SE518506C2 - Breath-operated device for use with an inhaler includes a return mechanism for deactivating a canister to close when airflow drops below a certain threshold value - Google Patents

Abstract

A breath-operated device having a return mechanism for deactivating a canister to close when an airflow drops below a certain threshold value, is new. A breath-operated device having a return mechanism for deactivating a canister to close when an airflow drops below a certain threshold value, is new. The device is used with an inhaler and comprises an actuator mechanism for activating a canister to open and dispense a medicament in response to an airflow in the inhaler caused by user inhalation through an opening, and a return mechanism for deactivating the canister to close. The return mechanism comprises a flap, cylindrical shuttle, second arm, rotatable holders, and a fork-like member deactivates the canister when the airflow drops below a certain threshold value. The actuator mechanism comprises pressure plate (34), cylindrical body (36), flap, first arm (44), cylindrical shuttle, rotatable holders, and fork-like member. The inhaler comprises a body containing medicament, an aerosol canister arranged in the body, a nozzle fluidly connected with the canister, and an opening for dispensing the medicament which is also fluidly connected with the nozzle. The body includes a metered dose chamber, and dispenses a metered dose of the medicament. An Independent claim is also included for a medical distributor for distributing medicament to a patient, comprising breath-operated devices arranged in sequence with one another.

Description

25 30 n. o n now 518 506 2 amount of powder to be inhaled or a dose to be delivered. Other types of inhalers, such as nebulizers, may also have respiratory actuators for activating the delivery of a dose, or quantity of drug.

Some of the respiratory actuated devices include some form of disc-like lid, flap or wing movably disposed in an airway in the inhaler or adjacent an air intake. When inhaled, the pressure drop and / or air causes the plate to move and thereby activates the actuator so that a dose is delivered.

Some breath-activated inhalers are also provided with return means. These return means "restore" the actuator to a clear state so that the inhaler is ready for use in the subsequent inhalation. The return means also recharges the inhaler, for example refills a dose measuring chamber with medication for subsequent use. The return means is operated either manually, for example when a protective cap is opened or closed, or automatically, either at a specific time after inhalation or when inhalation ceases.

A disadvantage of the devices described above is that breath-activated devices can be inadvertently fired when the inhaler is ready for inhalation if the inhaler is dropped or otherwise exposed to sudden forces. As the plates, wings or flaps should be able to move by rather small forces exerted by the pressure drop / air during the inhalation, they can also be quite easily replaced by a sudden movement or a sudden change of movement of the inhaler, such as if the inhaler is shaken or hits a object when ready for inhalation. 10 15 20 25 30 ø. n | .n 518 506 ~ 3 .u .of A number of doses important to the patient can be lost in this way. Furthermore, for many types of inhalers, the doses will be delivered inside the inhaler if they are fired accidentally. The drug delivered inside the inhaler may be deposited on passageways or mechanisms of the inhaler and possibly interfere with function or contaminate the inhaler.

The deposition can also affect the dose-to-dose equivalence in that a smaller amount of drug is inhaled than intended and in that the deposited drug can be broken off during inhalation, the amount being greater than intended.

In connection with inhalers with automatic refilling means, an unintentional firing of the inhaler can also lead to an incorrect filling of the dose measuring chamber if, for example, the inhaler is kept in such a position during refilling that the medicament cannot fill the chamber properly. This may be the case, for example, with aerosol-powered canisters which must be kept in a substantially vertical position when the dose measuring chamber is refilled, especially when the canister is not full. The incorrect filling of the dose measuring chamber leads to an incorrect dose being delivered to the patient during the subsequent inhalation.

BRIEF DESCRIPTION OF THE INVENTION It is an object of the present invention to remedy the above-mentioned problems and to provide a device for the above-mentioned type of inhalers which reduces the risk of accidental firing of the inhaler.

This object is achieved according to an aspect of the invention characterized in that the moving means comprises at least one rotatably arranged device, the device or devices being balanced so around its pivot point that forces acting on the device (s) during sudden changes in the movement of the inhaler does not affect the device (s) so that a dose is delivered.

According to a further aspect of the invention, it is characterized in that the movement means comprises a balancing means arranged so as to the device (-n) that the forces acting on the device (-n) during sudden movements of the inhaler are balanced out by the balancing means.

According to a further aspect of the invention, it is characterized in that the torque of the balancing means is substantially the same as the torque of the device (-n).

