SE435571B - BLOOD ACID RESET UNIT SAFETY DEVICE - Google Patents

Description

78080694: may give rise to a life-threatening embolism in the patient.

Furthermore, an oxygenator apparatus is known for the safe and efficient utilization of blood oxygenator units with hydrophobic, porous membranes. A manometer is arranged to ensure that the gas pressure in the oxygenator unit is limited safely and reliably.

The above-mentioned oxygenator apparatus also discloses heat exchange means and the like for maintaining a suitable blood temperature and other desirable operating parameters.

For the commercial production of porous membrane oxygenation units, it is of utmost importance that it is ensured that the user uses the oxygenator unit correctly using the correct equipment for application and for the supply of blood and oxygen to the membrane oxygenator unit, so that no hazardous gas overpressure arises, which drives oxygen bubbles into the bloodstream, which can immediately give rise to a life-threatening situation.

The present invention aims to provide an oxygenator and diaphragm oxygenator unit for use in said device, wherein the membrane oxygenator unit can only be used with the greatest difficulty without the oxygenator itself, which can be designed so that it offers the necessary operating parameters for safe use. Consequently, a relatively safe arrangement for patient protection is offered.

The safety device of the blood oxygenator according to the invention is characterized by an outer casing enclosing a plurality of blood flow channels alternating with a plurality of oxygen flow channels and separated therefrom by a semicermeable membrane, which prevents passage of blood but allows passage of oxygen and carbon dioxide through the same stretch. inlet opening in the housing is located so that it directly exposes the ends of the oxygen flow channels to the outside of the housing, whereby easy connection of the oxygen flow channels to an oxygen line is prevented.

As a result of this arrangement, the oxygen reaches the plate by means of an oxygen conduit and is branched or spread to a wide flow path for delivery to the flow channels of the individual oxygenator unit by means of parts carried by the oxygenator itself instead of by the oxygenator unit. As a result, oxygenator units desired for use with the device according to the invention do not carry an oxygen distribution line and thus can not be used without difficulty with improvised equipment. Thus, the user of a disposable oxygenator unit is strongly motivated to use the standard equipment for this unit with its proven safety features instead of improvising its own appliance arrangement, which thus becomes more difficult.

A typical membrane oxygenator unit has blood and oxygen flow pathways, which include a plurality of interleaved parallel channels. The typical oxygenation units for use in the present invention are intended to have a wide orifice opening for oxygen inlets and outlets for spent gases to and from the oxygenator unit, the parallel, interleaved oxygen channels inlet and outlet in the oxygenator unit being directly exposed to the outside of the unit orifices. The branch opening on the plate of the blood oxygenator is consequently so proportioned that it encloses and seals the wide mouth opening around the inlet of the parallel channels, so that a closed oxygen flow path is obtained. The wide mouth opening of the oxygen inlet to the membrane oxygenator unit prevents the application of an oxygen line to the oxygenator unit in a simple manner, so that motivation is thus obtained for the use of the standard oxygenation equipment which is specially made for use with the membrane oxygenator unit, which includes required safety features, such as a means for limiting the gas pressure, a heat exchanger unit and the like.

The invention is explained in more detail below with reference to the accompanying drawings.

Fig. 1 is a schematic view of an oxygenator equipped according to the invention showing a porous membrane oxygenator unit installed in the holding member, Fig. 2 is a rear plan view of the oxygenator unit holder means, one side wall of the holder means being removed and the device shown without the oxygenator, while the heat exchanger means is shown in broken lines, Fig. 3 is a perspective view of the oxygenator holder means with a side wall removed, the view showing a typical membrane oxygenator unit prior to installation in the oxygenator holder means; Fig. 4 is a side view of the oxygenator holder means installed, and parts of the oxygenator unit and the holding means are broken away and shown in section, and Fig. 5 is a view on a larger scale, which in vertical section shows the device near the oxygen inlet of the oxygenator unit according to Fig.

The figures show an oxygenator, which comprises means 12 for removably holding a membrane oxygenator unit 14.0 means for supplying blood from a patient through the oxygenator in a first flow path and back to the patient are also provided. Blood in the inlet tube 16 is driven through the oxygenator by means of a conventional roller pump 20. The blood is drawn from a reservoir 22 for venous blood. It is supplied to the reservoir through a conduit 24 from the patient's venous blood.

