TECHNICAL FIELD OF THE INVENTION
The present invention relates to an inhalation device for oral or nasal delivery of medicament in powdered form, more specifically to a unit dose inhaler which is formed as a blister that contains a dose of medicament for inhalation.
BACKGROUND TO THE INVENTION
Dry powder formulations for inhalation are commonly pre-packaged in individual doses, usually in the form of capsules or blisters. A blister is typically cold-formed from a ductile foil laminate and has a puncturable or peelable lid. The lid is usually heat-sealed around the periphery of the blister after the dose of powder has been placed into the blister. Multi-dose inhalers, such as those disclosed in WO 2005/037353, contain a blister strip with number of doses to be used over a period of time, so that there is no need to insert a blister into the device each time it is used. There are also unit-dose devices that receive only one blister at a time, for example as disclosed in WO 2010/086285. Once the dose contained in a blister has been inhaled, the blister is removed from the device and discarded by the user. A new blister is then inserted for a subsequent dose.
Single dose, disposable, blister-like dispensers are also known. WO 2014/175815 discloses an inhaler with a body comprising an air channel that contains a powder and a foil with inlet and outlet holes that are closed by a removable tape. The air outlet is simply a hole in the lid, which is not very convenient for the user to inhale on. WO 2003/103563 discloses a unit dose powder inhaler with a lower wall formed from a sheet element and a peel-off piece of lidding material, such as foil. The lower wall has a recess that contains the medicament and a channel. To use the inhaler, the user breaks off a corner piece along a fracture line, which opens an air outlet at the end of the channel. An air inlet is formed by peeling off a portion of the lidding material. Alternatively, the lower wall has a further channel extending from the recess to the opposite corner, and the air inlet hole is formed by breaking off this corner. The user then inhales on the air outlet, which aerosolizes the powder. However, in this inhaler, some of the powder could transfer into the corner piece before use, and hence be lost when it is broken off, so that the full dose is not delivered to the user.
US2017/0119982 discloses an inhaler in which the body of the inhaler is held in a blister. The lid of the blister is connected to a seal which is located between a dose chamber and the airway formed in the body of the inhaler. The seal ensures that the powder is not transferred out of the dose chamber into the body or the blister (from which it might not be aerosolized), e.g. during transport or storage. When the lid is removed, the seal is pulled away so that the dose chamber is opened and the inhaler is thereby prepared for use. However, to achieve this, the inhaler is constructed from five separate parts: the base and lid of the blister, the body, the removable seal and the dose chamber.
US 2013/0291865 discloses a disposable unit dose inhaler with a housing having a lid, a dose chamber which contains the powder for inhalation and a dedicated mouthpiece (e.g. a tube) which is movable (rotatable or slidable) relative to the housing. When the user moves the mouthpiece relative to the housing, an opening is created and the dose chamber is opened, so that the mouthpiece is exposed for the user to inhale on, thereby causing the powder to be aerosolized. The dose chamber ensures that the powder is not transferred to another part of the housing (from which it might not be aerosolized), e.g. during transport or storage. Since the powder is held in the dose chamber, a consistent and predictable dose is delivered. However, the device is relatively complex to produce. Firstly the mouthpiece must be securely attached to the housing (so that it cannot come loose and be lost or even swallowed) in a way that permits the rotational or sliding movement. Secondly the dose chamber must be sealed before use, and then opened by the movement of the mouthpiece. In one embodiment, the mouthpiece is attached to the housing by a living hinge and a foil barrier forms the dose chamber which is pierced when the mouthpiece is moved. In another embodiment, the mouthpiece is mounted on a separate base. These co-operate to form the dose chamber, which is opened when the mouthpiece is rotated relative to the base. These require additional components (such as the barrier foil and the base) and additional process steps to manufacture the inhaler, which increases the costs and complexity.
Thus there remains a need for a unit dose inhaler that addresses these drawbacks, and which is simple and cost-effective to manufacture.
