DE2115333A1 - Method and device for generating a pulsating flow, in particular for perfusions for medical purposes - Google Patents

Description

FATE N ADVOCATE

dr. W. Schalk dipl.-ing. P. Wirth ^; dipl.-ing. G. Dannenberg DR. V. SCHMIED-KOWARZIK · DR. P. WEI N HOLD · DR. D. GUDEL

6 FRANKFURT AM MAIN

CR. ESCHENHEIMER STRASSE 39

March 29, 1971

Da / is Baxter Laboratories, Inc.

Morton Grove, Illinois 60053 / USA

Method and device for generating a pulsating flow, in particular for perfusions for medical purposes

Devices for generating a pulsating flow of a medium through a pipe are being used continuously for experimental purposes clinical work in the field of organ perfusion and the like. Used. It has been shown that the life of c- urgically removed living organs, such as Livers, hearts or kidneys can be extended by perfusing the organ with oxygenated solutions. In particular it has been found that the viability of such separate organs is enhanced by perfusion with oxygenated solution can be lengthened in a pulsating flow rhythm that mimics the heartbeat.

While various systems have already been created to create a pulsating flow of oxygenated living organs To supply liquid, these have been shown to have disadvantages in that they were unable to provide a to create a wide range of variations in pulsating flow schemes, through which the user would be given the opportunity to the exact amplitude and shape of the desired pulsating

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To determine pressure waves of the flow optionally. The known pumps also work for producing such pulsating Flows not with the optimal flow volume.

This deficiency is remedied by the invention, which provides a simple device for controlling the pulsing scheme Flow of a medium through a pipe creates, thereby changing both the amplitude and the shape of the Impulse or pressure wave as a function of time.

Furthermore, the invention creates a device with which larger amounts of flow through a narrow line of a pumping system for the pulsating flow can be supplied in order to achieve greater pumping capacities.

For this purpose, the invention provides a device that sets a medium in a line in flowing motion before, in which a pumping device generates a pulsating pressure for moving the medium through the conduit. The device contains an artery-like device with a resilient or elastic line section, the one Forms part of the aforementioned line. This line section is downstream of the one that generates the pulsating flow Device and is surrounded by a closed sleeve which has a pressurizable space around the line section forms around. The space within the sleeve can be pressurized as desired to allow the compliance of the conduit section by controlled pressure of any degree and by to change any scheme. Therefore, the pulsating flow pattern of the pump device modulate resulting pulsations through the line section flowing medium depending on the pressure surrounding this line section within the sleeve. For example, a constant pressure can be used

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or a pressure oscillating in phase with the pulsations to increase the amplitude and change the shape of the pulsations, or a pressure pulsating out of phase in order to reduce, change or complete the pulsations remove. So the result is the flow pattern obtained for the medium by selectively controlling the pressure within of the space surrounding the elastic line section optionally adjustable, as described in more detail below is.

The elastic or resilient line sections used here can have any cross-section, for example round, oval or the like.

Furthermore, a preferred embodiment of the invention provides that an immediately upstream of the pulsating Pump device located and with its entrance connected line part an anteroom of enlarged transverse dimensions forms to obtain increased pulsatile flow performance in accordance with the teachings of Anderson et al., American Heart Journal, Jan. 1967, pp. 92-105.

According to this preferred embodiment of the invention, the part of the conduit forming the vestibule is of a second one enclosed sleeve which defines a second pressurizable space around the conduit section. This The second space receives oscillating pressure, through which this antechamber during the filling phase of the pulsating pump device is caused to collapse and expand during the working phase of the pumping device. This will a copious amount of the medium is supplied to the pulsating pump device, as a result of which the pumping capacity is increased.

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The invention is described in more detail below with reference to the drawing, for example, namely show:

Fig. 1 is a schematic view of an organ preservation system according to the invention;

Fig. 2 is a vertical section through an embodiment of a coming for use in the invention pulsating pumping device with associated parts; and

3 shows a vertical partial section, corresponding to FIG. 2, of another embodiment of the Anteroom and the pulsating pumping device.

In the drawing there is shown a perfusion system for an organ in which the perfusion liquid, e.g. Blood or Plasma, is pumped through a typical, transparent preservation chamber 10 for the organ in which the organ is located can be observed. The medium or the perfusion liquid is supplied by a pulsating pump device fed through a line 14 of the chamber 10, flows through a cannulated organ therein and leaves the Chamber 10 via an outlet line 16. Another access to chamber 10 is provided for use as required. The access 17 can be brought into connection with the organ in order to remove organ secretions from the chamber 10 and if necessary to a (not shown) collecting container. If desired, the perfusion flow path of the organ preservation system be housed in a hyperbaric chamber in order to carry out the perfusion under positive pressure. the The entire device can also be accommodated in a compact container for transport.

