Tubing adapter for influencing the pressure inside a tubing section during a medical treatment

Abstract

A tubing adapter for interconnection with a least one tubing section of a medical device, a dialysis fluid tubing system including such a tubing adapter, a medical device including such a dialysis fluid tubing system, and a method for avoiding a pressure within a dialysis fluid tubing system that is below a minimum pressure are described.

Claims

1. A dialysis fluid tubing system, comprising: a first tubing section configured to interconnect with a heating device or comprising a heating bag; a pumping section configured to interconnect with a pump and arranged upstream of the first tubing section; and at least one of: (a) at least one tubing adapter comprising at least one of: (i) at least one locking mechanism for blocking a flow-through lumen; or (ii) a device for generating or amending a flow resistance of the at least one tubing adapter or of a second tubing section of the dialysis fluid tubing system connected to the at least one tubing adapter, wherein the at least one tubing adapter is configured to be arranged downstream of the first tubing section, wherein the at least one locking mechanism or the device for generating or amending a flow resistance is configured to prevent a pre-defined pressure upstream of the at least one tubing adapter, wherein the pre-defined pressure is a pressure below a pre-defined minimum pressure; and wherein the pre-defined minimum pressure is a pressure at which the first tubing section or the heating bag does not collapse; or (b) one tubing adapter integral with the dialysis fluid tubing system and comprising at least one of: (i) at least one locking mechanism for blocking a flow-through lumen; or (ii) a device for generating or amending a flow resistance of the one tubing adapter or of a second tubing section of the dialysis fluid tubing system connected to the one tubing adapter, wherein the one tubing adapter is arranged downstream of the first tubing section, wherein the at least one locking mechanism or the device for generating or amending a flow resistance is configured to prevent a pre-defined pressure prevailing upstream of the one tubing adapter, wherein the pre-defined pressure is a pressure below a pre-defined minimum pressure, and wherein the pre-defined minimum pressure is a pressure at which the first tubing section or the heating bag does not collapse.

2. The dialysis fluid tubing system according to claim 1, wherein the at least one tubing adapter or the one tubing adapter is or comprises at least one of a valve, a throttle or an aperture.

3. The dialysis fluid tubing system according to claim 1, wherein an opening pressure of the locking mechanism is between 5 hPa and 1000 hPa.

4. The dialysis fluid tubing system according to claim 1, wherein an opening pressure of the locking mechanism is between 50 hPa and 400 hPa.

5. The dialysis fluid tubing system according to claim 1, wherein an opening pressure of the locking mechanism is between 100 hPa and 350 hPa.

6. The dialysis fluid tubing system according to claim 1, wherein at least one of: the device for generating or amending the flow resistance of the at least one tubing adapter effects an amendment such that during use a pressure difference of between 5 hPa and 1000 hPa prevails over the device or over the at least one tubing adapter; or the device for generating or amending the flow resistance of the one tubing adapter effects an amendment such that during use a pressure difference of between 5 hPa and 1000 hPa prevails over the device or over the one tubing adapter.

7. The dialysis fluid tubing system according to claim 1, wherein at least one of: the device for generating or amending the flow resistance of the at least one tubing adapter effects an amendment such that during use a pressure difference of between 50 hPa and 400 hPa prevails over the device or over the at least one tubing adapter; or the device for generating or amending the flow resistance of the one tubing adapter effects an amendment such that during use a pressure difference of between 50 hPa and 400 hPa prevails over the device or over the one tubing adapter.

8. The dialysis fluid tubing system according to claim 1, wherein at least one of: the device for generating or amending the flow resistance of the at least one tubing adapter effects an amendment such that during use a pressure difference of between 100 hPa and 350 hPa prevails over the device or over the at least one tubing adapter; or the device for generating or amending the flow resistance of the one tubing adapter effects an amendment such that during use a pressure difference of between 100 hPa and 350 hPa prevails over the device or over the one tubing adapter.

9. The dialysis fluid tubing system according to claim 1, wherein the at least one tubing adapter is integral with the dialysis fluid tubing system.

10. The dialysis fluid tubing system according to claim 1, further comprising: at least one bag with dialysis fluid intended for flowing through the dialysis fluid tubing system; and the pump, wherein the pump is arranged for conveying the dialysis fluid in the dialysis fluid tubing system, wherein the at least one bag or the pump is connected to or intended for connection with the dialysis fluid tubing system.

11. The dialysis fluid tubing system according to claim 1, wherein the heating device or the heating bag is configured to heat dialysis fluid.

12. The dialysis fluid tubing system according to claim 11, wherein the heating device is configured to interconnect with the first tubing section or the heating bag.

13. A medical device for use with the at least one dialysis fluid tubing system according to claim 1.

14. The medical device according to claim 13, wherein the medical device is a blood treatment device or a dialysis device.

15. The dialysis fluid tubing system according to claim 1, wherein the first tubing section comprises the heating bag.

16. The dialysis fluid tubing system according to claim 1, wherein an opening pressure of the at least one locking mechanism is selected such that at least one of the container comprising dialysis fluid or the heating bag does not collapse.

