NO751109L - - Google Patents

Description

Saramenclampable pipeline -

The present invention relates to a collapsible

pipeline.

Devices for the transfer of blood from the body to a patient and from the external environment back to the patients circulatory system have long been known, within the framework of various medical and surgical interventions and situations.

E.g. recent developments in the surgical field have created an ever-increasing need to establish hypotensive conditions in a patient undergoing surgical procedures due to the need to reduce bleeding during surgical operations. A method to ensure such hypotensive conditions involves establishing an extra-legal blood circulation; This technique essentially consists in forming an artificial circulation network, outside the human body, in which network circulating blood is temporarily diverted for a shorter or longer time. The two main functions of blood circulation, dtfé. to keep the blood circulating as well as to enrich; with fresh oxygen the blood with a low oxygen content coming from the patient's veins is carried out with the help of a mechanical device, i.e. one pump and an oxygenator which, from a physiological point of view, replaces

the functions of the heart and lungs respectively.

Several devices are known to ensure such extra-alloy circulation. These devices, which are sometimes referred to as "heat-lung machines", differ from each other mainly

by the type of pump and oxidation device used. Three types of pumps have mainly been developed for use in such machines, namely rotary pumps, "finger" (or sigma motor) pumps and compression pumps. v.

Regardless of the pump type, these devices have the common feature that their function is based on the compression of a squeezable pipeline that contains the blood, which is thus exposed to movement with varying volume flow.

All such pumps use pipelines made of a flexible, elastoineric material with a circular cross-section and uniform wall thickness as a pipeline for transferring the blood, as such pumps are equipped with organs that are suitable for performing a pulsating compression and unloading of the squeezable pipeline. As a result of the stretch the pipeline is exposed to on the pump, the collapsible pipeline is flattened in the zones where it abuts the pump nulls, so that corresponding sealing zones are created for the blood. In the case of disc rotation will

the rollers cause continuous advancement of the flattened zones on the pipeline/i, with a corresponding displacement of the sealed

■ zones along the direction of blood flow. However, these squeezable pipelines with a circular cross-section and constant wall thickness have the disadvantage that an incomplete flattening of the pipeline zone takes place, which is subjected to compression against the roll due to strong; elastic reaction forces occur at diametrically opposite zones of the adjacent pipe section. against the roller, as a result of which a significant part of the thickness of the elastomeric material is brought to assume a contour with a very small radius of curvature.'

Consequently, the sealing of the pipeline at the zones soe is incompletely flattened by the rollers will be incomplete and not proportional to the applied pressure. In order to provide complete flattening of the pipeline along its entire diameter at right angles to the compressive action exerted by the rollers, the pipeline must bear against the rollers in such a way that a substantially increased tension is exerted on the pipeline.

Adding such an excess pressure to achieve complete flattening of the pipeline over its entire diameter entails the significant disadvantage that a large number of red blood cells are thereby traumatized and haemolysed, which significantly impairs the patient's blood. The longer the patient has to .,.

exposed to extracorporeal circulatory conditions, the stronger the hemolysis of the red cells. Another significant disadvantage of such, high pressure on the blood-carrying pipeline for the achievement of. total flattening is the strong tensile stresses that occur in the pipeline with the consequent increase in wear and reduction' of the pipeline's useful life.

According to the invention, a collapsible pipeline has been provided which is characterized by the fact that the pipeline wall has at least two diametrically opposed grooves which extend in the longitudinal direction of the pipeline. When in use, the pipeline should be mounted on a device suitable for carrying out the pulsating flattening and unloading of the pipeline, regardless of the type of device, in such a way that the flattening and unloading direction is generally perpendicular to the plane that runs through them. two diametrically opposed tracks. Consequently, they will zone off the pipeline as due to the flattening

assumes a contour that is characterized by a very small radius of curvature, corresponding to the zones on the pipeline that have weakened thickness, i.e. the zones that are provided with grooves.

It is to be understood that in connection with the present invention, the term "groove" denotes any hollowing or recess with any profile in the pipe wall, the shape and size of which are as such. that it causes minimal elastic reactions when pipelines are flattened at such "grooves", in contrast to: the significantly stronger elastic reactions that would occur if one tried to flatten the pipeline at zones of greater thickness' or in contrast to the elastic reactions that would occur at flattening of a pipeline with Uniform wall thickness... ,

In order for the invention to be better understood, and to show how it can be carried out in practice, it will be explained in more detail in the following with reference to the attached drawings, where: Fig. 1 is a perspective view of a square-shaped piece of pipeline according to a first embodiment of the invention in its unflattened state; Fig. 2 is a cross section of the pipeline along the line II-II in fig. 1, Fig..5 is a schematic diagram of a rotary pump on which the pipeline shown in fig. 1, is mounted, Fig. 4a is a cross-section of the square-shaped tube. wire according to fig. 1 along the line IVa-IVa in fig. 3, Fig. 4b is a cross-section of a pipeline of previously known type, under the same condition as that shown in fig. 4a, Fig. 5 shows a cross-section of a pipeline with a round shape according to another embodiment of the invention in a non-flattened state, Fig. 6 shows a cross-section of the pipeline according to Fig. 5" in a flattened state, . Fig. 7 shows a cross-section of another embodiment of a pipeline with a round shape according to the invention in a non-flattened state, Fig. 8 shows a cross-section of the pipeline according to fig. 7 in the flattened state.

