MEDICAL FLUID-LINE ARRANGEMENT AND MEDICAL ELASTOMERIC PUMP HAVING SUCH A FLUID-LINE ARRANGEMENT

Abstract

A medical fluid-line arrangement and a medical elastomeric pump having such a fluid-line arrangement. The fluid-line arrangement transfers a medical fluid between a medical elastomeric pump and a patient port. The fluid-line arrangement has a fluid-line channel with an inlet and an outlet. The inlet connects to an outlet of the elastomeric pump, and the outlet connects to the patient port. A throttle element is connected in a fluid-conducting manner to the inlet and outlet of the fluid-line channel. A portion of the fluid-line channel extends through the throttle element. The throttle element causes a narrowing of an active-flow cross section of the fluid-line channel. The throttle element is encapsulated at least partially in a thermally conductive body having a heat-absorption surface that is larger than an outer surface of the throttle element and that is intended to be applied flat to a skin surface of a patient.

Claims

1. A medical fluid-line arrangement for transferring a medical fluid between a medical elastomeric pump and a patient port, the fluid-line arrangement comprising: a fluid-line channel with an inlet for connection in a fluid-conducting manner to a pump outlet of the elastomeric pump, and an outlet for connection in a fluid-conducting manner to the patient port; and a throttle element, which is connected in a fluid-conducting manner to the inlet and to the outlet of the fluid-line channel and through which a portion of the fluid-line channel extends, wherein the throttle element causes a partial narrowing of a cross section of the fluid-line channel, the throttle element being encapsulated at least partially in a thermally conductive body, wherein the thermally conductive body serves to transfer body heat from a skin surface of a patient to the throttle element and has a heat-absorption surface that is larger than an outer surface of the throttle element and that is intended to be applied flat to a the skin surface of the patient.

2. The medical fluid-line arrangement according to claim 1, wherein the throttle element is encapsulated completely in the thermally conductive body.

3. The medical fluid-line arrangement according to claim 1, wherein the throttle element is made from at least a first material, and the thermally conductive body is made from at least a second material which has a higher coefficient of thermal conduction than the first material.

4. The medical fluid-line arrangement according to claim 1, wherein the thermally conductive body is made from a metal and/or a thermally conductive ceramic.

5. The medical fluid-line arrangement according to claim 1, wherein the thermally conductive body comprises a thermally conductive pad having a flexible pad-shaped envelope and a liquid and/or gel-like thermally conductive medium encased in a fluid-tight manner by the envelope.

6. The medical fluid-line arrangement according to claim 1, wherein the heat-absorption surface comprises an adhesive layer.

7. The medical fluid-line arrangement according to claim 1, wherein the fluid-line channel is encapsulated in the thermally conductive body in a region that adjoins the throttle element upstream in relation to a direction of flow of the medical fluid.

8. A medical elastomeric pump for delivering a medical fluid, the medical elastomeric pump comprising: a medical fluid-line arrangement according to claim 1; and an elastomeric membrane which forms a pump volume for receiving and delivering the medical fluid, wherein the elastomeric membrane is elastically expanded in a filling state at least partially filled with the medical fluid and exerts an expansion-induced delivery pressure on the pump volume, wherein a volumetric flow of the medical fluid is deliverable through an outlet of the pump volume by the delivery pressure, and wherein the medical fluid-line arrangement is connected at an inlet side to the outlet of the pump volume in a fluid conducting manner.

Description

BRIEF DESCRIPTION OF THE DRAWING FIGURES

[0014] Further advantages and features of the invention will become clear from the following description of preferred exemplary embodiments of the invention, which are explained with reference to the drawings.

[0015] FIG. 1 shows, in a greatly simplified schematic view, an embodiment of a medical elastomeric pump according to the invention, at the outlet of which an embodiment of a medical fluid-line arrangement according to the invention is connected in a fluid-conducting manner.

