DE4039191C1 - Liq. drug infusion pump - has rigid housing contg. drug chamber with volume varied by piston like ejector acting with spring unit - Google Patents

Abstract

Liq. drug infusion pump has a rigid housing (21) contg. a drug chamber (29) of volume which can be varied by a piston-like ejector (30) acted on by a pre-tensioned compression spring unit (27) fitted to the housing (21). The compression spring unit (27) is formed by a packet of series-connected disc springs (10), pref. identical metal or plastics disc springs which are sepd. by rigid spacer discs (32) and mounted in a concertina housing (28). USE/ADVANTAGE - The pump is an extra-corporeal or fully implantable, opt. once-contg. use pump for long term drug treatment e.g. analgesic therapy, chemotherapy and/or spastic therapy, as well as diabetic treatment. Compared with the pump of DE3507818, the pump has a compression spring unit of sufficient spring extension stroke to ensure constant delivery rate over the drug ejection phase.

Description

The invention relates to an infusion pump known for example from DE 35 07 818 C1 for dispensing liquid drug with one in a rigid ge house-trained medication with an outlet ment chamber, the volume of which by a piston-like Squeezing device under the action of a on the housing supported, preloaded compression spring device ver is changeable.

Many therapy procedures require continuous and even administration of a liquid drug over long periods of time. For this, infusion pumps are used, which are considered extra corporal portable pump if necessary in combination with a implantable port system or work as a full implant can be used. Therapeutic application areas are z. B. the pain, chemo and / or Spasticity therapy and diabetes treatment with the  Aim to patients who are on long-term medication may be able to provide outpatient care as possible. The The delivery rate of such infusion pumps is 1 ml / day to 10 ml / day, with a constant flow rate is sought.

In a known infusion pump (DE 29 16 835 A1) is a flexible one within a rigid housing Container arranged in the form of a bellows, the one end firmly with an annular wall of the casing it is connected and that under the action of a two phase fluid that evaporates through body heat and egg exerts pressure on the bellows by working together pressure is emptied. This is the driving force due to barometric pressure and temperature fluctuations influenced in the physiological / pathological area, so that a constant delivery rate cannot be achieved leaves. Besides, this infusion pump is because of it Dependence on body heat does not increase extracorporeally use.

In order to remedy the deficiencies described in one other infusion pump (EP 2 42 351 A1) as an extrusion direction for a flexible reservoir an elastic prestressed annular body provided. The ring shaped body is a silicone rubber ring in which the reservoir is integrated and to increase the Long-term stability a ra dial contains preloaded cylindrical metal spring. The manufacture of such an annular body with a ver required for a constant flow rate shaping characteristics are difficult. In long-term signs of material fatigue too unsuspecting verifiable changes in tension that affect the Infusion pressure and thus the flow rate, d. H. the medi change dose  

Another known infusion pump (DE 35 07 818 C1) uses only one as a printing device preloaded, frusto-conical coil spring Metal between the rigid housing and a piston-like propulsion part is supported. Disadvantageous with a frusto-conical coil spring is that the spring force is largely dependent on the travel and the characteristic curve can be progressive, so that no constant pressure force and therefore no con constant flow rate for the drug to be administered are achievable.

Another known implantable infusion pump (WO 87/04 631) consists of a housing, one of which is the Wall containing a liquid-containing chamber is thin plastic membrane made of elastomeric koni ring sections which are covered with metallic cylinders alternate ring sections, is formed and represents the squeezing device. The metallic Ring sections are in complex production in that Membrane elastomer embedded. By filling the kam The spring membrane is stretched and the approximately in Ring sections lying on the same plane form one with constant force effective drive of the Auspreßvor direction. The travel of the combined, flying ge stored ring sections is short, however, and the Spring force is correspondingly small, so that the Pumplei is insufficient for some applications.

The invention is based, the Infu sion pump according to DE 35 07 818 C1 to improve so that an extracorporeally portable, as well as fully Plantable or disposable pump created fen, whose mechanical compression spring device sufficient total suspension travel over the emptying phase a constant delivery rate guaranteed.  