BRIEF DESCRIPTION OF THE INVENTION
The present invention provides a very simple, low cost a unit-dose dry powder inhaler which is easy to use and inexpensive to produce, because its manufacture is based on the conventional blister strip production process. Accordingly, in a first aspect, the present invention provides a unit dose dispenser in the form of a blister containing a dry powder for inhalation, wherein the dispenser comprises:
- a base in which a cavity is formed, wherein the cavity comprises a bowl that contains the powder and a channel that opens into the bowl, and has an end remote from the bowl;
- a lid, such as a foil or foil laminate, which is sealed to the base around the cavity;
- an airway located in the channel, the airway comprising a mouthpiece and a body portion having at least one air outlet passage, at least one air inlet passage, a lower surface, and an upper surface, wherein:
- each air outlet passage opens into the bowl at a proximal end and extends from the body portion through the mouthpiece to an air outlet at a distal end;
- each air inlet passage opens into the bowl at a proximal end and has an air inlet at a distal end;
- the air inlet(s) and the air outlet(s) abut, and are closed by, the base and/or the lid;
- the lower surface of the body portion matches the shape of the channel so that it forms an interference fit with the channel;
- the upper surface of the body portion is flat and level with the base around the cavity, and the lid is preferably sealed to part of the upper surface;
- wherein part of the base and the lid of the dispenser is detachable, so that the air inlet(s) and the air outlet(s) are opened when the detachable part is removed, while the airway is retained in the channel.
The fact that the air inlet(s) and the air outlet(s) abut, and are closed by, the base and/or the lid ensures that the whole dose is retained within the airway. Since powder cannot leave the airway, little or no powder is lost when the detachable part is removed, so the whole dose is inhaled. Consequently, in contrast to the devices of US2017/0119982 and US 2013/0291865, there is no need for a separate way of sealing the powder compartment, so that additional components and process steps for securing the airway to the housing and for forming a closed dose chamber are not required.
The body portion of the airway and the channel may be semi-circular in cross-section.
The air outlet(s) may match the shape of the end of the channel so that the air outlet(s) abut, and are closed by, the end of the channel. For example, the air outlet may be curved to match the shape of the end of the channel. The air outlet(s) may be formed in the upper surface of the mouthpiece so that they abut, and are closed by, the lid.
The airway may comprise a barrier located between the air inlet(s) and the air outlet(s), wherein the size and shape of the barrier corresponds to the cross-section of the channel. The barrier may be a wall, or it may be extended to form a block. The block may be solid, or it may be hollow, apart from the wall. The lid is preferably not sealed to the upper surface of the block.
The lower surface of the body portion may extend continuously to the barrier so that the air inlets are formed in the upper surface of the airway between the upper surface of the body portion and the barrier so that they abut, and are closed by the lid.
The air inlet and/or air outlet passages may have baffles or corners or be formed as a labyrinth.
The airway may have one air outlet passage. The air outlet passage may have an extension that protrudes into the bowl. The end of the extension may be located at, or close to, the centre of the bowl. The extension may taper so that the end is narrow.
The airway may have one air outlet passage and one air inlet passage, so that the air flow is asymmetric and creates a cyclone in the bowl.
The airway may have one air outlet passage and two air inlet passages. The air inlet passages may be on either side of the air outlet passage. The air inlet passages may have extensions that protrude into the bowl.
The dispenser may have a line of weakness, such as perforations, in the base and/or the lid. The dispenser may have a notch in one or both edges of the base and/or the lid. The line of weakness and the notches may facilitate removal of the detachable part.
A pair of dispensers may be joined together so that the powders in both dispensers can be inhaled simultaneously. A plurality of dispensers may be joined together in the form of a strip which provides a multi-day supply of powder, wherein each dispenser is detachable from the rest of the strip.
In a second aspect, the invention provides a process for producing unit dose dispensers, in particular dispensers according to the first aspect of the invention, the process comprising:
- a) forming cavities in a base material, each cavity comprising a bowl, and a channel that opens into the bowl and has an end remote from the bowl;
- b) simultaneously or in either order, filling the powder into the bowls and placing an airway into the channel, the airway comprising a mouthpiece and a body portion having at least one air outlet passage, at least one air inlet passage, a lower surface, and an upper surface, wherein:
- each air outlet passage opens into the bowl at a proximal end and extends from the body portion through the mouthpiece to an air outlet at a distal end; and
- each air inlet passage opens into the bowl at a proximal end and has an air inlet at a distal end;
- the lower surface of the body portion matches the shape of the channel so that it forms an interference fit with the channel; and
- the upper surface of the body portion is flat and level with the base around the cavity;
- c) sealing a lid material to the base and preferably to part of the upper surface of the body portion so as to seal the cavities; and
- d) simultaneously or in either order, forming a detachable part of the base and lid materials, and cutting the base and lid materials to form individual dispensers, or pairs of dispensers, or strips with a plurality of dispensers;
wherein the air inlet(s) and the air outlet(s) abut, and are closed by the base material and/or the lid material in such a way that they are opened when the detachable part is removed.