Downstream of the oxygenator, the blood from the oxygenator enters the blood outlet tube 18 and from there through the heat exchanger 26 (for example according to U.S. Pat. No. 3,640,340) to the arterial blood reservoir 28 through the tube 19, from where it is driven by a second roller pump 30 into the patient's arterial line. 32. The heat exchanger 26 is mounted on a holder 27, the inlet and outlet of the heat exchange fluid flow path communicating with openings 29 through the holder 27 of the holder 12 for connection to a source of heat exchange fluid. A cardiotomy reservoir 34 may be provided for receiving blood from a cardiotomy aspirator which draws blood from the patient's site of intervention or the like, and directs the blood to the reservoir through line 36. The cardiotomy reservoir is connected through line 38 to a filter 40, which in turn is connected to reservoirs 22.

The holder 12 of the unit is held by a bracket 35, which in turn carries a mast 37 with hangers 39, 41 for removably holding blood-containing components of the oxygenator. The bracket 35 is in turn held on a hanger 43, which is arranged at a support element 45.

Figures 2 - 5 show details of the holder 12 of the oxygenator unit and connected parts.

The holder 12 is shown carrying an oxygenator unit in contact with a plate 42, which in turn offers an oxygen inlet manifold opening 44, which terminates at its inner end with an O-ring seal 46. An oxygen source is connected through the oxygen inlet line 48 to the opening 44, so that a closed oxygen flow path is obtained through the plate and into the oxygenator unit.

The recess 50 inside the O-ring seal 46 is arranged to allow the oxygen gas to flow freely through the entire interior of the O-ring seal 46. the opening 44, the O-ring seal 46 and the recess 50 are positioned so that they closely communicate with the oxygen inlet 52 of the oxygenator unit 14, as shown in Figs. 3 and 5. As is best seen in Fig. 3, the oxygen inlet 52 is elongated so that the many inlet ends of conventional The parallel flow channels 54 of the oxygenator are all directly exposed to the interior of the oxygenator unit through the inlet 52. The O-ring seal 46 is so proportioned as part of the manifold opening of the plate 42 that it encloses and seals the inlet 52 of the oxygenator unit 14 so that a closed oxygen flow path is obtained when the unit 14 installed in the holder 12.

The outlet opening 56 of the oxygen flow path at the unit 14 is also typically elongate to allow free discharge of excess oxygen plus carbon dioxide and water vapor, which is introduced into the second flow path of the oxygenator unit 14.

Fig. 5 shows a typical construction for the layers forming the flow paths 54. A porous, semipermeable membrane 14m lies over a net 14s in a pleated multilayer arrangement as further illustrated in U.S. Pat. No. 3,757,955. The edges of the membrane and the net are sealed by a cured, embedding compound 14p, and the structure is enclosed between walls 15, which are held together by fasteners 17 (Fig. 3).

As shown in Fig. 4, the plate 42 touching the oxygenator unit is positioned so as to separate from it and form an unbroken wall 58 over the gas outlet opening 56 of the oxygenator unit in the position of use, the gap 59 typically being approximately 3.2 mm wide. As a result, exhaust gas from the outlet 56 can escape indefinitely in a plurality of directions through the space 59 between the plate 42 and the unit 14. The consequence of this is that the probability of unintentional clogging of the outlet 56 is greatly reduced, since the gas is sufficiently vented from the oxygenator unit 14 as long as any substantial portion of the elongate space 59 remains open to the exterior.

The plate 42 is mounted to the holder 12 by means of a removable nut 60 at one end and through a conventional locking member 52 at the other end, so that the plate 42 can be easily removed from the holder 12.

The conduit 64 and the conduit 65 through the cover 70 provide a connection between the oxygen inlet manifold opening 44 and a safety member 66, which is held by the bracket 27, to prevent the pressure of the oxygen gas in the inlet manifold opening from reaching a level high enough for gas bubbles to pass through the porous, semipermeable membrane 14m of the oxygenator unit 14. This safety member 66 comprises a liquid-filled tube with a rigid, tubular extension 68 of the conduit 64. The safety member functions in a known manner as a pressure-limiting device.