This object is achieved in that the compression spring device from a package in series switched arranged disc springs is formed.

With a suitable choice, the diaphragm springs have the geome trical dimensions a spring characteristic, which is in the above area of the characteristic curve becomes flat. In this flat The characteristic range is only weak depends on the travel and remains almost constant. The This flat characteristic area is used as an ar beitsbereich for the constant rates according to the invention pump used. Since the usable travel range is one single spring is relatively small for one Pump of acceptable size and sufficient reserve However, the travel volume is of the order of magnitude 7 mm to 10 mm are required, several tel lerfedern arranged in a row so that the individual Add spring travel with constant spring force. With such a compression spring device, one can constant reservoir pressure over the evacuation cycle, d. H. achieve a constant funding rate because that Belleville washer package is essentially independent of travel Has power that can be used to do that piston-like squeezing device with constant surface to postpone. The package of coni connected in series shear disc springs is flat, so that a flat construction way of the housing possible with sufficient spring travel is. The manufacturing costs are due to the simple Chen construction low. The pump stands out characterized by high operational reliability because

• a) Overdose when used as directed closed is;
• b) no susceptibility to failure due to electronic construction elements and electrical energy source is given;
• c) barome does not influence the driving force  trical pressure and temperature fluctuations in the physiolo gische / pathological area occurs; and
• d) disc springs are robust and no long-term fatigue show signs of deterioration. The dynamic demands Disc springs are used in this application very low.

The plate springs of the plate spring pair are preferably ketes until the start of the approximately horizontal characteristic curves area biased. The almost horizontal course the upper characteristic range of the disc spring assembly serves as a work area for the pressure spring device tung. The spring force is only in the work area low from the further spring deflection (travel) dependent, so that over the remaining deformation path of the spring assembly a quasi constant force for ver which is used to increase the volume of the Reduce fluid reservoirs.

The disc springs of the package are advantageous identical and made of metal or plastic. There is one between each of the adjacent disc springs stiff spacer arranged which the springs in keep a central position and as a support and Serve as a support surface.

The disc springs are preferably in a fold bellows-like wrapping housed, one end of which is attached to a bottom wall of the housing and de ren other end with a plate-shaped propulsion part is connected, the egg in the medication chamber NEN displaceable piston forms and that if necessary in the Bottom wall ventilation holes for the cladding cavity available. The bellows-like covering exists preferably made of metal. In the bottom wall of the casing The opposite top wall is a pot-shaped one  Pre-chamber formed on the outside of egg ner pierceable membrane is closed and the inside with the medication chamber of the housing Culverts connected. The inner surface of the Antechamber wall can be attached to the passages with a Filter element equipped as the Kontamina tion lock serves and z. B. Die cuts that at Pierce the membrane with a cannula for filling the medication chamber arise.

For a fully implantable pump design it is suggested to put the bottom wall of the case on its outer surface with a cavity-forming membrane to span the z. B. firmly is glued. The cavity between the membrane and the Bottom wall serves through the ventilation holes in the bo denwand as a volume compensation chamber and takes the Ven ventilation air due to the volume vol shifts on.

As an alternative to the ventilation of the compression spring device containing bellows-like covering can Ventilation holes are eliminated when the medication came mer is filled with a medium that z. B. by Sufficient condensation or evaporation processes Changes in volume.

In a particularly advantageous embodiment of the invention it is intended that the disc springs as slotted Feathers with a ring of radially inward Fe tongues are formed. Slotted disc springs are for the compression spring device of an infusion pump pe particularly cheap because they are so simple can be dimensioned so that they are in a Place the infusion pump in an acceptable small size leave; because they have the largest possible flat ver  have running characteristic range in which the spring force fluctuates by a maximum of +/- 5%, because in this Characteristic range one to achieve the pumping effect generates sufficiently large force and because its maximum critical spring stresses occurring below the Strength limits of spring materials are.

