WO1994028957A1

WO1994028957A1 - Powder inhaler with metering device

Info

Publication number: WO1994028957A1
Application number: PCT/EP1994/001038
Authority: WO
Inventors: Martin Herder; Wolfgang Göttenauer; André Narodylo; Joachim Goede
Original assignee: Asta Medica Aktiengesellschaft
Priority date: 1993-06-14
Filing date: 1994-04-02
Publication date: 1994-12-22
Also published as: TW238251B; IL109992A0; DE4319514C2; AU6564894A; ZA944203B; DE4319514A1

Abstract

Described is a powder inhaler for therapeutic use, in which the metering precision is improved by means of a compression pulse acting on the powder. Also described is a double-dose and low-dose inhalation control.

Description

POWDER INHALATOR WITH DOSING DEVICE

description

In inhalative asthma therapy, powder inhalers are being used more and more frequently as doser and inhaler devices, since the doser aerosols that were customary up to now can no longer be used because of the use of halogenated hydrocarbons as propellants for environmental reasons. Doser aerosols have the disadvantage that the patient must be able to coordinate the triggering of the spray and the inhalation. This is not always the case under the conditions of an acute asthma attack in which the patient is under severe stress. In the case of pulse inhalers, there is no need to coordinate inhalation and spray actuation since the patient's inhaled air carries the active ingredient.

In conventional powder inhalers (for example according to EP-A 406 893), each dose of the active ingredient is contained in a single hard gel capsule. The capsule is inserted into the device, stabbed through several thorns, and the released content is carried along by the patient's air flow and reaches the patient's lungs. A disadvantage of the powder inhalers with capsule filling is that, for better filling of the capsule and to maintain the dosage, an inert auxiliary, such as lactose, must be added. In some patients, inhalation of the inverted lactose powder may cause irritation to the airways. Furthermore, there is no guarantee that the pierced capsule will be emptied completely and that its contents will be available to the patient. There is also a risk that capsule fragments can be inhaled.

This invention relates to an inhaler for introducing an amount of solids dosed with a compression pulse into an air stream sucked in by a user according to the preamble of patent claim 1.

Solid-state inhalers are now available in large numbers and in many designs.

These inhalers are used to inhale primarily pharmaceutically active substances or mixtures, in particular powdery substances or mixtures, from a user.

For example, EP 518 087 describes a powder inhaler with a rotatably mounted metering disc, in which the specific shape of the Dos 1 Erkavl tat is intended to prevent the powder from accidentally falling out.

Another inhaler is known for example from EP 0 069 715 B1. The inhaler described in this patent comprises a storage chamber which opens into a chamber with elastic spring-loaded scrapers, where solid particles penetrate into it by rotating a perforated membrane and continues to cycle to the suction position. At this position, the solid particles are conveyed through the suction tube with the help of a suctioned air flow and with additional air sucked in from the side In the mouthpiece, dispersed through a helical channel and thus as 1 nhal 1 capable 1 total air-solid mixture was administered to the test person.

The inhaler described has various night spots. After increasing the number of doses, the metering holes in the membrane become blocked. In addition, solid agglomerates accumulate in the mouthpiece, which pose a risk to the test subjects of the increased amount of pharmaceuticals. By rotating the Dos 1 membrane several times without sucking off the powder, part of the powder is conveyed back into the storage chamber, but when using it, there may also be a risk of increased drug consumption for the test subject.

The wall formed as a baffle plate, which is another element for the disassembly of the powder, soiled by adhering powder. Improper breathing can cause moisture to enter the inhaler and cause the powder to clog.

It is therefore the object of the invention to design an inhaler for solids which reports the above mentioned night effects. This object is achieved by the invention as defined in the characterizing part of claim 1. The inhaler described here volumetrically doses a defined solid amount from a solid matter! rather (3) (F1g. 1). The vol umetr1 see dimension allele, without the use of a mechanical H11 fsenergl e, leads to inaccurate dosing.

In order to achieve a high dose 1, the solid found in the solid sperm is (3) a compaction pulse, which puts the solid in the Dos 1 Erkav 1 into a state of uniform density. In this compression pulse, the compression springs (4), which are pre-tensioned between the base body (5) and the upper part (1) with an integrated mouthpiece, make it difficult to pull the Dos 1! Boar (10) suddenly relaxes when the curve nose of the Dos 1 schel be (6) is pulled past the vertical edge of the underlying body of the course. The entire base body (5), in addition to solid matter spar (3) with embedded solid matter, air flap (12) with bearing pin (9), lower fitting piece (7), diaphragm valve 11 (13) with F1x1erst1ft (16) and Dos 1 experience (6), during the Aufschiagens an impulse, the solid in the Dos 1 be (6), which is located at the tent point below the solids storage (3). With this compression pulse, a high dose is achieved precisely.