The liquid perfusate is distributed uniformly from the organ within the chamber 10 via the line 16 in a conventional manner Heat exchanger 18 supplied in which it is set to the desired

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Temperature, generally between 4 and 37 ° C, to control the temperature of the system. Separated The circuit for a heat exchanger medium 20 directs this closely adjacent to that from the line 16 into the heat exchanger entering perfusate, but the two media are kept separate by thin, heat-transferring metal plates. That Heat exchange medium, such as saline solution, circulates in lines 22 between the heat exchanger 18 and a conventional temperature controller and pump 24.

The perfusate of the desired temperature flows from the heat exchanger 18 via a line 26 to a conventional oxygenator 28 (for example as described in Belgian patent specification 726 886), which supplies oxygen to the transfusate and carbon dioxide / The oxygenator 28 also includes a flow path for the oxygen with a supply line and a delivery line 32. The perfusate flows from the oxygenator 28 via a line 34 and a tight connection 36 into an enlarged line section, which forms the vestibule 38, which is usually made of flexible, t ^ affem, thin-walled rubber tube is formed. The anteroom 3 £ forms a flexible chamber in which the perfusate is located accumulates between the filling phases of the pulsating pump device and is covered by a protective tube 37 (Pig. 2, 3) surround. The amount of the perfusate flowing in the system is adjusted as required by additions from a reservoir 41 with a Control valve 43 regulates in order to compensate for losses caused by secretion discharge via connection 17 and the like.

As FIG. 2 shows, the pulsating pump device has a cylinder 42, within which an elastic cylinder is axially Tube 44 is attached. The space 45 between the tube 44 and the cylinder 42 is surrounded by annular seals and 49 closed and forms a closed annular chamber. In the inlet 46 and outlet 48 of the pump device 12 is each a one-way valve flap 50 is provided through which the

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Flow through inlet 46 enter tube 44 and through outlet 48 while preventing flow in the opposite direction.

The cylinder 42 is provided with an inlet opening 52 for a medium which is supplied by an oscillating pressure generating system, to which a pipe 54 containing a column of hydraulic medium belongs, which via a line 58 to a conventional, oscillating pressure generating control station 60 (Fig. 1), which is actuated by a source of pressurized gas 61, generally oxygen. In the exemplary embodiment, the control station is connected in such a way that it feeds the line 58 with oxygen at an oscillating pressure and also supplies oxygen to the oxygenator 28 via the line, normally via a flow meter contained in the control station 60. The oscillating pressure causes a reciprocating flow through the inlet opening 52 to the space 45, the inside of the cylinder 42, the tube 44 surrounds ^ XWA the pump means to operate 12 by alternately collapsing and re-expanding the tube 44, in accordance with the Pressure waves of the oscillating pressure. When the tube collapses, the perfusate in the tube 44 is pressed out through the outlet 48, while when the tube 44 expands, the medium or perfusate enters through the inlet 46 in each filling phase of the pump. In general and expediently, the pumping device 12 is located vertically at a lower level than the organ chamber 10 in order to obtain a hydrostatic overpressure which assists the filling of the tube 44 during the filling phase of the pump. The oxygenator 28 is also vertically lower than the chamber 10 in order to be there under pressure.

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A pneumatic control device suitable for the control station 60 for the delivery of oscillating pressure to the line 58 and the inlet opening 52 is in an attachment by Demers et al. entitled "APerfusion Circuit for Organ Preservation in Portable Chambers (in German: A perfusion circuit for organ preservation in portable Chambers) ", in the Journal of Surgical Research, Vol. 9, No. 2, pp. 95-99 (1969). This article is concerned also with a suitable combined heat exchanger-oxygenator, which instead of the separate units shown here and 28 can be used in the invention. This or other pneumatic systems can be set so that the desired pauses between pulses can be obtained.

In accordance with the invention, an elastic conduit section 62 forms part of the conduit for the pulsating Flow of the medium or perfusate, and this section lies downstream of the pulsating pump device 12. He is of a closed, integral with the cylinder formed sleeve 64 surround to a pressurizable space 66 between the sleeve and the resilient conduit section 62 to form. The line 68 extends from the space 66 to a pressure control 70 (FIG. 1), which via a Line 72 is connected to a pressurized oxygen source 61.

