clip is installed that overlaps the duct. 5. The column according to claim 1, characterized in that a check valve, in particular a Bunsen valve, is used as the shutoff element of the pipe. 6. The column according to claim 1, characterized in that a filter is used as a shutoff element of the nozzle, the pore size of which is smaller than the size of the sorbent granules. 7. The column according to claim 6, characterized in that the filter is made in the form of self-sealing inside the upper part of the pipe elastic open-cell polyhedral volumetric structure. 8. The column according to claim 1, characterized in that the upper part of the pipe located inside the housing is made in the form of a solid tube, and the outer part is in the form of an elastic tube. 9. The column according to claim 1, characterized in that the pipe is located in the center of the lower cover and is directed along the axis of the housing. 10. The column according to claim 1, characterized in that the end face of the upper part of the pipe is located above the level of the sorbent. 11. The column according to claim 1, characterized in that the end face of the upper part of the nozzle is located above the liquid level covering the sorbent. 12. The column according to claim 1, characterized in that the outlet fitting is connected to the bottom cover through an elastic tube. 13. The column according to claim 1, characterized in that the output filter is made in the form of a disk with an opening whose diameter is less than or equal to the outer diameter of the nozzle, and the diameter of the disk is greater than or equal to the diameter of the inner cylindrical part of the lower cover, the disk thickness is at least an order of magnitude larger than the average pore size of the output filter. 14. The column according to claim 1, characterized in that the output filter consists of two or more disks adjacent to each other, moreover, the disk in contact with the sorbent provides selectivity and has smaller pores and a smaller thickness than the second disk, which acts as a substrate. 15. The column according to claim 1, characterized in that the output filter is made of hydrophilic material. 16. The column according to claim 1, characterized in that the liquid used is a 0.9% isotonic sodium chloride solution or distilled water. 17. The column according to claim 1, characterized in that the casing is made of transparent material and has a scale of the column filling volume with sorbent and liquid. 18. The column according to claim 1, characterized in that the membrane is made of elastic material and is mounted with the possibility of movement along the body and self-fixation at a given level.

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