A fill level indicator with which the fill level of the Medication chamber can be read realize according to the invention that with the plat ten-shaped propulsion part one end of a display element mentes, the other end of which is connected by the Bottom wall of the housing slidably protrudes. It can use two variants of display elements and it can be a rigid pen or a flat flexible band. The length the rigid pin is dimensioned so that it at completely empty medication chamber flush with the Completes the outer surface of the bottom wall of the housing. Circumferential scaling marks e.g. B. in the form of a Line division or colored areas on the pen enable level detection. A flat bend sames, e.g. B. metallic tape is at the exit set through the bottom wall of the housing by 90 ° places and z. B. in a guide rail on the floor Wall outside so that it runs smoothly and is displaceable parallel to the housing base outer surface. With this variant, the scaling markings be attached to the bottom wall of the housing, so that with emptying medication chamber the band moving radially towards the center of the pump End marking lines or color markings free gives. Both embodiments of level indicators have the advantage that the path change of the pin or Band directly proportional to the change in volume of the medi amount of funds is (- <linear scaling). The filling  level indicator enables a constant check of the Function and the current filling status, whereby the medication application is controllable and safe rer becomes.

There is a capillary in the outlet of the medication chamber resistance used as a throttle element. With this Throttle element is the desired flow rate festge sets. It can be a hollow fiber which in an annular space in the peripheral wall of the housing is wrapped inserted.

In the drawing is an embodiment of the He the invention is shown schematically.

It shows:

Fig. 1, the calculated spring characteristic of a dimensio ned slotted disc spring,

Fig. 2 shows the calculated spring characteristic of a packet of four series-connected slotted disc springs,

Fig. Federspannungsver the calculated critical course of the sized slotted plate spring 3,

Fig. 4 is a slotted plate spring, in side view,

Fig. 5 is a slotted disk spring in top view,

Fig. 6 shows a section through an infusion pump with four disc springs in the empty state, with an embodiment of a level indicator and

Fig. 7 is a sectional view of the infusion pump of Fig. 6 in the filled state,

Fig. 8 shows a section through a filled infusion pump with another embodiment, a level indicator,

Fig. 9 is a top view of the level indicator shown in Fig. 8,

Fig. 10 is a cross section through the level indicator along the line XX in Fig. 9 and

Fig. 11a, 11b different ways of scaling the level indicator according to Figs. 8-10.

A slotted plate spring suitable for a spring assembly of four slotted plates in the pressure device of an infusion pump according to FIGS. 6 and 7 is shown in FIGS. 4 and 5. Your dimensioning can be iteratively selected with the help of a computer program by varying the geometry and material parameters so that the desired dimensions of an infusion pump are adapted to the largest possible flat area of the declining characteristic curve, which serves as a working area and up to it Begin the spring or the spring assembly must be biased so that a quasi-constant force is available via the residual deformation of the spring, which generates a constant flow rate of the squeezed medication.

A preferably usable slotted disc spring 10 made of metal consists of a circular outer edge 11 , on which a ring of radially inwardly directed spring tongues 12 is formed. Each spring tongue 12 runs obliquely upwards in the plane of the edge 11 from the outside inwards and ends at a blunt tip 13 . All blunt tips 13 of the spring tongues 12 lie on a circle, the center of which coincides with the center of the edge 11 . The regions 14 adjoining the edge 11 between two spring tongues 12 each have an arc shape. All arcs 14 also lie on a concentric circle. The slotted plate spring 10 is conically shaped, the Ver young evenly extending from the outer edge of the ring 11 to the tips 13 of the spring tongues 12 . The theoretically expected spring characteristic of a single slotted disc spring 10 is shown in Fig. 1 Darge. A package of four slotted disc springs 10 , which are connected in series, as in the example shown in FIGS. 6 and 7 , has a theoretically expected spring characteristic curve according to FIG. 2. The usable spring travel range of the disc spring package consisting of four slotted disc springs 10 is at the preferred example is about 9 mm. The average spring force in this area is approximately 150 N with a fluctuation range of +/- 5% to the mean value ( Fig. 2). The Tel spring pack must be pretensioned by approx. 13 mm until the usable working area begins. The critical spring tension (fully flattened disc spring 10 ) is approx. 1400 N / mm ² ( Fig. 3), the tensile strength of the spring steel 67 SiCr5 with 1500 to 2200 N / mm ² is for a dimensioned disc spring 10 for the loads occurring in an infusion pump are sufficient.