The pressure controller 70 can be a simple constant pressure regulator or, if desired, variable pressure regulator and also be coordinated with the oscillating pressure of the source 60, if necessary. If the medium is through a Pressure pulse is pushed out of the pump 12, the amplitude and the shape of the pressure wave can be changed by changing the The elasticity or resilience of the line section 62 can be changed. This elasticity or resilience becomes by the pressure supplied via line 68, if desired

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controlled so that the volumetric capacity of the line section 62 is changed in this way. When high pressure is applied is the compliance characteristic of the section 62 when it is exposed to a pressure wave coming from the pump 12 is entirely different from the compliance characteristics of section 62 when low pressure or there is a reduced pressure in line 68 and space 66. A constant pressure can be provided for the space 66 as well as an oscillating pressure or any desired type of pressure, either in phase or out of phase with the oscillating pressure used to drive the pump 12. This offers great flexibility in the control of the shape of the pressure pulses of the oscillating flow, which via the line 14 of the organ chamber 10 is fed.

Fig. 3 shows a modified embodiment of a device according to the invention, which - apart from the features listed below - corresponds to the device according to FIGS. The line part forming the antechamber 38 is located here within a sleeve 37% with a cap 71 creates another pressurizable space 72. The line part delimiting the vestibule 38 is at 74 with the cap 71 glued so that the space 72 is tightly sealed here. A line 76 leads from the space 72 to an oscillating source Pressure, such as the source 60. The pressure oscillations in the spaces 45 and 72 are arranged so that they do not in Are in phase with one another, the pulses in room 72 generally shortly preceding those in room 45. So if that elastic tube 44 of the pump 12 is in the filling phase of a pumping cycle to receive medium through the inlet 46, is a pressure pulse is fed to the space 72 via the line 76, which the line part that forms the antechamber 38 to the Brings collapse and thus presses medium into the pump 12. A check valve to prevent excessive backflow To prevent from the vestibule 38 is not

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necessary. The main part of the content 1 "anteroom 3" flows into the pump 12 without such a valve because its inlet 46 is much wider than the line 34 - and because the pressure in the line 34 is greater than the pressure inside as a result of the elevated Qrgankanaer 10 ά "& elasti rule tube 44 during the 1st FUllxyklus" owing to the inherent elasticity of the pipe 44 and its tendency to return to the expanded state. However, if necessary, a check valve can be provided for increased efficiency.

Apart from Pfease's ossillated radar pressure, the Rau * is conducted via line 78 and aintn linlai 79 via a conventional delay device which is connected to line 76 and actuates a control valve la of line 73, which opens it in one position and in In another position it closes, but allows a backflow * in order to obtain an oscillating bridge in the pipe 80 and the space 45. The line 78 is further connected to a bridge, such as, for example, the oxygen pre-1 → 1, in order to produce a constant pressure in the line 78 upstream of said valve.

A typical delay device may consist of a line connected to line 76 which passes through leads a chamber of predetermined volume and then past an adjustable Radelventil to a pressure-responsive one Switch for the control valve. The volume of the chamber and the needle valve are adjusted so that gives the desired time delay. A suitable control valve is available from the Fluidonics Division of Imperial Eastman Corporation * Chicago, Illinois, under the ID number 300135.

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QRK3INAI. INSP £ CT £ Q

During the Puapphase of the pump in Fig ΛΖ · 3, the flap 50 of the inlets 46 are closed let β and the oscillating pressure in the Rau "72 and in line 76 u ^ r is up. reduced * level, among other things to enable the line part forming the precharger 38 to "fill it with perfume" again.

Since the printing process "a Ik Rau" 72 can be preferred that the duration of each printing process, through / Se? the rough 38 forming ^. £ ^ ϊϊ

or ^ {rif ^ -5} ^: 'v ^ .iii & ^

lating "pressure had a Haiimue of etira 100 mi of mercury. The frequency of the two oscillating pressures was for example 60 vibrations per minute (1 Hertz). The pressure in the Line 68 can be constant, for example at 20 ma mercury lie. A constant Dniek of this size in line 68 ensures that a minimum diastolic form is constant between the purgings. in the system, and that in particular, such a minimal form within the organ the organ chamber 10 is supplied via the line 14. It will believed that this prolongs the viability of the organ will.

The parts that come into contact with the perfusate are preferred made from silicone rubber so that they are harmless to blood.