The process is adapted from the standard process for producing blister strips for dry powder inhalers. It can be implemented with mainly conventional materials and existing production equipment. It therefore provides a straightforward and inexpensive way of manufacturing simple unit dose dispensers.
BRIEF DESCRIPTION OF THE FIGURES
FIG. 1 shows a conventional process for producing blister strips for dry powder inhalers.
FIG. 2 shows the process for producing an inhaler according to the invention.
FIG. 3A shows a dispenser produced by the process of FIG. 2. FIG. 3B is an expanded view of the components of the dispenser. FIG. 3C shows the airway its own. FIG. 3D is a transverse cross-section through the body portion of the airway. FIG. 3E is a longitudinal cross-section through the end of the mouthpiece. FIGS. 3F and 3G are isometric views which show the dispenser after the detachable part has been torn off. FIG. 3H illustrates the air flow through the dispenser during inhalation.
FIGS. 4A-4D show a further embodiment a dispenser. FIGS. 4A and 4B show the airway its own. FIGS. 4C and 4D show the dispenser after the detachable part has been torn off.
FIGS. 5A and 5B show a variant of the dispenser of FIG. 4, after the detachable part has been torn off.
FIG. 6A illustrates the air flow during inhalation for a further embodiment. FIGS. 6B and 6C are cross-sectional views along A-A and B-B of FIG. 6A respectively.
FIG. 7 shows yet another embodiment, with baffles in the air outlet passage.
FIGS. 8A and 8B show an embodiment in which the airway creates a cyclone in the bowl.
FIG. 9A shows a pair of dispensers for simultaneous inhalation. FIG. 9B is a cutaway side view when the dispensers are folded so as to lie one on top of the other.
FIGS. 10A and 10B show strips of six dispensers.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 illustrates the conventional process for producing blister strips for dry powder inhalers. The production line has a forming tool 1, two filling heads 2, 3 and a sealing tool 4. A sheet of base material 10 passes along the production line from left to right. A roll 5 of lid material 11 is located between the second filling head 3 and the sealing tool 4.
The base material is typically a laminate comprising a polymer layer in contact with the drug, a soft tempered aluminium foil layer and an external polymer layer, as described for example in WO 2006/108876. The aluminium provides a barrier to ingress of moisture, oxygen and light, whilst the polymer aids the adherence of the foil and provides a relatively inert layer in contact with the drug. Suitable materials for the polymer layer in contact with the drug include polyvinylchloride (PVC), polypropylene (PP) and polyethylene (PE). The polymer layer in contact with the drug is typically PVC of 30 μm thickness. However, a thicker or thinner layer of e.g. 60 μm or 15 μm may be used where a stiffer or more flexible laminate is required. Soft tempered aluminium is ductile so that it can be cold-formed into a blister shape. It is typically 45 μm thick. The external polymer layer provides additional strength and toughness to the laminate, and is typically made from oriented polyamide (OPA), typically 25 μm thick.
The lid material is typically a foil or a foil laminate preferably comprising a heat seal lacquer, a hard rolled aluminium layer and a top layer of primer, as described for example in WO 2006/108876. The heat seal lacquer bonds to the drug-contacting polymer layer of the base laminate during sealing to provide a seal around the top of the cavity. If the polymer layer in contact with the drug in the base material is PE, the heat seal lacquer on the lid material may be replaced with a further layer of PE. On heat-sealing, the two layers of PE melt and weld to each other. The aluminium layer is typically hard rolled and 20-30 μm thick. The primer facilitates printing onto the strip, for example dose numbers.