[0016] FIG. 2 shows, in a partially cut-away and sectional enlarged detail, a region II of the fluid-line arrangement according to FIG. 1.

[0017] FIG. 3 shows the region according to FIG. 2 in a partially cut-away and sectional side view.

[0018] FIG. 4 shows a further embodiment of a medical fluid-line arrangement according to the invention in a region II according to FIG. 1 and in an illustration according to FIG. 3.

DETAILED DESCRIPTION

[0019] According to FIG. 1, a medical elastomeric pump 1 is provided for use in outpatient and/or inpatient infusion therapy. The medical elastomeric pump 1 serves to receive and deliver a medical fluid 4 and can also be designated as an elastomeric infusion pump.

[0020] The medical elastomeric pump 1 has an elastomeric membrane 2 which forms a pump volume 3 for receiving and delivering the medical fluid 4. In the present case, the medical fluid is a liquid medicament 4 not defined in any more detail. With reference to FIG. 1, the medical elastomeric pump 1 is shown in a filling state. In this filling state, the pump volume 3 is filled with the medical fluid 4, as a result of which the elastomeric membrane 2 is flexibly expanded like a balloon on account of a mechanical action of the medical fluid 4. In FIG. 1, the elastomeric membrane 2 is illustrated with an exaggerated wall thickness for graphic reasons. By contrast, in an unfilled state, the elastomeric membrane 2 is slack or at any rate less elastically expanded. For filling the pump volume 3 with the medical fluid, a reclosable filling nozzle 5 is provided, which is attached to the membrane 2 in a fluid-tight manner known in principle. The elastic expansion of the elastomeric membrane 2 subjects the pump volume 3 to a delivery pressure p, by means of which the medical fluid 4 can be delivered through an outlet 6 of the pump volume 3 into a medical fluid-line arrangement 7 that is connected in a fluid-conducting manner to the outlet 6. As will also be seen from FIG. 1, the outlet 6 of the pump volume 3 is arranged in the region of a passage nozzle 8 which, at an end region of the elastomeric membrane 2 directed away from the filling nozzle 5, is attached to said elastomeric membrane in a fluid-tight manner known in principle.

[0021] The medical fluid-line arrangement 7 is only shown in a greatly simplified and partially cut-away schematic view in FIG. 1. The medical fluid-line arrangement 7 serves to transfer the medical fluid 4 from the pump volume 3 of the elastomeric pump 1 to a patient port 9, which is only indicated symbolically in the drawing. In order to transfer the medical fluid 4, the fluid-line arrangement 7 has a fluid-line channel 10, indicated by a dot-and-dash line. The fluid-line channel 10 has an inlet 11 and an outlet 12. In the present case, the inlet 11 is secured non-releasably on the passage nozzle 8 and is connected to the outlet 6 in a fluid-conducting manner. In an embodiment not shown, the inlet 11 can be provided with a suitable connector for releasable fluid-conducting connection to the elastomeric pump 1. In the present case, the outlet 12 leads into a connector 13, which is provided for fluid-conducting connection to the patient port 9. The connector 13 is a Luer connector in the present case, but this is not obligatory. In an embodiment not shown, the connector 13 can be designed for example in the form of an attachment marketed under the federally registered trademark NRFit®. By means of the delivery pressure p, the medical fluid 4 is thus able to be delivered from the pump volume 3 into the inlet 11 of the fluid-line channel 10 via the outlet 6 and can be delivered therefrom further through the outlet 12 into the patient port 9 via the connector 13.

[0022] In the present case, the medical elastomeric pump 1 is dimensioned in such a way that it can be readily worn on the body by a patient and can be used without an external energy supply, particularly in the context of outpatient therapy. The medical elastomeric pump 1 is accordingly light and dimensionally compact, wherein in the present case the pump volume 3 has a nominal size of 400 ml. It goes without saying that the pump volume 3 may also differ from this, for example having a nominal size of between 50 ml and 750 ml.