In a device according to the invention, any medium can be used in the conduit 68 and the space 66 between the conduit section 62 and the sleeve 64 as well as in other areas which can be pressurized, as the case may be

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ORIGINAL INSPECTED

desired characteristics in terms of elasticity or flexibility. Liquids of different viscosity, such as for example oil, silicone oil or water result in different Compliance characteristics, which in turn are different from the characteristics of gases. An incompressible liquid, such as saline solution, can be used while the line 68 is being shut off so that the line portion 62 has little compliance is obtained, which then results in only very little damping or modulation of the pressure pulses passing through.

The aforementioned special embodiment is only intended to serve as an example, without the inventive concept in this way restrict in any way. Rather, the invention can be used in many different devices, including perfusion devices intended for organs, which include: a) a container for an organ; b) a supply line for perfusate to the organ in the container; c) a device for generating a pulsating Pressure in the perfusate supplied to the organ; d) a device to ensure a minimum pre-pressure in which by the body maintain circulating perfusate between pressure pulses; e) a device for oxygenating the of the Organ of coming perfusate; and f) a control device via which the delivery of the pump and also the period of the High pressure pulses is adjustable.

Manually controllable devices can be provided to monitor the temperature and pressure of the fluid being supplied to the organ To change the perfusate, as well as to control the pulse rate or size as well as the systolic duration of each of the Pulse generated by the pump.

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Claims (12)

Mar. 29, 1971 - 12 - Baxter Laboratories, Inc. Da / is Device for generating a pulsating flow in a line with a pump for generating a pulsating pressure which causes a medium to flow in the conduit, characterized in that a Part of the line made of an elastic, or flexible Id θ stands tubular section (44; 62 Y, which is surrounded by a sleeve (42; 64, 37 ') sealed against it, which delimits a pressurizable space (45; 66; 72) around this tubular section, and that a device ( 58 or 78; 68; 76) is provided for controlling the pressure in this space, whereby the flow pattern of the medium flowing through this line section can be controlled as a function of the pressure prevailing in this space. 2. Apparatus according to claim 1, characterized in that the line section (62) downstream and preferably is provided adjacent to the pulsating pressure generating pump (12). 3. Apparatus according to claim 1 or 2, characterized in that the pump (12) has a cylinder (42) with an axially therein arranged, elastic or resilient tube (44) and seals (47, 49), which the outer wall shut off the pipe from the inside, which forms a closed path for the medium to be pumped, that further an inlet (46) and an outlet (48) are provided for the flow through the pipe (44), the one one-way valve each to prevent backflow (50) comprise the cylinder (42) having an inlet (52; 79) to the space inside the cylinder and outside 109843/120 7 of the tube connected to a first source (58; 78) oscillating pressure is in connection, via which the pulsating pressure of the pump (12) by repeated Compression and expansion of the tube (44) can be generated. 4. Device according to one of the preceding claims, characterized in that the line for the pulsating flow forms a closed circuit. 5. Apparatus according to claim 4, characterized in that part of this line has a vestibule (38) of enlarged Forms transverse dimensions immediately upstream of the inlet (46) of the pump (12) to increase the Pump power is arranged. 6. Device according to one of claims 3-5 »characterized in that the sleeve (64) and the cylinder (42) consist of a single, one-piece component. 7. Apparatus according to claim 5, characterized in that the conduit part forming the vestibule (38) is surrounded in a sealing manner by a second sleeve (37 '), the one second, pressurizable space (72) bounded around this line part and that with a second source (76) stands for oscillating pressure that is not in phase with the oscillating pressure from the first source (68) is. 8. Perfusion device for organs, characterized in that it comprises a device according to one of the preceding Contains claims. 109843/1207 9. A method for transferring a medium from a source of pulsating pressure to an organ, the said organ the line supplying the medium receives a pulsating flow, characterized in that a flexible or The elastic part of the line is exposed to an external pressure that differs from atmospheric pressure, by means of which the scheme of the pulsating flow is modulated according to this external pressure. 10. The method according to claim 9, characterized in that the external pressure is greater than atmospheric pressure and is constant to the organ during the total period of pulsating flow the perfusate with a minimum of To supply the form. 11. A method for conveying a medium through a first line, characterized in that the medium first within one, from a second, to a pulsating working pump leading line formed vestibule is collected, that then the line forming the vestibule compressed and thereby the medium is driven into the pump and then from this into the first line is pumped. 12. The method according to claim 11, characterized in that the first line is connected to a living organ and that a liquid perfusate is used as the medium. 109843/1207 Blank page