An infusion pump 20 is shown in implantable embodiment. It has a rigid circular cylindrical housing 21 with a flat bottom wall 22 , a cover wall 23 opposite this parallel and a circumferential side wall 24 . The top wall 23 and the side wall 24 are supplemented by an inner shell body per 25 adapted shape, so that these parts are two layers. The indicated screws 26 releasably connect the bottom wall 22 and the top wall 23 to one another while simultaneously fixing the shell body 25 , so that the housing 21 can be opened. The cover wall 23 and the shell body 25 include a medication chamber 29 is disposed in which a compression spring device 27 as a drive for a piston-type extrusion device. The compression spring device 27 is in a bellows-like envelope 28 with a closed fold wall z. B. made of metal, the wall at ih rem with the help of screws 26 on the bottom wall 22 is fixed and the other inner edge z. B. is sealed by gluing to the peripheral edge of a rigid plate-shaped propulsion part 30 . The driving part 30 has a circular shape and runs parallel to the bottom wall 22 and the top wall 23 . In its center it is provided with a circular cylindrical bulge 31 , the closed end of which is turned towards the bottom wall 22 . The largest diameter of the bellows-like sheath 28 is slightly smaller than the inside diameter of the medicament chamber 29 , so that device 27 can be moved freely.

The compression spring device 27 consists of a package of four slotted Tellerfe connected in series 10 , which ben 32 are separated by three annular spacers 32 . The spacers 32 on the one hand have the task of keeping the plate springs 10 in a central position, and on the other hand they serve as a support and support surface between adjacent plate springs 10 . The middle of the three di punch disks 32 is provided on its outer edge with a ring edge 33 projecting beyond its two levels, while corresponding ring edges 33 a are provided on the inner circumference of the two outer spacers 32 . The ring edges 33 , 33 a meet the Zentrierungsaufga be for the plate springs 10th The coaxial inner holes 34 of the three spacers 32 have a diam water that allows the passage of the circular cylindrical expansion 31 ( Fig. 7). The outer edge 11 of the outer plate spring 10 on the bottom wall side is supported on the inner surface of the bottom wall 22 , and the outer edge 11 of the inner plate spring 10 bears against the driving part 30 . The edges 11 of the two mittle ren springs 10 rest on the middle spacer 32nd The spring tongues 12 of all the springs 10 of the spring package point towards the center of the axis of the housing 21 .

The bottom wall 22 is provided in the region of the bellows-like casing 28 with a plurality of bores which form ventilation holes 37 for ventilation of the casing 28 containing the spring drive. In the depicted th implantable infusion pump, a thin elastic membrane 35 is provided to cover the ventilation holes 37 , which spans the bottom wall 22 flat and z. B. is glued. The space 36 between the membrane 35 and the bottom wall 22 serves as a volume compensation chamber which receives the ventilation air when the medicament chamber 29 is filled ( FIG. 7) and releases it again when the medicament chamber 29 is emptied, so that the membrane 35 seals itself tightly against the outer surface of the Bottom wall 22 creates ( Fig. 6).

As a level indicator in the example of FIGS. 6 and 7, a cylindrical pin 40 is used , which is mounted on the bottom surface of the bulge 31 perpendicular to this in a positive or non-positive manner and whose longitudinal central axis runs ver in the central axis of the pump. The diameter of the pin 40 is dimensioned so that it can slide through a central ventilation hole 37 with a slight play. The pin 40 is so long that it at completely emptied medicament chamber 29 is flush with the outer surface of the bottom wall 22 from closes (Fig. 6), while it projects with filled Medica ment chamber 29 with the largest portion of its length to the outside (Fig. 7) . The pin 40 can have differently colored longitudinal sections 40 a, which serve as scaling. The pin 40 is only shown in the example for the sake of illustration. Its use is limited to a non-implantable infusion pump, in which there is no membrane 35 and an observation of the position of the pin 40 relative to the bottom wall 22 is possible.