[0023] It will be seen from FIGS. 2 and 3 that the fluid-line arrangement 7 moreover has a throttle element 14 which is connected to the inlet 11 and to the outlet 12 in a fluid-conducting manner. In this respect, the fluid-line channel 10 extends at least partially through the throttle element 14. In FIGS. 2 and 3, this can be seen from the dot-and-dash lines shown in these for illustrating the fluid-line channel 10. The throttle element 14 causes a partial narrowing E of an active-flow cross section Q of the fluid-line channel 10. The throttle element 14 serves to throttle a volumetric flow V of the medical fluid 4 that is delivered through the fluid-line channel 10 by means of the elastomeric pump 1.

[0024] In the present case, the throttle element is designed in the form of a capillary element 14 and is made from plastic. Moreover, the throttle element 14 can also be designated as a flow limiter.

[0025] In the present case, the fluid-line channel 10 is formed from an arrangement of a plurality of line portions 15, 16 and the throttle element 14. In the present case, the line portions are each designed in the form of a flexible hose portion 15, 16 made from plastic. The hose portion 15 adjoins the throttle element 14 upstream in relation to a delivery direction of the volumetric flow V as indicated in FIG. 1. The hose portion 16 adjoins the throttle element 14 downstream. An outlet (not shown in detail) of the hose portion 15 is connected in a fluid-conducting manner to an inlet 17 of the throttle element 14. By contrast, an inlet (not shown in detail) of the hose portion 16 is connected in a fluid-conducting manner to an outlet 18 of the throttle element 14. For this purpose, the hose portions 15, 16 and the throttle element 14 can be joined together in a manner known in principle. In an embodiment not shown, it is instead possible to simply provide a hose portion which extends continuously between inlet 11 and outlet 12 and on which a throttle element is integrally formed.

[0026] The fluid-line arrangement 7 moreover has a thermally conductive body 19. The throttle element 14 is encapsulated at least partially in the thermally conductive body 19. Compared to an outer surface F, the thermally conductive body 19 has a larger heat-absorption surface W which is intended to be applied flat to a skin surface H of a patient (FIG. 3).

[0027] The thermally conductive body 19 serves to transfer body heat from the skin surface H to the throttle element 14. This is primarily intended to counteract temperature fluctuations on the throttle element 14. Such unwanted temperature fluctuations can lead to a change of viscosity of the medical fluid 4 in the region of the throttle element and thus to a change of the throttle action thereof. Fluctuations of the volumetric flow V can thereby arise, which can ultimately have a negative effect on the overall administration of the medical fluid 4. The thermally conductive body 19 and the design of the rest of the fluid-line arrangement 7 counteract this.

[0028] In the present case, the throttle element 14 has a circular cylindrical outer contour. The outer surface F is therefore, in the present case, the lateral surface of a circular cylinder. In the present case, the thermally conductive body 19 has a cuboid shape, which is to be understood purely as an example. The heat-absorption surface W is many times larger than the outer surface F. In an exemplary embodiment not shown, the heat-absorption surface W can be at least one order of magnitude larger than the outer surface F. The thermally conductive body 19 encases the throttle element 14 such that an inner wall (not shown in detail) of the thermally conductive body 19 is in planar contact with the outer surface F. In the present case, the throttle element 14 is encapsulated completely in the thermally conductive body 19, except for the regions joined together at the ends to the hose portions 15, 16.

[0029] In the present case, the throttle element 14 is made from at least a first material M1. The thermally conductive body 19 is made from at least a second material M2. Compared to the first material M1, the second material M2 has a higher coefficient of thermal conduction. The first material M1 is in the present case a plastic not defined in any more detail. The second material M2 is a metal. In the present case, the metal chosen is aluminum. In an embodiment not shown, the metal chosen can be copper, for example. In another embodiment not shown, the thermally conductive body can be made from a thermally conductive ceramic, for example from aluminum oxide and/or aluminum nitride.

