EP2242524A1

EP2242524A1 - Passive flow regulator for infusion of medicaments

Info

Publication number: EP2242524A1
Application number: EP09709010A
Authority: EP
Inventors: Eric Chappel; Stephan Gamper
Original assignee: Debiotech SA
Current assignee: Debiotech SA
Priority date: 2008-02-09
Filing date: 2009-02-06
Publication date: 2010-10-27
Also published as: US20100324504A1; WO2009098314A1

Abstract

Flow regulator for the infusion of medicaments, comprising, in succession, a substrate (1), a channel (5), a spacer (3) and a membrane (4), the latter having at least one hole (6) communicating with the channel (5), characterized in that the regulator is produced from at least two separate elements (1-4), the first element comprising the membrane (4) and the second element comprising the spacer (3).

Description

PASSIVE FLUX REGULATOR FOR INFUSION OF DRUGS

Field of the invention

The present invention is in the field of drug delivery in liquid form. It concerns more precisely the flux regulators used for this purpose.

State of the art

The operating principle of a flow regulator of the state of the art (see FIGS. 1 and 2) is described in particular in the patent application WO 99/38552. It is a membrane 4 pierced at its center 6, which is deflected by the pressure of the reservoir and which comes into contact with a substrate 1 on which is etched a fluidic channel 5, the latter being p. ex. in the form of a spiral. The membrane 4 thus closes this channel 5 after contact, with the exception of the location where the central hole 6 is located. The liquid of the reservoir therefore flows through the central hole 6 and then along the channel 5. The membrane 4 the distance between the membrane 4 and the substrate 1 and the channel 5 are dimensioned so that the fluid resistance of the channel 5 varies proportionally with the pressure in the tank. The flux is therefore constant in a certain pressure range. It does not depend on the pressure. In case of overpressure, the channel 5 closes completely and the flow is interrupted.

The regulator described in WO 99/38552 is manufactured by etching, e.g. ex. chemical, or by ionic type dry fastener, the central hole 6 of the membrane 4, the membrane 4 itself, the spacer 3 between the membrane 4 and the substrate 1 and the channel 5 itself. The membrane 4 and the spacer 3 are created simultaneously from the same element. Thus an error on the thickness of the membrane 4 also affects the thickness of the spacer 3 and vice versa. General presentation of the invention

The present invention relates to a new flow regulator structure and a new method which simplifies the assembly of the different parts of the regulator and which makes it possible to achieve better manufacturing tolerances by the same method used.

The flow regulator according to the invention successively comprises a substrate, a channel, a spacer and a membrane, the latter comprising a central hole communicating with the channel. The regulator is characterized in that it is made from at least two distinct elements, the first element comprising the membrane and the second element comprising the spacer.

According to one embodiment of the invention, sheets of controlled thickness and low roughness are stacked, each sheet having a particular function. These sheets are for example obtained by rolling, then by wire cutting or stamping, and then by mirror polishing. Thus the stack consists of a flat substrate with only one exit hole, a thin sheet with the through channel, a thin sheet with a disk pierced for the spacer, a thin sheet pierced in the center for the membrane. This stack makes it possible to master before assembly all the thicknesses, such as for example the membrane, the spacer and the depth of the channel, which is thus perfectly defined by the thickness of the sheet chosen for this function. For a square-shaped channel, the flow rate varies as the power of four on the side of this square in the approximation of the laminar regime for a Newtonian fluid and at constant temperature. By this method the tolerance on the depth is perfectly mastered and there remains only the tolerance on the width of the channel, that is to say that which was already rather well mastered previously. The regulator according to the invention makes it possible to achieve flow accuracies which were not attainable by the standard machining methods of silicon or Pyrex.

The exit hole can also be offset on the edge of the membrane to have the inlet and the outlet of the fluid on the same side. The regulator according to the invention can be completely clogged at a defined pressure in order to avoid overdoses. This threshold pressure is reached when the channel is completely covered by the membrane.

The regulator according to the invention may comprise means for measuring the deflection of the membrane, for example using strain gauges placed in the Wheatstone bridge configuration on the membrane. These gauges can be made by ion implantation or diffusion if the membrane is silicon. External gauges may also be placed on the membrane, for example by gluing, if said membrane is not made of a piezo-resistive material.