The ventilation holes 37 and the membrane 35 can fall off, when the medication chamber is filled with a sigkeit flues 29 z. B. experiences sufficient volume changes through condensation or evaporation processes. Such an infusion pump 120 is shown in the filled state in FIG. 8. The infusion pump 120 is extracorporeally portable and its components correspond to the example of FIGS. 1 to 7 except for the level indicator . The level indicator in this example has a flat, flexible band 60 , one end 61 of which on the circular cylindrical extension 31 of the driving part 30 is permanently attached. The band 60 protrudes through a slot 71 in a connection piece 70 , which is fitted in an appropriately fixed manner in an opening 63 in the bottom wall 22 . At the exit from the slot 71 , the band 60 is deflected sideways via a roller 72 . At the outward end of the nozzle 70 , an elongated flat housing 64 is formed, which it extends to one side and which is firmly and tightly connected to the surface of the bottom wall 22 . The housing 64 is shown in plan view in FIG. 9. It is designed as a elongated body, in the upper wall of which a viewing window 66 is recessed, which is sealed by a transparent pane 67 . The Ge housing 64 forms with the surface of the bottom wall 22 a chamber 68 , the width of which is only slightly greater than the width of the band 60 and in which the band 60 is guided to be longitudinally displaceable. The movement of the belt 60 can be observed through the viewing window 66 , the width and length of which correspond approximately to the dimensions of the belt 60 .

On the bottom of the chamber 68 , a scale 65 is introduced , which is slid over from the free end 62 of the band 60 and indicates the respective filling state of the medicament chamber 29 . Figs. 11a and 11b show two different ways of Skalenge staltung. The elongated strip of the scale 65 a ( Fig. 11a) is divided into four equal areas, which are delimited by lines W, X, Y, Z, O. W shows the area full of 100% filling, while Z only shows a 25% filling. When the end 62 of the band 60 reaches the line O, the medicament chamber 29 is empty. The days to refill the medication chamber 29 can be calculated by observing the time it takes for the end of the band 62 to cover the distance W / X etc.

The scale 65 b ( Fig. 11b) is divided into colored longitudinal sections 1 , 2 , 3 , 4 . The longitudinal section 1 can be green and give a fill level of 100% to 75% again. The longitudinal section 2 is yellow and corresponds to a degree of filling of 75% to 50%. The longitudinal section 3 can be colored orange and represent the degree of filling 50% to 25%. The longitudinal section 4 is red and shows the degree of filling 25% to 0%. When the end 62 of the band 60 reaches the end edge of the longitudinal section 4 , the medicament chamber 29 is empty. The user of the infusion pump 120 equipped with this scale 65 b must ensure that the medication chamber 29 is refilled when the end of the band 62 enters the red area. The four longitudinal sections 1 , 2 , 3 , 4 each cover a quarter of the total length of the scale 65 b. The longitudinal extent of the scale 65 corresponds to the stroke of the closed end of the bulge 31 in relation to the inner end wall 43 of the cup-shaped prechamber 41 of the shell body 25 .

The shell body 25 is provided in the middle of its cover wall 23 adapted plate 25 a with a pot-shaped prechamber 41 , the circular cylindrical wall 42 of an inner end wall 43 protrudes into the medi chamber 29 and into the cavity from the bulge 31 of the driving part 30 insertable or is extractable from this. A septum 50 in the form of a circular disk is preloaded into a fit between the plate 25 a of the shell body 25 and the outer cover wall 23 so that it closes the open end of the antechamber 41 . The antechamber 41 is connected to the medicament chamber 29 via lateral openings 44 in the wall 42 . The openings 44 is on the inner surface of the wall 42 a z. B. hül sen-shaped filter element 45 , which serves as con tamination barrier between the prechamber 41 and the medicament chamber 29 when by means of a steel cannula, which is pierced by the rubber-elastic septum 50 , medication is filled into the medicament chamber 29 . With the help of the steel cannula can be carried out on the free in the prechamber 41 eye of the steel cannula and the bore 44 and the emptying of the medicament chamber 29 .