By pushing in the Dos 1 slider (10) 1n towards the inhaler housing (11), the entire base body (5), together with integrated parts (3, 12, 9, 7, 13, 16), is again boiled with the help of the Dos1 (10) located slope on the curve nose of the Dos1 (6) on the vertical edge of the curve base body (15) lifted and positioned in a horizontal direction to the air duct and thus the still relaxed compression spring between the base body (5) and the upper part (1) (4), pressed together again (see F1g. 3 and F1g. 4).

The 1m air duct below the Dos 1 is (6) arranged membrane ent11 (13, 14, 16) prevents accidental blowing into the inhaler, the solids discharge from the air inlet opening 1m upper part (1) the inhaler. The entire metered amount of solids is thus available for the test subject to inhale.

In order to rule out multiple dosing, the air flap (12), which is arranged in the 1m air duct and which is mounted on the suction duct of the base body (5) with a bearing pin (9), must release the suction duct of the base body (5) through the suction pressure applied by the test subject. Only then is a new dosage possible for the next inhalation process. If a dose is triggered by sticking out and sticking in the Dos 1 boar (10) without a subsequent inhalation process, a new Dos 1 process is initiated by the hook-shaped connection of the air flap retractor (12) on both sides and the boar on the Dos1 ( 10) locked above the integrated spring (see F1g. 6). The risk of administration of an increased amount of pharmaceuticals is thus excluded.

Although this embodiment is described in connection with a mouthpiece, if an inhalation is not to take place orally, another outlet part can be used, for example a nosepiece.

F1g. 1 Left front view of the inhaler 1m section

F1g. 2 Top view of the inhaler 1m section B-B, marked in F1g. 1.

F1g. 3 Right front view of the inhaler with the dose of boar (10) cut in Tel 1

F1g. 4 Right front view of the inhaler with the Dosi inserted

F1g. 5 Top view of the inhaler without a lid

F1g. 6 Top view of the inhaler 1m section

F1g. 7 Rare view of the inhaler 1m section C-C, marked 1n F1g. 5

Claims

1. Inhaler for introducing one with one

Compressed-dose quantity of solids, in particular pharmaceutically active solids or mixtures of substances, preferably in powder form, in an air stream sucked in by a user, which after the introduction of the solids as a solid-air mixture enters the airways of the user characterized in that by the sudden relaxation of the spring elements preloaded between the base body (5) and the upper part (1) during the release of the doser slide (10), and that the cam nose of the dos 1 see (1) be (6) on a vertical edge of the underlying curve body ( 15) is pulled past by pulling the Doser erbers (10) and thus the entire body (5) together with solid matter rather (3) with embedded solid, air flap (12) with bearing pin (9), lower fitting (7), diaphragm valve 11 ( 13) with F1x1erst1ft (16) and Dos1 see1 e (6), whose Doslerloch is at this tent point below the solids storage (3) located, bounces on the base body of the curve, and that the solid is compressed in the cavity and, with high dos 1, the air channel of the base body (5) is conveyed precisely by inserting the doser slide (10) and is ready for the patient to inhale.

2. Inhaler according to claim 1, characterized in that the metering pulse rather by bumping against the solid matter, e.g. with the help of a sphere, if the cavity to be filled is closer to the tent point below the solids level.

3. Inhaler according to claims 1-2, characterized in that the metering pulse is realized by relaxing one or more tension spring elements.

4. Inhaler according to claims 1-2, characterized in that the metering pulse is realized by relaxing one or more compression spring elements.

5. Inhaler according to claims 1-4, characterized in that a metering pulse is also replaced by multiple smaller dos 1 er1 mpul se.

6. Inhaler according to claim 5, characterized in that the multiple small Dosi er1 mpul se are realized by one or more vibration elements.

7. Inhaler according to claims 1-6, characterized in that the multiple small

Dos 1 er 1 mpul se can be realized by a grid element.

8. Inhaler according to claims 1-7, characterized in that the protruding noses of the Dosi be (6) over the edges of the

Base body (15) are guided, thus also complete the vertical downward movement and thereby the height difference of the Dos 1 er1 mpul ses def1 n 1 ert.

9. Inhaler according to claims 1-8, characterized in that according to claim 5, the vertical edge of the curved base body (15) form the height difference together with the potential energy of the prestressed spring elements (4) the size of the Dos 1 he 1 mpul ses.

10. Inhaler according to claims 1-9, characterized in that according to claim 6, the energy of Dos 1 he 1 mpul ses is greater than 0.

11. Inhaler according to claims 1-10, characterized gekennzei chznet that a Mehrfachdosi tion through a 1m suction channel arranged air flap (12) is prevented in such a way that with the help of a be1dse1t1g hook-shaped connection of air flaps guide 1 (12) and on the metering slide (10) The integrated spring blocks a new dosage without inhalation and only opens the air flap (12) in the intake channel after inhaling due to the suction pressure applied by the test person, releases the hook cover and only then does the metering slide (10) for releases a new dosage.

12. Inhaler according to claims 1-11, characterized in that a membrane vent 11 (13, 14, 16) allows only suction and prevents blowing into the inhaler in order to reduce the solids discharge.

13. Inhaler according to claims 1 to 12, characterized in that an amount of a desiccant is in the solid matter rather (3).