Detailed exposition of the invention

The invention is described in more detail below by means of examples illustrated by the following figures:

FIG. 1, already described above, illustrates a flow regulator of the state of the art in the rest position.

Figure 2, also described above, illustrates the regulator of Figure 1 in active mode, when the membrane is deformed.

FIG. 3 presents an exploded and schematic view of a first embodiment of a flux regulator according to the invention. FIG. 4 shows a second embodiment of a flux regulator according to the invention. FIG. 5 illustrates the steps of a method for producing a substrate-channel assembly according to the invention.

A first embodiment of the flux regulator according to the invention is illustrated in FIG. 3a. This is formed from four sheets 1 to 4, a first sheet intended to form the substrate, a second sheet 2 intended to contain the channel 5, a third sheet 3 having a large central opening 7 intended to form the spacer 4 and a fourth sheet acting as a membrane 4. The membrane 4 may be made of polished silicon, a material that has excellent mechanical properties, but also metal or any other material that has a high elastic limit. The piercing of the membrane 4 may be carried out by chemical etching or by very short-pulse laser drilling, such as for example the femtosecond laser, which avoids plastic deformation by heating the membrane 4. The direction of the laser drilling is important because a bead may be present on the periphery of the hole 6. Thus in the center of the channel 5 is preferably cleaned a circular recessed portion whose diameter is at least equal to the hole 6 of the membrane 4, which allows on the one hand increase the tolerances on the positioning of the membrane 4 with respect to the channel 5 and also to prevent this eventual bead from creating a spacing and thus a poor sealing of the channel 5 at the level of the hole 6.

The spacer 3, the channel 5 and the substrate 1 can be made for example of metal, such as for example steel, or more advantageously ceramic LTCC. These co-cured ceramics are in fact drilled, for example by laser, machined, aligned, serigraphed on the surface and then pressed in the green state, which allows three-dimensional stacks, and then the hot sintering makes it possible to assemble permanently and without leakage the different elements. The final assembly method, for example for rolled sheets of metal, can be a recess, a weld or a bonding. For large systems it is preferred to use a recess via two precision circular parts which enclose the different sheets, for example by clamping with screws. The upper part has to be recessed to create a cavity 9 above the membrane and pierced in the center for the arrival of the fluid.

The fluid outlet can be arranged in the lower part or in the upper part of the regulator.

When the outlet of the fluid is situated opposite the inlet 6 (see FIG. 3), exit holes 10 and 11 are respectively formed in the sheet 2 containing the channel 5 as well as in the substrate 1.

When the outlet is located on the same side as the inlet, the membrane sheet 4 also includes an outer hole of larger diameter than the central hole for the outlet.

The alignment is obtained either by additional centering holes, or by the substrate 1 itself. Indeed there is no tolerance on its thickness or its width. It is easy to imagine a kind of cavity in which the sheets would fit. Alignment pins can be used for large systems. Alignment is facilitated if the edges of the leaves are circular and the housing of the substrate in which these sheets fit.

The surface roughness of the membrane 4, the channel 5 and the substrate 1 must be much smaller than the characteristic dimensions of the component, that is to say the depth of the channel 5, the thickness of the spacer 3, the thickness of the membrane 4 and the diameter of the inlet hole 6. The use of laminated sheets, machined and already mirror polished before the final assembly substantially reduces leaks during operation.

The channel 5 itself can be made by electroplating directly on the substrate 1, for example by lithographically making the negative channel 1 to achieve the deposition of the metal hook layer, which after growth will define the channel 5 embossed . The negative part of the spacer 3 can also be made by electroplating. The surface roughness obtained by electroplating is entirely compatible with the proper functioning of the component. In order to preserve the layer assembly principle whose thickness is well controlled, it is possible to carry out the growth of the channel 5 negative on a sacrificial layer which will be dissolved before assembly on the substrate 1.

FIG. 4 represents an assembly of a passive flux regulator with the spacer 3, the channel 5 and the substrate 1 made in one piece, for example by plastic or ceramic injection, or by plastic embossing. The cover 8 can also be made in this way. The cover 8 includes a cavity 9 which allows a good distribution of the pressure above the membrane 4.