The sheet of base material 10 first passes through the forming tool where it is cold formed to create rows of blister cavities 12 by moving the upper part 1a of the forming tool 1 downwards so that the base material is pressed between the upper 1a and the lower 1b parts. Then the formed base sheet passes under the filling heads 2, 3. Each filling head dispenses measured amounts of powder into a row of cavities. The two filling heads are spaced apart by an odd number of blister pitches (i.e. the distance between the centres of adjacent blister cavities in the longitudinal direction of the base sheet), and the base sheet is advanced by two blister pitches in each step. Thus the first filling head fills odd numbered rows 13 and the second filling head fills even numbered rows 14 of blister cavities. In practice, there may be a larger number of filling heads, for example six, in which case the base sheet advances by six blister pitches in each step. Next, the lid material 11 is dispensed from the roll 5 on top of the base sheet and the sealing tool 4 heats and compresses the base and lid material together in a region surrounding each cavity to form a heat-seal. Knives (not shown) cut the formed, filled and sealed blister sheet longitudinally into blister strips 18 as it advances, and also transversely to the required length.
FIG. 2 illustrates the process of the invention. The cavities are formed in the base sheet 10 in the same manner as the conventional process, but are shaped differently. As well as a bowl 21 into which the powder 20 is dispensed, the cavities also have a channel 22, one end of which opens into the bowl. An airway 23 is placed into the channel 22 from a magazine. Although FIG. 2 shows the airway 23 being placed into the channel 22 after the powder 20 has been filled into the bowl 21, these steps may occur simultaneously, or in either order. Placing the airway 23 into the channel 22 before the powder 20 is filled into the bowl 21 has the advantage that this avoids any possibility of powder being trapped underneath the airway. Then the cavities are sealed with lid material 11 in the same manner as the conventional process. The lid material may also bond to part of the upper surface of the airway. Finally, the sheet is cut into individual dispensers, or strips of dispensers. The dispensers may be cut out to form a desired shape, for example with a tab 27, as shown in FIG. 3A. A line of weakness 28 between the tab 27 and the remainder of the dispenser may be formed in this step to facilitate removal of the detachable part 26 (which comprises both the base and lid materials). The line of weakness is typically provided by perforations or scores in the lid and/or base material, and/or a notch in one or both edges. The position of the line of weakness may be indicated by a printed line on the on the lid material. Similarly, a line of weakness may be provided between each dispenser in a strip (as shown in FIG. 10), so that individual dispensers can be detached as needed.
Since the process is based on and adapted from the standard process for producing blister strips for dry powder inhalers, it can be implemented using mainly conventional materials and existing production equipment. It therefore provides a simple and inexpensive way of manufacturing unit dose dispensers.
FIG. 3A shows the blister produced by the process of FIG. 2, after it has been cut out from the sheet to form an individual dispenser. The blister has a main part 24 comprising the bowl 21 and a neck 25, and a detachable part 26 comprising the tab 27. Between the main part 24 and the detachable part 26 there is a line of perforations 28 in the lid and a corresponding line of perforations 29 in the base.
FIG. 3B is an expanded view of the components of the dispenser, namely the base 10, the powder 20 located in the bowl 21, the airway 23 which fits in the channel 22, and the lid 11. The channel 22 extends from the bowl 21 along the neck 25 and into the detachable part 26.
FIG. 3C shows the airway 23 which has a body portion 23a. FIG. 3D is a transverse cross-section through the body portion 23a, which has three passages: a central air outlet passage 30 and two air inlet passages 31, 32, one on either side. At one end (the proximal end, on the left side in FIG. 3C), the air outlet passage 30 and the air inlet passages 31, 32 open into the bowl 21. The air inlet passages 31, 32 have extensions 31b, 32b which protrude further into the bowl than the central air outlet passage 30. At the other end, the air outlet passage is a tube which protrudes beyond the ends of the air inlet passages to form the mouthpiece 33. The distal end of the air outlet passage, which is shown in longitudinal cross-section in FIG. 3E, has an air outlet 30a. The air inlets 31a, 32a are formed by the distal ends of the air inlet passages 31, 32 remote from the bowl 21.