With a device according to the invention, the movement means, such as for instance a plate or flap, or a device of the movement means, such as a rotatably arranged borrowed cake, or combinations of rotatably arranged devices, are kept substantially stationary when the inhaler is subjected to sudden movements, but is activated, or moved during inhalation.

This prevents inadvertent activation of the inhaler due to forces acting on, and attempting to rotate, a device of the moving member.

Preferably, the device of the moving member is balanced with respect to forces acting on the inhaler so that the torque point of the device is arranged at or near its axis of rotation. This prevents the device from rotating due to acceleration or deceleration. With a device according to the invention, external forces on the inhaler will not fire the breath-activated device as easily as with known inhalers of this type when the inhaler is in a ready position.

In one embodiment, when the device of the movement means is designed as a rotatable plate-like flap, a balancing means having a torque which is substantially equal to the torque of the flap is arranged 518 506m. 5 on the opposite side of the pivot point. The balancing means thus balances the flap so that it is kept stationary when the inhaler is exposed to external forces in a very simple but still effective manner.

These and other aspects and advantages of the invention will be apparent from the detailed description of an embodiment and from the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS In the detailed description of the invention, reference will be made to the accompanying drawings, in which Fig. 1 shows the present invention, showing a cross-sectional side view of an inhaler comprising Fig. 2 breath activated component according to the invention shown in detail , partially cut away, by a shaft and included in the inhaler according to Fig. 1, Fig. 3 shows the component according to Fig. 2 from the side, Fig. 4 an inhaler, balanced in a shaft, shows a detailed view in perspective of a flap included in Fig. 5 shows a top view of the flap according to Fig. 4, Fig. 6 shows a side view of the flap according to Fig. 4, Fig. 7 shows a detail view of a still another use of the present invention, and u ø f: nn 518 506 6 Fig. 8 the present invention. shows a detailed view of a further use of DETAILED DESCRIPTION OF THE INVENTION Figure 1 shows an example of an inhaler embodying the present invention. The inhaler 100 shown is for aerosol powered drugs contained in a canister 102 disposed within the housing 104 of the inhaler. A valve tube 102 of the canister is inserted into a nozzle 108 provided with an outlet directed towards an inhalation mouth 110. Pressure means 112 are arranged in contact with the top of the canister as shown in the figure. The pressure means comprises a piston 114 and a pressure plate 116. Compression springs 119 are arranged between the pressure plate and the housing. Actuators 120 are provided adjacent the pressure plate to hold it in a position when the compression springs are tensioned. The actuator further comprises levers and shuttles.

Fig. 2 shows a detail of a component 10 of a breath-activated inhaler. The component comprises an air intake passage 12, through which air flows upon inhalation. In the air intake, a flap or wing 14 is arranged rotatably about an axis of rotation 16. Spring means (not shown) force the flap upwards in Fig. 2 against the inner wall of the air intake. In this position, the flap or wing mainly blocks the air intake passage. The part of the wing that is on the opposite side of the axis of rotation is connected to the actuator.

The general function of the component is that during inhalation, a pressure difference is created between the interior and exterior of the inhaler housing 104. This pressure difference causes the flap or wing 14 to rotate about the axis of rotation 16 towards its spring means so that the air intake opens and an air gap is created. The rotational movement of the flap or wing triggers the actuator so that the holding of the pressure plate 116 is released, whereby the springs 118 push down the canister 102. In turn, the valve tube 106 is pushed into the canister, whereby a dose of medicament is delivered through the mouth part. 110.

The flap or wing is arranged with balancing means 18. In the embodiment shown in Figs. 1 and 2, this comprises a weight arranged on the opposite side of the axis of rotation in relation to the flap or wing. The center of gravity 20 is arranged in the same plane as the center of gravity 22 of the flap or wing and the pivot point. The weight of the balancing means is selected so that the weight times the distance to the pivot point is equal to the weight of the flap or the wing times the distance between its center of gravity and the pivot point. With this arrangement, the flap or wing is balanced with respect to external forces exerted on the inhaler in that the resulting torque on both sides of the pivot point is the same. Since the centers of gravity are located on the same plane as the pivot point, the flap or wing will be balanced for external forces in all directions.

Fig. 3-5 Shows an embodiment where the flap or wing 14 is not balanced in all directions. Here, the weight 18 is placed slightly below the pivot point and the flap or wing. Here, the center of gravity 22 of the flap or wing and the balancing member 20 and the pivot point 16 will not be arranged in the same plane. Here, the flap or wing will be substantially balanced along line 26 which intersects the pivot point and the resulting center of gravity.