[0030] To apply the heat-absorption surface W to the skin surface H, an adhesive layer 20 is provided in the present case. The adhesive layer 20 is arranged on the underside of the thermally conductive body 19. In a state (not shown) in which the fluid-line arrangement 7 is supplied, the adhesive layer 20 can be provided with a cover film or the like, which prevents unwanted adhesion of the adhesive layer 20 and can be removed from the adhesive layer 20 before the thermally conductive body 19 is applied. The adhesive layer 20 does not necessarily have to be provided. In order to apply the thermally conductive body 19 to the skin surface H, it is instead possible to use sticking plaster and/or dressing material or to position it beneath a layer of clothing of the patient, for example, although this is less advantageous.

[0031] As can be seen in particular from FIG. 3, the fluid-line channel 10 is encapsulated in the thermally conductive body 19 in a region B that adjoins the throttle element 14 upstream in relation to the direction of the volumetric flow V. In this way, the medical fluid 4 can be warmed even before it enters the throttle element 14. The region B can thus also be designated as a pre-heating region. A length of the pre-heating region B is advantageously dimensioned such that the volumetric flow V is already heated to a maximum achievable temperature when it enters the throttle element 14. For this purpose, in particular the length of the pre-heating region B, the other dimensions of the thermally conductive body 19, the thermal conduction properties of the second material M2 and the heat-absorption surface W have to be coordinated with one another, taking account of the volumetric flow V.

[0032] FIG. 4 shows a further embodiment of a fluid-line arrangement according to the invention, the view being limited to the region II according to FIG. 1. The fluid-line arrangement according to FIG. 4 differs from the embodiment described with reference to FIGS. 1 to 3 only in terms of the design of the thermally conductive body 19a shown in FIG. 4. In this respect, structural parts and portions of identical design are labeled with identical reference signs and are not separately described again. Instead, in order to avoid repetition, reference is made to the disclosure concerning the fluid-line arrangement 7 according to FIGS. 1 to 3, which disclosure, apart from the design of the thermally conductive body 19a, applies correspondingly for the embodiment according to FIG. 4.

[0033] The thermally conductive body that can be seen in FIG. 4 is designed in the form of a thermally conductive pad 19a. The thermally conductive pad 19a has a flexible pad-shaped envelope 21a and a second material in the form of a liquid and/or gel-like thermally conductive medium M2′. The thermally conductive medium M2′ is encased in a fluid-tight manner in the envelope 21a. By virtue of the flexible nature of the pad-shaped envelope 21a and the liquid and/or gel-like state of the thermally conductive medium M2′, the shape of the thermally conductive pad 19a is conformable. It is thereby possible, firstly, to achieve a particularly advantageous flat application of the whole heat-absorption surface Wa on the skin surface H. Secondly, the conformability enhances the wearing comfort.

[0034] In the present case, the pad-shaped envelope 21a is made from a film that is made of a plastic not defined in detail. In the present case, the envelope 21a has an upper portion 22a and a lower portion 23a in relation to the drawing plane of FIG. 4, said portions 22a, 23a being joined together in a fluid-tight manner at the edge. For example, the portions 22a, 23a can be adhesively bonded to each other, sewn together or joined in a fluid-tight manner in some other way.

[0035] In the present case, the thermally conductive medium M2′ is a gel not defined in any more detail. The gel M2′ lies over the entire outer surface F of the throttle element 14. In the present case, an entire volume of the envelope 21a is filled by the gel M2′, such that no air inclusions remain. Moreover, the envelope 21a is attached in a fluid-tight manner to an outer circumference of the hose portion 15 and to an outer circumference of the hose portion 16, in a way that is not shown in any detail, such that in these attachment regions too there is no escape of the thermally conductive medium M2′ from the envelope 21a.

[0036] It will be appreciated that the underside of the thermally conductive pad 19a can be provided with an adhesive layer 20 (cf. FIG. 3) in the region of the heat-absorption surface Wa.