As shown in FIG. 3D, the body portion 23a of the airway 23 has a generally semi-circular cross-section, with a flat upper surface 34a. The semi-circular lower surface 34b corresponds in size and shape to the channel 22 so that it is held in the channel by an interference fit. When the airway is located in the channel, the flat upper surface 34a is level with the base around the cavity (i.e. with the top of the channel). This has the advantage that the lid material of the main part 24 can be sealed to the flat upper surface of the body portion of the airway, as well to the region of the base that surrounds the cavity. This ensures that the airway 23 is held securely in place in the dispenser. The lid material in the detachable part 26 however is not sealed to the upper flat surface of the airway, in order that the detachable part can be detached easily. The airway may accordingly have a heat seal lacquer on the flat upper surface 34a or be made from PE to facilitate formation of a heat seal with the lid, in the same manner as described above for the base material.
Since the lid material is sealed to the upper flat surface 34a of the airway 23, and the lower semi-circular surface 34b of the airway 23 forms an interference fit with the channel 22, the bowl forms a closed powder chamber, apart from the air inlet passages 31, 32 and the air outlet passage 30. Powder could be transferred from the bowl 21 into the air inlet and air outlet passages, and hence into the detachable part between manufacture and use, for example during transport or storage. Any powder that remains within the air inlet and outlet sections of the airway will be aerosolized when the user inhales. However, any powder that enters the detachable part would be lost when it is removed, in which case the full dose would not be delivered.
In order to prevent transfer of powder into the detachable part, a barrier is located a small distance in front of the air inlets 31a, 32a. The barrier is in the form of a semi-circular wall 35 which forms an interference fit with the channel. Consequently, any powder that is in the air inlet passages 31,32 can leave through the air inlets 31a, 32a, but cannot get past the wall 35 and so is not able to enter the detachable part 26. Also, as shown in FIG. 3E, the air outlet 30a is curved so that it matches the shape of the end of the channel 22a. Since the curved air outlet 30a abuts the end of the channel 22a, any powder that is in the air outlet passage 30 cannot exit through the air outlet 30a. Together with the wall 35, this ensures that essentially the whole dose is retained within the bowl 21 and the airway 23. Only powder that is stuck to the parts of the lid adjacent to the air inlets or to the part of the channel that abuts the air outlet could be transferred to the detachable part. The materials from which the lid and base are made are chosen to minimize powder adhesion. As a result, little or no powder is lost when the detachable part is removed, and essentially the whole dose is inhaled. Consequently, in contrast to the devices of US 2017/0119982 and US 2013/0291865, there is no need for a separate way of sealing the powder compartment.
To prepare the dispenser for delivering a dose of medication, the user pulls the tab 27 along the lines of perforations 28, 29 to remove the detachable part 26. FIGS. 3F and 3G are isometric views which show the upper and lower sides of the dispenser respectively, after the detachable part 26 has been torn off in order to expose the air inlets 31a, 32a and the air outlet 30a. Since the channel 22 and airway 23 extend into the detachable part 26 when it is present, the air inlet passages 31, 32 and the air outlet passage 30 protrude out of the main part 24 which remains after the detachable part 26 has been removed. This ensures that any loose parts of the torn lid material cannot block the air inlets.
Once the detachable part has been removed, the dispenser is ready to use. The user inhales on the mouthpiece 33. Since the mouthpiece 33 extends beyond the air inlets 31a, 32a and the wall 35, there is no danger of the user's lips blocking the air inlets. FIG. 3H illustrates the air flow during inhalation. Air flows into the air inlets 31a, 32a, through the air inlet passages 31, 32 and enters the bowl 21. The extensions 31b, 32b of the air inlet passages 31, 32 which protrude further into the bowl than the air outlet passage 30 ensure that the air flows through the centre of the bowl and aerosolizes the powder 20. The aerosolized powder then flows into the air outlet passage 30, along the mouthpiece 33, through the air outlet 30a and into the user's lungs.