This configuration may be due to the limited space available in the inhaler. Thus, the resulting center of gravity 24 will not coincide with the pivot point of the flap or the wing 26 but with the line 26. However, it is arranged so that the flap or wing is balanced for forces exerted on the inhaler. in selected directions. For example, with an aerosol inhaler, it is recommended that it be shaken before use so that the drug inside the canister is properly suspended. Depending on the design of the inhaler, ie how it is held, it is shaken in different directions. The inhaler shown in Fig. 1 will be shaken in a substantially vertical direction as shown by the arrow 130. The flap or wing is then substantially balanced with respect to these directions.

Fig. 7 shows another use of the present invention. For many inhalers, it is important that the inhalation forces be kept low, which makes it necessary to have the controls responsive to these low forces. On the other hand, the depressing forces need to be relatively high to be able to overcome the forces required to depress the canister. Therefore, it is necessary to have some form of transmission mechanism that amplifies the movement from the flap or the wing to the compression springs. Fig. 7 shows an example of how a first link in the transmission comprises a lever 150 rotatably arranged.

The lever is connected to the flap or wing 14 via a rod 152. A second arm 154 or lever is connected to the lever via a lug 156. The transmission further includes arms, levers, rods, shuttles and the like for transmitting and transmitting the movement to a holding member 160. which holds the pressure plate 116 against the force of the compression springs 118. When a patient inhales, the flap 14 rotates about its axis of rotation, pushing the rod 152 downward. The rod rotates the lever 150, the arm 154 releasing the contact with the lug.

The movement is transmitted through the transmission until the holding member 10 releases the pressure plate. When very small forces are required, and desired, to turn the lever, this is balanced against external forces according to the invention. A weight 162 is arranged on the opposite side of the pivot point and selected so that the resulting center of gravity of the weight of the rake arm coincides with the pivot point 164, the lever being balanced against directional forces, for example vertical as seen in Fig. 7.

Fig. 8 shows a detailed view of a locking and disengaging means for a breath-activated inhaler. This includes a first rotating device 212 rotatable about an axis. The first device is arranged with a surface 214 inclined with respect to a vertical axis as seen in Fig. 2. The lower end of an arm 200 arranged for a breath-activated device, not shown, is arranged with a corresponding inclined surface 216. The first the device is arranged with an upwardly directed lug 218, on which lug the other device is in a substantially horizontal position. A third device 222, arranged slidably in a vertical direction, rests with a lower end on the second device. The third device is attached to a holding device, which, for example, holds compression springs arranged on a canister of an inhaler in a charged, tensioned position. As soon as the arm 200 moves downwards, the subsequent devices being taken out of contact with each other, the canister is depressed by the spring forces. In order to prevent the inhaler from being activated by sudden forces, the first device 212 is balanced so that its center of gravity is located in the pivot point of the device. Although the present invention has been described in connection with an aerosol inhaler, it should be understood that it is equally applicable to other types of inhalers such as powders and nebulizers as well as to nasal inhalers operating according to the same principles. It is to be understood that the present invention can be used to balance static as well as dynamic forces, i.e. predetermined directions of motion, non-predetermined directions of motion as well as motions in plan your planes. Although the invention has been described in connection with a balancing means arranged for the flap and the lever of the transmission mechanism, it should be understood that the principles according to the invention can be applied to other components of an inhaler which are rotatably arranged.

In this context, it is to be understood that the word "rotatable" may be a ballast balancing on an edge, or that the shaft on which a rotating ballast is arranged is smaller than the hole, so that there is a specific point of contact, pivot point, between the shaft and the hole.

Claims (3)

10 15 20 25 51 8 5 06 - - / I PATENTKRAV An inhaler device (10), said inhaler comprising an inhalation opening, a container containing medicament, an actuator capable of delivering a dose of medicament from the container, a moving means (14) connected to the actuator and arranged in the inhaler so that it moves when inhaled through the inhalation opening, characterized in that the movement means comprises at least one rotatably arranged device (14), this at least one device being balanced so around its pivot point (16) that forces acting on it at least one device during movement of the inhaler, which causes acceleration / deceleration, this does not affect at least one device. 2.. Device according to claim 1, characterized in that the moving means comprises a balancing means (18) arranged so as to have at least one device that forces acting on the at least one device during said movement of the inhaler are balanced out by the balancing means. Device according to claim 2, characterized in that the torque of the balancing means is substantially the same as the torque of the at least one device.