HU180870B - Equipment for the enrichment of blood in oxygen - Google Patents

Abstract

Apparatus for the oxygenation of blood, comprising a box, in the axis of which is arranged an oxygenation chamber around which there is disposed an oxygenation chamber around which there is disposed a defoaming chamber with micro porous material, wrapped by micro porous filter, and a reservoir for oxygenated blood with heat exchanger, and in the lower terminal of the oxygenation chamber there is an oxygen chamber with inlet pipe for oxygen and exit tubes for blood, in which, at the bottom of the oxygenation chamber (2), there is coaxially mounted an inlet pipe for the oxygen (6), and at an angle with respect thereto, there are disposed some pipes for the entrance of the blood (5). ) and (7), the outlet orifices from which are arranged below the oxygen chamber (3) and in the center of the oxygenation chamber (2), a hollow chamber (9) is placed around the which one has A spirally shaped heat exchanger (10) is tightly fastened and an oxygenation line (19) is arranged in the upper terminal of the oxygen chamber (2), which passes through the box (1) and its terminal. top is on the lid (27) of the box (1), to which a covering pipe (23) arranged at a predetermined distance on and around the oxygenation pipe (19) is tightly fixed, and in the lower terminal of the covering pipe (23) and in the oxygenation pipe (19) there are strongly circumscribed fixing elements (15) and (15 "), to the holes of the periphery of which both terminals of the material are fastened micro porous (7)

Description

The present invention relates to an apparatus for medical oxygenation of blood during medical interventions.

A device for oxygenation of blood having an oxygen chamber and a blood chamber arranged above it is known. These chambers are interconnected through passages through which oxygen passes under pressure. Above the blood chamber is a bundle of tubes through which blood and oxygen passes, this blood is already saturated with oxygen. Above the tubes, a gas discharge chamber is formed through which the foamed blood flows into the cylindrical defoamer space. The defoaming space is bounded by a microporous material covered with a thin layer of silicon. The microporous material covers a portion of the upper end of the bundle.

The defoamer cylindrical space and the venting chamber are surrounded by a thin blood filter, thereby concentrating a conduit for circulating blood with a heat exchange tube. Underneath the defoamer bed is a blood reservoir, where oxygen-enriched blood is collected.

A disadvantage of the above apparatus is that oxygen and venous blood meet at relatively high pressures, which in turn results in damage to most of the blood cells. This high pressure is determined by the stiffness that the blood must overcome as it passes through the tube bundle. The tubes are relatively small in diameter, which causes intense foaming, which is not an anatomical phenomenon.

In order to defoam the highly foamed blood, the blood is passed through a porous material which is saturated with silicone or covered with a thin layer of silicone. It mixes with blood cells. Subsequently, oxygenated blood is introduced into the human body. However, the silicone components have been found to be known as "silicone components". silicone embolism has a detrimental effect on the treated person's central nervous system. Most of the blood cells die, due to the high rate of oxygen saturation, interact with the silicon component and thus fail to fulfill their physiological function.

It is an object of the present invention to overcome the above shortcomings.

Accordingly, the object of the present invention is to provide an IC device for oxygenation of blood which minimizes damage to blood cells and does not require the use of silicone components as a foaming agent.

The object is solved by an apparatus 15 having a housing having an oxygen enrichment chamber disposed along its axis which is surrounded by a defoamer chamber with a microporous material, a foam chamber covered by a microporous filter, and a container for receiving oxygenated blood, and an oxygen field is provided with an oxygen inlet tube and a blood outlet tube. This can be further improved according to the present invention by coaxially forming the oxygen inlet tube in the bottom of the oxygenation chamber, while the blood inlet tubes are at an angle, their outlets are located below the oxygen space, and the oxygen enrichment chamber provided with an oxygenation tube at the upper end of the oxygenation chamber passing through the housing and an upper end extending beyond the housing lid, a cover tube 30 disposed spaced relative to the oxygenation tube and engaging the lower end of the housing member , whose peripheral openings are joined by microporous material.

It is desirable to have an embodiment in which the ratio of the cross-sectional areas of the oxygen enrichment chamber to the housing is 1: 4 and the ratio of the cross-sectional areas of the oxygen enrichment tube to the oxygen enrichment chamber is 1: 2.

The most important advantages of the device according to the invention are: the saturation of the venous blood with the required amount of oxygen occurs at a minimum flow rate of 10 and at a minimal pressure of oxygen, which results in little foaming of the blood, thus avoiding silicone defoaming component application -; furthermore, the minimal rate of oxygen saturation of the blood only negligibly damages the blood cells, so that the arterial blood treated with the apparatus of the invention maintains its maximum physiological effects.

