LU87753A1 - AEROSOL DISTRIBUTOR - Google Patents

Description

AEROSOL DISTRIBUTOR

The present invention relates to a dispenser which is particularly suitable for dispensing and administering metered amounts of fluid. The main use of such a device is to dispense metered amounts of a drug-containing liquid in aerosol form for inhalation therapy. The invention relates more particularly to a dispenser of this type in which the dose of medicament is administered according to the inhalation by the patient.

Dose controlled inhalers are well known in medicine for treating respiratory conditions or alleviating the effects thereof, such as asthma, and generally include a pressurized aerosol dispenser container removably mounted in a support and means for actuating a valve in the container to cause the release of a metered quantity of liquid containing the medicament to be introduced into a chamber comprising a mouthpiece to be used by the patient. The means for actuating the valve may be a manually operated control device, or the patient may simply push the closed end of the container with a thumb or finger, but in either case the patient must coordinate valve operation with inhalation to obtain maximum benefit from the medication.

Unfortunately, many patients requiring this type of treatment are unable to coordinate their breathing with this manual valve control.

The object of the present invention is to provide a dose-controlled inhaler in which the release of the drug in the form of an aerosol is caused by the patient's inhalation.

In accordance with one aspect of the present invention, there is provided a dispenser operable by inhalation for use with a pressure container dispensing an aerosol which comprises: a receptacle for said container; means defining a storage compartment arranged to receive a controlled dose from the container and having an outlet; a valve having a closed position in which it closes in service the pressure outlet of the dose in the chamber and an open position in which the outlet is open to allow the dose to exit the compartment and enter the outlet nozzle; an outlet nozzle through which a user can inhale and a release device reacting to the inhalation of the user, so as to put said valve in the open position.

In a preferred embodiment, the reaction of the piston unit to inhalation causes a valve to be actuated to release the stored medication from the receiving and storing means to the mouthpiece.

Many embodiments of the present invention will now be described by way of example only with reference to the appended figures which respectively represent:

Figure 1, a view mainly in section of an inhalation device according to the present invention;

Figure 2, a sectional view on a larger scale of certain parts of Figure 1;

Figure 2a, a view similar to Figure 2, but showing part of a modification thereof and;

Figure 3 is a sectional view of another embodiment of the present invention.

As can be seen in Figures 1 and 2, an inhalation device 2 comprises a housing 4 containing a chamber 6 for an aerosol dispenser containing a medicament 8. The dispenser 8 comprises a box 10 and an output wire 12 of which the details are shown more clearly in Figure 2.

Box 10 contains a drug in suspension or in solution in a liquid aerosol propellant, the drug suitable for inhalation therapy. The interior of the box 10 communicates with the outlet tube 12 through an outlet valve (which is of conventional shape and is not shown), the valve comprising a metering chamber. The tube 12 has a transfer nozzle (not visible in the figures) which, when the tube is moved inward relative to the box 10 and only then, establishes communication between the interior of the metering chamber and 1 inside the tube. The housing 4 has a bore 14 co-axial with the compartment 6 and the outlet tube 12, fits in this bore, the outer end face of the tube coming into contact with a shoulder 16 at the base of the bore 14. The housing 4 has an outlet nozzle in the form of a mouthpiece 18 and a hollow interior part 20. Co-axially with the chamber 6 and below the level of the mouthpiece 18, is a short cylindrical part 22 descending vertically and having a bore 24.

A projection 26 enters the hollow part 20 and the bore 14 extends in the upper part of this projection. A feed tube 28 defining a feed chamber 29 is located in a bore 30 co-axially with the bore 14 in the projection 26 and extends upward, a short distance above the shoulder 16 at the base of the bore 14. An outlet orifice 32 connects the chamber 29 to the lower part 20 and to the mouthpiece 18 of the housing 4.

In the bore 24 of the housing is located a plug 34 having a skirt 36 and an upper part 42. Several holes 38 pass through the skirt around its periphery.

A low friction sealing disc 39 is fixed by gluing to the base of the projection 26 and a length of very fine rigid wire 40 goes up through the sealing disc and in frictional contact with it where it passes freely through the hollow supply tube 28. The wire also extends downwards and passes freely through a hole 41 in the upper part 42 of the piston 34. At the upper end of the wire is fixed a valve head 44 which, when the inhaler is not in use, rests in hermetic contact on the upper face of the supply tube 28 under the weight of the piston 34. Two discs 46 and 48 are fixed on the wire 40. A disc 46 is positioned around from the central point of the wire length, and the other disc 48 is positioned near the lower end of the wire and below the part 42 of the piston 34.