The shell body 25 is equipped with a radially thickened side wall 25 b, which is capped by a mantle surface 22 a of the bottom wall 22 and forms an annular cavity 46 therewith, in which a pillar flow resistance from z. B. hollow fiber material 47 is housed wound. In the annular cavity 46 open a radial bore 51 in the side wall 25 b and a through a bore in the jacket surface 22 a passed catheter 52 , the tip leads to a destination to which the drug is to be passed on. The drug chamber end of the capillary resistance (hollow fiber 47 ) is connected to the bore 51 . The distal end of the capillary resistor is connected to the pump-side end of the catheter 52 . The fluid dispensed from the medicament chamber 29 thus first passes through the hollow fiber 47 and then reaches the destination via the catheter 52 .

When liquid is injected through the pre-chamber 41 into the medicament chamber 29 , the spring assembly of the compression spring device 27 is tensioned. The springs 10 absorb that energy which is later required for the expulsion of the liquid through the outlet 51 . In this way, the infusion pump is "rechargeable" and can be used as often as required.

If during the pumping process the Druckfedervorrich device 27 relaxes and by pushing the drive part 30 in the medication chamber 29 medication element is pressed out through the bore 51 , the capillary resistor 47 forms a throttle element with which the desired constant flow rate of the medicament can be determined. When the outflowing drug has passed the capillary resistance 47 , it flows into the catheter 52 and flows with a constant flow rate to the application site due to the constant force of the spring assembly 10 biased to the beginning of the horizontal characteristic range.

Claims (10)

1 infusion pump for dispensing liquid medication with a in a rigid housing ( 21 ) ausgebil Deten, an outlet having Medicament chamber ( 29 ), the volume of which is supported by a piston-like extrusion device ( 30 ) under the action of a prestressed compression spring device on the housing ( 21 ) ( 27 ) can be changed, characterized in that the compression spring device ( 27 ) is formed from a packet of disc springs ( 10 ) arranged in series. 2. Infusion pump according to claim 1, characterized in that the plate springs ( 10 ) are biased to the beginning of the approximately horizontal characteristic range. 3. Infusion pump according to claim 1 or 2, characterized in that the plate springs ( 10 ) are identical and made of metal or plastic and that between each of the plate springs ( 10 ) a rigid spacer ( 32 ) is arranged. 4. Infusion pump according to one of claims 1 to 3, characterized in that the plate springs ( 10 ) are accommodated in a bellows-like envelope ( 28 ), one end of which is attached to a bottom wall ( 22 ) of the housing ( 21 ) and the other end is connected to a plate-shaped driving part ( 30 ) and that if necessary in the bottom wall ( 22 ) ventilation holes ( 37 ) are provided for the encapsulation cavity. 5. Infusion pump according to one of claims 1 to 4, characterized in that the bottom wall ( 22 ) of the housing ( 21 ) opposite the cover wall ( 23 ) has a cup-shaped prechamber ( 41 ) on the outside of a pierceable membrane ( 50 ) is closed and the inside is connected to the medication chamber ( 29 ) of the housing ( 21 ) via passages ( 44 ). 6. Infusion pump according to one of claims 1 to 5, characterized in that the bottom wall ( 22 ) of the housing ( 21 ) is spanned on its outer surface with a cavity-forming membrane ( 35 ). 7. Infusion pump according to one of claims 1 to 6, characterized in that the plate springs ( 10 ) are formed as slotted Tellerfe with a ring of radially inwardly directed spring tongues ( 12 ). 8. Infusion pump according to one of claims 4 to 7, characterized in that with the plate-shaped propulsion part ( 30 ) one end of a display element is connected, the other end through the bottom wall ( 22 ) of the hous ses ( 21 ) slidably projects and with a scale ( 40 a; 65 a, 65 b) interacts. 9. Infusion pump according to claim 8, characterized in that the display element is designed as a rigid pin ( 40 ) or as a flat flexible band ( 60 ). 10. Infusion pump according to one of claims 1 to 9, characterized in that a capillary resistor ( 47 ) is used as a throttle element in the outlet ( 51 ) of the medicament chamber ( 29 ).