17. A method of using the dialysis fluid tubing system according to claim 1, the method comprising: interconnecting the at least one tubing adapter with the dialysis fluid tubing system in fluid communication.

18. The method according to claim 17, wherein the at least one tubing adapter is interconnected with the dialysis fluid tubing system downstream of the heating device or the heating bag.

19. The method according to claim 17, further comprising: interconnecting the at least one tubing adapter with dialyser couplings of the dialysis fluid tubing system.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows schematically a tubing adapter according to the present invention having a non-return valve and two tubing connectors.

(2) FIG. 2 shows schematically a dialysis fluid tubing system according to the present invention with an integrated non-return valve.

(3) FIG. 3 shows schematically a medical device for dialysis according to the present invention with an extracorporeal blood circuit and a dialysis fluid tubing system according to the present invention.

DETAILED DESCRIPTION

(4) FIG. 1 shows schematically a tubing adapter 100 according to the present invention, which in this exemplary embodiment is intended for being connected with a tubing section 200 of a dialysis fluid tubing system 300 (see FIGS. 2 and 3).

(5) In this exemplary embodiment the tubing adapter 100 according to the present invention consists of a locking mechanism, which is embodied as a non-return valve 1 (below also referred to as valve 1) and which is illustrated as such, two tubing connectors 3, 5 and two optionally provided short tubing sections 7 of the tubing adapter 100. The tubing adapter 100 may comprise further components.

(6) In this exemplary embodiment the particular components of the tubing adapter 100 are firmly connected to each other, for example by bonding or ultrasound welding. However, the components may be releasably interconnected to each other as well. This is advantageous because at the site of its use the tubing adapter 100 can still be provided with tubing connectors 3, 5 in various sizes which can be connected to corresponding tubing connectors of tubing systems other than the tubing system 300 which is shown here.

(7) For connecting the tubing adapter 100, the tubing connectors 3, 5 are interconnected with tubing couplings of the dialysis fluid tubing system 300. Tubing connector 5 is embodied as a first coupling, here also referred to as male part or connector, and tubing connector 3 is referred to as female part or connector. In this exemplary embodiment, the female part of the coupling (tubing connector 3) is embodied identically to a corresponding tubing connector 3 of the known tubing section 200.

(8) The two tubing connectors 3, 5 are assembled or plugged into each other such that the dialysis fluid tubing system 300 is extended hereby by the uncovered or free length of the tubing adapter 100.

(9) With regard to FIG. 1, the dialysis fluid flows through the tubing adapter 100 from right to left during normal use of the tubing adapter. Valve 1 of tubing adapter 100 opensfor example against the force of a springif and when a minimum pressure prevails upstream of the valve 1, that is, on the right-hand side thereof with respect to FIG. 1.

(10) With reference to FIGS. 2 and 3, it is explained in more detail how the tubing adapter 100 or its valves 1 work.

(11) FIG. 2 shows the dialysis fluid tubing system 300 according to the present invention as part of a medical device 600 according to the present invention (see FIG. 3), which in this case or exemplary embodiment is a treatment system for dialysis. The medical device 600 further comprises an extracorporeal blood circuit 400 (shown as a section or cut here, see also FIG. 3), and also a dialyzer 11 which is being flown through by both fluids (blood and dialysis fluid) for exchange of substances.

(12) The dialysis fluid tubing system 300 which can be embodied as a single use tubing system (disposable) is being filled with dialysis fluid from a bag 9. The dialysis fluid is conveyed along the dialysis fluid tubing system 300 by a pump 13, which, by way of example only, is embodied as a roller pump. The dialysis fluid from bag 9 may flow into a heating device 14 which is arranged downstream of pump 13, that is, on the pressure side of pump 13, by gravity or by aspiration of the pump, or both. The heating device 14 shown in the figures isby way of exampleembodied as a device comprising at least a heating bag 15 and heating rods or heating spindles 17, for which reason it is herein also called a bag heater. The dialysis fluid is heated inside the heating bag 15. For ensuring that heat is transferred from the heating device 14 or the heating spindles 17 to the heating bag 15 it is helpful or maybe even necessary that compared to the atmosphere a positive pressure of the dialysis fluid prevails inside the heating bag 15. In this way, the wall of heating bag 15 nestles or adjusts to the heating spindles 17, thereby enabling or promoting the heat transfer. In other words, by a positive inside pressure, collapsing of the heating bag 15 and a deterioration or interruption of the heat transfer is avoided.

(13) The valve 1 is arranged further downstream of the pump 13 and downstream of the heating device 14. In this exemplary embodiment the valve 1 is also integrated into the tubing system 300. Therefore, FIG. 2 shows no tubing adapter 100 according to the present invention. Valve 1, being integrated as is shown here, therefore needs no tubing couplings such as are shown in FIG. 1. Alternatively, the valve 1 may be interconnected with a tubing system 300 as is shown in FIG. 1, the valve then being part of tubing adapter 100 according to the present invention.