The box 10 can slide up and down in the compartment 6 and can therefore be moved manually by direct pressure of the finger on the end of the box or else a lever system or a screw device can be provided. In the example shown in Figure 1, a lever 50 is articulated around a pivot pin 52 fixed in a forked lug 54 on the housing, and a projection 56 can be pressed on top of the box 10 by manually tilting the lever.

In service, the patient pushes the box down into compartment 6, as just mentioned, which actuates the outlet valve in the box. This causes a controlled dose of medicament and propellant to pass through the metering chamber into the hollow chamber 13 defined in the outlet tube 12, above the supply tube 28, which is hermetically sealed at this time by the valve head 44. The sealing is carried out because the propellant in the chamber 13 is at a pressure essentially greater than atmospheric pressure and therefore pushes the valve head 44 against the end of the tube 28. It is understood that 1 the entire dose does not enter chamber 13 at this time. This is because the chamber 13 is in communication with the metering chamber by the aforementioned transfer nozzle so that the dose is maintained partially in the chamber 13 and partially in the metering chamber according to the relative dimensions thereof.

While continuing to hold the box in the lowered position, the patient places his mouth on the mouthpiece 18 of the housing, and inhales through the mouth. Maintaining the box in the lowered position has the effect of preventing the dose contained in the chamber 13 from escaping through the transfer nozzle. Inhalation by the patient causes a decrease in pressure in the hollow interior part 20 of the housing, which causes the piston 34 to rise to its position shown in dotted lines in FIG. 1, where its upper face comes into contact with the disc 46 by moving the wire 40 upwards, so as to disengage the valve head 44 which ceases to be in hermetic contact with the top of the supply tube 28. As the cross section of the piston 34 is very large by comparison with the surface of the valve head 44, a relatively small pressure difference on either side of the piston is sufficient to overcome a much larger opposite difference, on either side of the valve head. The controlled dose of medicament and propellant in the metering chamber of the dispenser outlet valve and in the chamber 13 passes through the supply tube 28 and through the outlet port 32, where it mixes with the air entering the hollow part 20 of the housing through the holes 38 in the walls of the raised piston 34. As a result, a controlled dose of drug is inhaled by the patient.

If desired, a means (not shown) can be provided to keep the box in the lowered position during inhalation without the patient having to continue to press the lever 50, by providing for example a helical screw with large pitch of 90 ° C.

In the embodiment described above, the weight of the piston is sufficient to bring the wire and the valve head to their lower position while being light enough to be lifted, under the effect of inhalation by the patient. The friction of the sealing disc 39 on the wire 40 is limited enough to offer very little resistance to the axial movement of the wire, but effective in causing the correct sealing of the lower end of the supply tube 28. It is advisable note that it is not necessary to provide a high degree of tightness between the sealing disc 39 and the wire 40, since the controlled dose is situated only in the region immediately above the sealing disc during from its passage to the outlet orifice 32.

Alternatively, a flexible diaphragm can be used, this being fixed for example by gluing around its peripheral edge, on the underside of the projection 26 and on the wire 40. Sufficient bending of the diaphragm must be obtained to allow the low elevation required to lift the valve head 44 from its seat on the supply tube.

If this proves to be necessary, a light compression spring 150 can be interposed as shown in FIG. 2a, between the sealing disc 39 and the disc 46, in order to push the valve head against its seat on the tube. food. This has the effect that the valve head always rests on the supply tube before the dispensers are actuated by the patient, which therefore eliminates the possibility that the first part of the dose entering the chamber 13 can not escape beyond the valve head, before the valve head has time to seal under pressure in the chamber 13. It also results therefrom that the dose cannot leave the chamber 13, simply by reversing the device after the dispenser has been activated. If there was not the spring, this could happen by the fall of the piston hitting the disc 46.

If desired, the piston 34 can be retained in the bore 24 by providing a trellis grid or the like on the open end of the bore. This is visible in Figure 2a where there is an end cap 152 with air holes 154. Alternatively, the underside of the cylindrical portion 22 may be provided with an annular flange facing inward which s extends below the walls 36 and the piston. In both cases, the piston 34 does not have to be fixed to the wire 40 and the lower part of the wire as well as the disc 48 can be eliminated. However, the aforementioned compression spring is necessary in this case to return the valve head 46 to its sealing position.

In another alternative device, the cylindrical part 22 is provided with holes around its periphery and the piston is inverted, that is to say that its part 42 is at the base, but it is also provided with holes 38 spaced around the inverted skirt.