The invention will be described in more detail with reference to the drawing, in which a preferred exemplary embodiment of the device according to the invention is shown in section. 20

The apparatus for oxygenation of blood according to the invention has a housing 1 through which an oxygen enrichment tube 19 passes. Outside the housing 1, the lower end of the oxygen enrichment tube 19 is connected to the oxygen enrichment chamber 2. On the lower part of the oxygen enrichment chamber 2, an oxygen supply tube 6 is arranged coaxially. Its terminal end is tapered to an oxygen space 3, the outlet of which is covered with microporous sheets 4. The two sides of the oxygen space 3 are at an angle of 45 ° to each other. An arterial blood supply tube 5 and a venous blood supply tube 7 are connected to the lower end of the oxygen enrichment chamber 2. In the center of the oxygen enrichment chamber 30 there is a hollow chamber 9, equidistant from its walls. a spiral-shaped heat exchanger 10 is mounted along its periphery. Inlet 11 and outlet 12 of the heat exchanger 10 are provided in the upper and lower sections of the oxygen enrichment chamber 2 respectively. at the lower end. 35

The oxygen enrichment tube 19 begins at the top of the oxygen enrichment chamber 2 and extends centrally through the entire housing 1 and extends beyond the housing 27. The oxygen enrichment tube 19 is covered by a topsheet 40 25 under which six apertures 24 are formed around the circumference of the oxygen enrichment tube 19. Around the oxygen enrichment tube 19 is a casing tube 23 which is secured to the housing 27 cover. At the lower end of the casing tube 23, two halves of round fasteners 15 'are rigidly fixed. A concentric defoamer chamber 20 is formed around the oxygen enrichment tube 19, which is located at the top and bottom of the cylindrical 15 and 20 respectively. 15 'fasteners and microporous 17 material on the side. The microporous material 17 is held at both ends by the fasteners 15 and 15 'and the inner and outer sides 16 and 15 respectively. It is provided with a 16 'mesh 50 having a pore size of 30 to 80 microns, which is equivalent to the pore size of the microporous material 17, and a thickness of 15 to 30 mm. The microporous material 17 is concentrically disposed around the oxygen enrichment tube 19 and spaced from the bottom and lid of the housing. 55

Between the outer circumference of the microporous material 17 and the housing 1 is formed a reservoir 18 for arterial blood, which has a downwardly tapered configuration. In this downwardly narrowing portion 13 and 13 'outlets are located for arterial and coronary blood. On the opposite side, 14 plugs are provided for receiving blood samples. The cover 27 of the housing 1 is provided with a tubular connection 22 for pouring blood or other fluids. Four openings 21 are formed around the circumference of the cover 27 through which the selected carbon dioxide and excess oxygen can escape.

In the exemplary embodiment of the device according to the invention, the mode of operation is as follows: venous and coronary blood passes through the 7 and 5 sections respectively. on the 5 tubes. These 8 enter the mixing space and fill the area around the oxygen space 3. The oxygen enters the oxygen space 3 through the tube 6 at a ratio of 0.5 to 1 relative to the blood. The bubble blood rises upwardly in the oxygen enrichment chamber 2 as it passes along the heat exchanger 10 and through the oxygen enrichment tube 19, then through the openings 24, into the casing tube 23 and then into the defoamer chamber 20. From there, blood passes through the inner filter screen 16 ', the microporous material 17 and the outer filter screen 16. Meanwhile, the bubbles in the blood disappear and the remaining oxygen and carbon dioxide are separated. The gas thus separated flows into the top of the housing 1 and exits the device through the openings 21.

The foamed blood flows downwardly toward the bottom of the microporous material 17, which is then collected in the collecting container 18. From here, oxygen-enriched blood can be introduced into the arterial system of the human body through the outlet tubes 13 and 13 '.

Claims (2)

Patent claims An apparatus for oxygenation of blood having a housing and an oxygenation enrichment chamber disposed in an axis thereof, surrounded by a defoamer chamber with a microporous material, covered by a microporous filter, and a container for receiving oxygenated blood which is provided with an oxygen exchanger and blood conduits, characterized in that in the bottom of the oxygen enrichment chamber (2) the oxygen inlet conduit (6) is coaxially arranged, the blood conduits (5 and 7) being arranged at an angle, their outlets being located below the oxygen space (3); a hollow chamber (9) is formed in the center of the oxygen enrichment chamber (2) on which a helical heat exchanger (10) is fixed and at the upper end of the oxygen enrichment chamber (2) an oxygen enrichment tube (19) extends through the entire housing (1). and extends beyond the housing (1) ( 27), a cover tube (23) is fastened to the lid (27) and spaced around the oxygen enrichment tube (19), and the lower end of the cover tube (23) is secured to fasteners (15, 15 ') on both sides of microporous material (15). 17) They will contribute. An embodiment of the device according to claim 1, characterized in that the ratio of the cross-sectional areas of the oxygen enrichment chamber (2) and the housing (1) is 1: 4 and the ratio of cross-sectional areas of the oxygen enrichment tube (19) and oxygen enrichment chamber (2) : 2nd