(14) Valve 1 is arranged within the tubing system 300 such that it closes if the pressure upstream of valve 1, that is, between valve 1 and heating device 14 or heating bag 15, is too low. By closing, it is avoided that a pressure which is too low and which prevails downstream of valve 1 propagates upstream of valve 1 and into the heating bag 15 and possibly results in a negative pressure (related to the atmosphere) or in an inside pressure that is lower than desired. As already discussed above, a positive pressure inside the heating bag 15 is helpful for establishing or securing the desired or expected heat transfer.

(15) In certain exemplary embodiments according to the present invention, the opening pressure is between 5 and 1000 hPa, preferably between 50 and 400 hPa, particularly preferably between 100 and 350 hPa. That is, the inner pressure or inside pressure of the heating bag 15 must be at least as high as this value or must exceed a pressure downstream of the valve by at least this value for the valve 1 to open, if the flow loss occurring in the tubing section between the heating bag 15 and the valve 1 are not taken into account. In other words, the pressure upstream of valve 1 must be at least that high (between 5 am 1000 hPa, preferably between 50 and 400 hPa, particularly preferably between 100 and 350 hPa) or exceed by this value to overcome the opening pressure of valve 1.

(16) A lower pressure downstream of valve 1, and, in consequence, evacuating or sucking dry of the dialysis fluid further upstream up to the heating bag 15, may in practice have several reasons. This will be explained in more detail with regard to FIG. 3 making reference to a complete treatment system.

(17) FIG. 3 shows schematically a medical device 600 (also referred to as a treatment system) for dialysis, which in this exemplary embodiment according to the present invention is for the continuous veno-venous hemodiafiltration (a combination of hemofiltration and hemodialysis), also known as CVV-HDF, with an extracorporeal blood circuit 400, a substituate tubing system 500 and a dialysis fluid tubing system 300 according to the present invention.

(18) Blood is taken from the patient by an arterial connector 19 or an arterial line of the extracorporeal blood circuit 400. A stop-cock 21 is arranged downstream of the arterial connector 19. Downstream of the latter, the arterial pressure is measured by a pressure sensor 23; further downstream there is a blood pump 13. Between the blood pump 13 and the connector of the arterial line for connecting the arterial line with the dialyzer 11, the hemofiltration pressure is measured by a pressure sensor 25. Downstream of the pressure sensor 25, heparin is administered to the blood for anticoagulation at admission port 27.

(19) Within the dialyzer 11, substances are exchanged with the dialysis fluid of tubing system 300 which leaves the dialyzer 11 as dialysate. This will be further explained below.

(20) Downstream of the dialyzer 11, the blood flows in a venous drop chamber 29, in which the venous pressure is measured by a pressure sensor 31. A stop-cock 33 is arranged downstream thereof. The blood is returned into the vessels of the patient by a venous connector 35.

(21) The substituate tubing system 500 serves to partly substitute the fluid volume which was removed by filtration within the dialyzer 11 during treatment. To this end, substituate fluid from a bag 9 is used. The substituate is conveyed within the substituate tubing system 500 by a substituate pump 13 into a heating bag 15 where it is heated before it is fed into the blood circuit 400.

(22) The tubing system 300 upstream of the dialyzer 11 has already been explained with reference to FIG. 2. The filtrate pressure is measured downstream of the dialyzer 11 by a pressure sensor 37; further downstream, the dialysate istogether with the filtrateconveyed into a collecting bag 39 by a pump 13, or disposed.

(23) In the following, reasons for a low pressure downstream of valve 1 are discussed.

(24) A lower pressure (when compared to the atmosphere) downstream of valve 1, which would possibly result in evacuating or sucking dry of the heating bag 15 if there was no valve 1, may be caused by, for example, deposit on the filter membrane of the dialyzer 11 (on the membrane side of the blood circuit 400, for example, by blood that starts clotting). This results in a decrease of the permeability of the filter membrane in the dialyzer and also to an increased transmembrane pressure TMP.

(25) Regardless of this phenomenon, using filter membranes of low permeability may also result in this low pressure problem on the dialysis side of the dialyzer 11 (the same effect as with deposit on the membrane may occur here). Thus, a low permeability results in a high TMP for achieving a desired or requested exchange of substances in the dialyzer 11. When using filter membranes of low permeability, the tubing adapter 100 according to the present invention and/or the dialysis fluid tubing system 300 may, therefore, be used for avoiding a marked negative pressure and for ensuring an optimal, desired or expected heat transfer from the heating device housing to the heating bag 15.

(26) A pressure on the dialysis side that is possibly too low for the needs of the heating bag occurs particularly during continuous veno-venous hemodiafiltration (CVV-HDF) dialysis treatments, which require high filtration flow rates and a correspondingly high pressure gradient over the filter membrane, i.e., a high transmembrane pressure TMP.

(27) The pressure reference point for the area around the filter membrane of the dialyzer 11 is located in the area of the venous connector 35. The pressure reference point for the dialysis side is the pressure sensor 37. From there, the pressure of the dialysis side of the filter membrane (in the tubing system 300) may be tracked back by considering pressure differences caused by flow and by hydrostatic pressure differences. Accordingly, with a sufficiently high TMP, a pressure below atmosphere may prevail within the heating bag 15 and the heating bag may collapse if this is not avoided by, for example, using the tubing adapter 100 or the dialysis fluid tubing system 300 according to the present invention.