The holes in the cylindrical part are effectively closed by the continuous part of the skirt 36, when the piston is in its lowest position. With this arrangement, inhalation by the patient causes the piston to rise and when the holes in the skirt are aligned with the holes in the cylindrical part 22, the air passes through the holes aligned in the mouthpiece. To ensure the alignment of the holes in the skirt with those in the cylindrical part, a suitable key device can be provided between the piston 34 and the bore 24. As a variant, the holes 38 can be interconnected by an annular groove made in the outer surface of the skirt.

In yet another alternative arrangement, shown in Figure 3, the intermediate chamber is filled with a controlled dose of medication which is discharged to the mouthpiece by means of a magnetically operated gate valve which is actuated by 1 ' inhalation of the patient.

As seen in Figure 3, the box 10 is located in a housing 104 and its outlet tube 12 extends in a bore 114 which is connected by a small diameter hole 116 to an intermediate chamber 120. The chamber 120 is connected to the mouthpiece 118 by an outlet element 119 having an outlet orifice 121 surrounded by a valve seat 122. A valve valve 124 is pushed against the valve seat 122 by a light spring 126. The valve valve 124 can slide into a bore 128 formed in the housing 104 and another bore 130 by a cavity 132 formed in a cylindrical part 134 of the housing towards the bore 128. The bores 128 and 130 are separated only by a very thin partition. In the bore 130 is a cylindrical part 138 of the piston unit which comprises a piston head 140 normally in contact with a seat 142 and thus retained by a light spring 144. The cavity 132 is connected to the mouthpiece by a passage 146.

The globe valve 124 and the cylindrical part 138 are designed so as to be able to attract one or the other magnetically. For this purpose, the cylindrical part 138 comprises an element 139 which is a magnet or is made of a magnetizable material and the globe valve comprises a magnet or, provided that the element 139 is a magnet, it is made of a material magnetizable.

In use, the box is pushed in as already described, in order to introduce into the intermediate chamber 120 a controlled dose of medicament and propellant. The patient then inhales through the mouthpiece 118 and this causes a pressure drop in the cavity 132. The pressure difference between the two sides of the piston head 140 is sufficient to overcome the action of the spring 144 and can cause a additional displacement of the cylindrical part 138 with its element 139 in the bore 130 until it comes into contact with the wall 136. The proximity of the element 139 has the effect of moving the valve 124 from its position sealant in contact with the valve seat 122 and the medicament mixes with the air flowing past the plunger head 140 and is inhaled by the patient.

Claims (11)

A dispenser actuatable by inhalation for use with a dispensing container for pressurized aerosol, and comprising: a receptacle for said container; means defining a storage chamber adapted to receive a controlled dose from the container and having an outlet; a valve having a closed position in which it closes in service the pressure outlet of the dose in the chamber and an open position, in which the outlet is open to allow the dose to leave the room and enter the outlet nozzle; an outlet nozzle through which a user can inhale and a release device which reacts to the inhalation of a user to move said valve to the open position. 2. Device according to claim 1, comprising means defining a bore for receiving an outlet tube from the pressurized aerosol dispensing container and said storage chamber being disposed at least partially in said outlet tube. 3. Device according to claim 1 or 2, wherein the device for releasing the dose comprises a piston, one side of which is subjected to pressure in the outlet nozzle and the other side of which is subjected to atmospheric pressure, the piston can move under the effect of inhalation between a rest position, to an open position of the valve. 4. Arrangement according to claim 3, in which the piston is provided with at least one orifice right through, this orifice being essentially closed when the piston is in its rest position and being open when the piston is in its valve open position. 5. Device according to any one of the preceding claims, in which said storage chamber communicates with the outlet nozzle by a supply chamber and an outlet orifice, the communication being controlled by said valve. 6. Device according to claim 5, in which the device for releasing the dose is connected to said valve by a control element which passes through said supply chamber. 7. Device according to claim 6, in which said feed chamber has an opening closed by a sealing disc and in which said control element passes in sliding contact through an opening in the sealing disc. 8. Device according to claim 6, in which said supply chamber has an opening closed by a flexible diaphragm and in which said control element passes through and is sealed to the diaphragm. 9. Device according to any one of claims 5 to 8, based on claim 2, in which one end of said supply chamber extends in the outlet tube and in which said valve comprises a valve element which, in the closed position of the valve, is pushed against said end of the supply chamber. 10. Device according to any one of claims 1 to 4, in which said valve and said device for releasing the dose are equipped with means which are designed to cooperate magnetically with one another, when the device for releasing the dose reacts to inhalation by the user, said cooperation having the effect that the valve moves to its open position. 11. Device according to any one of the preceding claims, comprising means for returning the device for releasing the dose to its initial position, after inhalation by the user.