In the drawing, fig. 1-4a, a first embodiment of a collapsible pipeline according to the invention is shown. The pipeline 1 has a largely square cross-section and is made of any elastic and flexible material which is unaffected by and suitable for use in connection with the blood fluid to be transported in the pipeline. Suitable materials for making the collapsible pipeline are well known to a person skilled in the art. Examples of suitable elastic and flexible materials are natural rubber, elastomeric ethylene-propylene copolymers, and silicone rubber. The pipe line 1 comprises four thick walls<g>^a^^b^^Ccoé^cfccsoBiie^ofor-connected with each other by means of weakened wall zones 5b, 3c and 3d, respectively, which delimit the same number of tracks,, as for simple his fault is given by the same reference number as the weakened wall zones. The end parts ~4a, 4b in the pipeline 1 are in engagement with locking blocks 5a, 5b. These toe blocks are provided with through-holes for receiving housing pipe fittings 7a, 7b in which pipelines 6a, 6b respectively are inserted.

As shown in fig. 3, the collapsible conduit I is mounted on a conventional rotary pump (which is schematically indicated in the figure). The pump comprises a disc 9 which is arranged for rotation about its axis in the direction of the arrow, by means of appropriate drive means (not shown).

The edge 9a of the disk 9 is rotatably supported by running rollers 10a, 10b, and 10c, on which rollers the collapsible pipeline 1 is arranged with slight tension. Under the influence of . this weak stretch (which in turn causes a pressure on the pipeline

which is quite insufficient, as indicated above, to produce at least appreciable hemolysis), the pipeline 1 assumes, at the zones which successively come into contact with the rollers, a fully flattened state along the entire diametrical zone at right angles to the flattening action exerted of the rollers, as shown in fig.4a. Fig. 4a also shows the perfect seal provided by the flattened parts of the pipeline. Fig. 2 and 4a also clearly show the different purposes of the "grooves" 3a and 3b in relation to the "grooves" 3b and 3<*« While the former serve the task of facilitating ddn perfect flattening of a pair of adjacent pipe walls (e.g. 2a, 2d) against the opposite pair of adjacent walls 2b, 2c without significant elastic reaction forces at right angles to the flattening plane B which is formed, the "tracks" 3b,r 3d serve the task of promoting the approximation of neighboring walls^, so that in the flattened state wall 2a is flush with wall 2d and wall 2b is flush with wall 2c, without significant elastic reaction forces occurring parallel to the flattening plane P.

It is clear that the elastic reaction forces in these pipeline zones will be significantly smaller than the elastic reaction forces 3 that would occur with a relatively thicker wall, as happens with such pipelines of a known type that are usually used and are not provided with tracks.

For the sake of comparison, we are fig. 4b the situation in case of incomplete flattening which is achieved with a pipeline of a known type with uniform wall thickness, under the same stretch as the pipeline according to the present invention shown in fig. 3 and 4a.

From fig. 4b also shows the incomplete seal achieved by the incompletely flattened pipeline at the diametrically opposite zones 11a, 11b. Fig. 5 and 6 show as a further embodiment a round-shaped, collapsible pipeline according to the invention, respectively in the absence of external stresses and in a flattened state. Fig. 7 and 8, which correspond to fig. 5 and 6, show a further embodiment of the invention. It appears from fig. 7 and 8 that the "grooves" that are necessary to achieve the desired technical effect are the same as those that define the flattening plane P.

According to a particularly preferred embodiment of the invention, the collapsible pipeline is produced in such a way that it takes on a self-contained shape in accordance with the contour that the pipeline assumes when it rests on the rotating pump disk, i.e. it is

mostly U-shaped, as shown in fig. J>.

It has actually been found that if the pipeline, instead of being manufactured in accordance with a straight design and then being bent when the pipeline is taken up on the rollers of the rotary pump, is manufactured in such a way that it has an inherent or built-in approximately U -shape corresponding to the U-shape pipeline in any case assumes when mounted on the rollers, the volume of blood contained in any branch of the pipeline between one roller and the next roller becomes greater than the volume of blood contained in a corresponding branch of a pipeline which is produced in a straight design and then bent during assembly on the pump. Consequently, under the same construction and operating conditions, pumps using U-shaped collapsible pipelines according to the present invention will provide a larger qtreasoning volume than. nipples on which straight pipelines-are mounted*

:.,- It has been found that when a pipeline according to the present invention is subjected to flattening, the elastic 'reaction jaws' which arise at the folded pipe sonor sora have little curvature. ning radius, in connection with the use of this type of pipeline, largely irrelevant, which results in an easy and complete flattening of the pipeline along the whole pipeline diameter. This complete flattening of the pipeline is also achieved under the influence of very small tensile forces, so in all cases insufficient to cause trauma and/or lysis of red cells. •''< '

One has in fact found that while the conventional . pipelines3oa ordinaryvip are used, must be utoettes'for a pressure of about ^7 kg for complete flattening, will Qt pressure on only then. 70 g of product is sufficient to achieve, samiae ro sul tat with the collapsible pipeline; according to the present invention. If one assumes that a pressure of only 2 kg is sufficient to cause: hemolysis and ragged blood cells, it is clear that this improved compliant pipeline does not cause any appreciable degree of hemolysis. ' ;,' , ■ ' \

Claims (4)

1. Collapsible pipeline, characterized in that the pipeline's wall is provided with at least two diametrically opposed grooves that extend in the pipeline's longitudinal direction. ,2. Collapsible pipeline as specified in claim 1, characterized in that the pipeline wall is provided with 1 at least two further tracks which are located-on A towards set sides in relation to a plane running through the two first-mentioned tracks. 3, Collapsible pipeline as specified in claim 1 or 2, characterized in that it has a roughly rectangular cross-section. 4. Collapsible pipeline as stated in claim 3, characterized in that it has a largely square cross-section, 5" Collapsible pipeline as stated in claim 1 or 2, characterized in that it has a roughly circular cross-section. 6. Collapsible pipeline as stated in one of the preceding claims, characterized in that it has a U shape.