The membrane 4 is made of a material having a high elastic limit and advantageously the minimum of internal stresses.

This method has many advantages compared to the machining methods of the state of the art. With the method according to the invention, the relative tolerances are wider, in particular for the micro machining of silicon or metal. When the substrate, the channel and the spacer are formed from a single element, the method according to the invention consists mainly in the production of a single mold of required dimensions, for example by one or two electroplating operations. nickel on a positive or negative channel and spacer. Replication of the components by plastic injection or embossing from this mold achieves excellent relative tolerances and good surface roughness, with suitable process parameters such as pressure cooling and injection time. embossing. This method significantly reduces manufacturing costs and the number of process steps. A coating may be necessary on all parts of the components to ensure their biocompatibility, for example a diamond layer, a layer of gold or titanium. The various elements are then assembled by direct bonding plastic / silicon or plastic / metal, or by bonding, embedding. A groove or a groove can be arranged in the plastic or ceramic substrate to be able to extend the glue. The membrane 4 is then positioned on the substrate 1 for the polymerization with possibly a pressing pressure to maintain the assembly tolerances.

In the microreplication configuration, the difficulty is essentially reduced to a single critical alignment, namely that of the membrane 4 on the replicated part. A self-centering technique via a groove or extra thickness on the replicated part can be used. Alignment holes may also be drilled in the membrane 4 and the replicated portion of the regulator.

For manufacturing methods involving microreplication, special attention must be paid to the design of the original part (master) which will then be used to generate the injection molds or embossing heads. The tolerances required for this element require the realization of the master by micromachining techniques.

1. Wet etching, for example KOH, of a silicon wafer to make the spacer then dry etching for the spiral, with a slight angle to facilitate demolding. 2. Dry or wet etching of Pyrex for the spiral and realization of the spacer by deposition of resin, for example SU8 by spinning, followed by photolithography and eventually optionally a metallization (see process flow below).

FIG. 5 illustrates an exemplary embodiment of the master, including a deposition of SU8 after dry etching of the channel, followed by a photolith and possibly a metallization. Of course, the invention is not limited to the embodiments illustrated and discussed in the present text.

Claims

claims

1. Flow regulator for the infusion of drugs successively comprising a substrate (1), a channel (5), a spacer (3) and a membrane (4), the latter comprising at least one hole (6) communicating with the channel (5), characterized in that the regulator is made from at least two distinct elements (1 -4), the first element comprising the membrane (4) and the second element comprising the spacer (3).

2. Flow controller according to the preceding claim wherein the first element is a sheet.

3. Flow controller according to one of the preceding claims wherein the second element also comprises the channel (5).

4. Flow controller according to the preceding claim wherein the second element also comprises the substrate (1).

Flow controller according to claim 1 or 2, comprising a third element which comprises the substrate (1) and the channel (5).

6. Flow controller according to claim 1 or 2 comprising four elements (1 -4), the first (4) comprising the membrane, the second (3) having the spacer, the third (2) having the channel and the fourth

(1) comprising the substrate.

7. Flow controller according to the preceding claim wherein the four elements (1 -4) are sheets.

Flow regulator according to the preceding claim wherein at least one of the sheets (1 -4) is obtained by rolling.

Flow regulator according to claim 7 or 8 wherein at least one of the sheets (1-4) (4) is made of polished silicon.

Flow regulator according to one of the preceding claims, comprising means for measuring the deflection of the membrane (4).

1. Regulator according to one of the preceding claims consisting of at least one sheet whose circumference is circular.

12. Regulator according to one of the preceding claims, the inner periphery of the spacer (3) is circular.

13. Regulator according to one of the preceding claims sized so that the fluid path is obstructed when a threshold pressure of the fluid inside the regulator is reached.

14. Method of manufacturing a flux regulator according to one of the preceding claims comprising the stack of four sheets (1 - 4), the first being intended to form a substrate (1), the second a channel (5). , the third a spacer (3) and the fourth a membrane (4).

15. Method according to the preceding claim comprising a step of aligning the sheets (1 -4).

16. Method of manufacture according to one of claims 1 to 12 characterized in that the spacer (3) and / or the channel (5) are created by electroplating or any other method of deposition.