The holder 12 of the oxygenator unit also comprises upper and lower plates l2p, l2q and side walls l2s, which are fastened to each other in the manner previously described for the plate 42 by means of nuts l2n, which fit on bolts l2b, and locking means l2d.

The plate 129 is attached to the bracket by gluing or welding. The oxygenator unit 14 need not be enclosed along its rear side, i.e. the blood flow side § In the embodiment shown here the inlet manifold opening 44 does not go straight through the plate 42 but makes two rectangular bends as shown in Fig heating block 69, which is arranged in the lid 70, which in turn is carried by the plate 42. The heating block 69, through which the inlet distributor opening 44 passes as an elongate duct, comprises means for heating the oxygen gas entering the oxygen gas. the setter unit, to a predetermined temperature. A heating block 69, which can be used in this case, can typically consist of a 45 watt, 120 volt electric heating cartridge with a resistance of 3 ohms. The line 65 also passes through the heating block 69, so that it communicates with the opening 44.

The heating block 69 is regulated by two thermostats 72, which are electrically connected to each other, so that the disconnection of either thermostat deactivates the heating block 69. The purpose of this is to provide high security so that the oxygen does not overheat, as an oxygen temperature exceeding 42 ° C can seriously damage the blood in the oxygenator. A fuse 73 is also provided to increase safety.

An insulating wall 74 prevents excessive heat loss from the heating block 69. If desired, alarm means may be provided for activating an audible alarm device 78 when a pressure switch 79, which is in fluid communication with the inlet manifold opening 44, does not sense a gas pressure which exceeds a standard pressure of at least 152 mn1H2O, which corresponds to approximately an oxygen flow through the opening 44 of 5 liters per minute, when the opening diameter is approximately 6.35 mm. This arrangement may include a conventional relay 80 which acts on the alarm device 78 when a predetermined gas overpressure is not sensed.

An opening 82 passes completely through the plate 42 and the lid 70, so that the inflation line 84 of the oxygenator unit 14 can be passed therethrough. The inflation line 84 communicates with an inflatable shim in the oxygenator 14, which can be used to put the mesh layers 14s and the membrane layers 14m under pressurizing pressure to counteract the tendency of the oxygenator unit to expand due to the blood pressure which tends to dislodge the mesh. and membranes. The inflatable shim may be placed in the middle of the stack of nets and membrane layers or it may be constructed with a U- so that it offers a pair of expansion elements The inflatable shaped cross section, on each side of the stack for the same purpose. The shim can also be constructed in other ways. Typically, the holder 12 of the unit is placed at an angle to the vertical plane by means of the bracket 35 for raising the blood outlet as shown in Fig. 4, so that the initial filling of the oxygenator unit with blood or saline is facilitated. The angular placement facilitates the removal of all air bubbles from the oxygenator unit into the outlet conduit 18 during initial filling. The bottom plate 12q has a chamfered lower edge 86, so that the holder 12 assumes the same angular position relative to the vertical plane, when resting on a horizontal surface, before it is hung by means of the bracket 35 on the arm 43. Thus the holder 12 can easily be provided with an oxygenator unit and the unit is initially filled with saline solution before hanging on the arm 43.

The described embodiment of the invention can be modified and varied within the scope thereof in many ways.

Claims (2)

78080694 »CLAIMS 1. Safety device at blood oxygenation unit, -recognized - characterized by an outer casing (15) enclosing a plurality of blood flow channels alternating with a plurality of oxygen flow channels (54) and separated therefrom by a semipermeable membrane (l4). which prevents the passage of blood - but allows the passage of oxygen and carbon dioxide therethrough, an elongate inlet opening (52) in the housing being positioned so as to directly expose the ends of the oxygen flow channels (54) to the outside of the housing, thereby easily connecting the oxygen flow channels to an oxygen line is prevented. 2. A safety device according to claim 1, characterized in that the semipermeable membrane (14m) consists of a porous, hydrophobic material. __.-