FIGS. 4A and 4B show an alternative embodiment of the airway 23 in which the barrier is in the form of a block 41 with a semi-circular cross-section which matches the size and shape of the channel. The block 41 is shown in FIG. 4B as being a hollow extension from a wall (as in FIG. 3), but it could alternatively be solid. Having a hollow or solid block 41 instead of the wall has the advantage that it is even less likely that powder could get past the barrier and into the detachable part. This is because there is close contact between the flat upper surface 42 of the block 41 and the lid, and between the semi-circular lower surface 43 of the block 41 and the channel, over a longer distance. The lid is not sealed to the upper flat surface 42 of the block 41 since doing so would make it difficult to remove the detachable part. FIGS. 4C and 4D are isometric views which show the upper and lower sides of the dispenser after the detachable part has been torn off so that the air inlets 31a, 32a and the air outlet 30a have been exposed. As with the embodiment of FIG. 3, the perforations are spaced apart from, and closer to the bowl than, the air inlets 31a, 32a so that any loose parts of the torn lid material cannot block the air inlets.
FIGS. 5A & 5B show a variant of the embodiment of FIG. 4, in which the lower surface 34b of the body portion of the airway extends continuously to the block 41. Consequently, the air inlets 31a, 32a are formed only by the gap between the upper flat surface 34a of the body portion and the upper surface 42 of the block 41. The air outlet 30a is formed in the upper surface of the mouthpiece 33 instead of the curved end. Thus both the air outlet 30a and the air inlets 31a, 32a abut, and are closed by, the lid. The lid prevents powder from leaving the airway and entering the detachable part, thereby ensuring that the full dose is delivered when the used inhales.
FIGS. 6A, 6B & 6C show a further embodiment. FIG. 6A is a view from above of a dispenser after the detachable part has been removed, but with the lid not shown so that the airway and powder are visible. FIGS. 6B and 6C are cross-sectional views along A-A and B-B of FIG. 6A respectively. The air outlet passage 30 has an extension 30b that tapers as it protrudes into the bowl 21, so that the narrow end 30c of the extension is close to the centre of the bowl. Since the area of the air outlet passage at the point where the powder could enter it is smaller, powder transfer from the bowl into the air outlet passage before use is reduced. The tapering extension may be present in any of the embodiments, for example it may be used in combination with air inlet passages that have extensions which also protrude into the bowl, as in the embodiments of FIGS. 3 and 4.
The central part of the airways and channels shown in FIGS. 3 to 6 have a semi-circular cross-section, and the airway has three passages that provide the air inlets and the air outlet. However, the airway and channel may have other cross-sectional shapes, provided that they match, i.e. the airway fits snugly into the channel. The airway could have other numbers of passages, provided that there is at least one air inlet and at least one air outlet. The mouthpiece could have a different shape, such as an elliptical rather than circular cross-section. The extensions of the air inlet passages are shown in FIGS. 3 and 4 as being straight, but they could alternatively be curved so that they match the inner surface of the bowl; this can help to hold the airway in place so that it cannot be pulled out along the channel.
FIG. 7 shows a longitudinal cross-section through a dispenser in which the air outlet passage 30 has internal baffles 44. The baffles help to retain powder that has entered the air outlet passage from the bowl before use. The air inlet passages may similarly have baffles. Additionally or alternatively, the air inlet and/or air outlet passages may have corners or be formed as a labyrinth for reducing the powder transfer through the passages into the detachable part. The baffles/corners/labyrinth may be present in the air inlet and/or outlet passages in any of the embodiments.
FIGS. 8A and 8B show an embodiment in which the airway is designed to create a cyclone in the bowl. FIG. 8A is a view from above of a dispenser after the detachable part has been removed, but with the lid not shown so that the airway and powder are visible. FIG. 8B is a longitudinal cross-sectional view through the centre of the dispenser. The airway has an air outlet passage 30 on one side and a single air inlet passage 31 on the other side. This asymmetric arrangement of the air inlet and air outlet passages creates cyclonic motion of the air within the bowl 21 when the user inhales, as indicated by the arrow. The cyclone helps to entrain the powder 20, and results in the smallest particles circulating near the centre of the bowl, whereas larger particles gravitate towards the edge of the bowl. Since the aerosolized powder enters the air outlet 30 from the top of the centre of the bowl through the extension of the air outlet passage 30b, the small particles are preferentially delivered to the user's lungs.
FIG. 9 shows an embodiment which is designed to deliver the contents of two dispensers simultaneously, for example in order to deliver a double dose, or to deliver two different medicaments simultaneously, for example if the two medicaments cannot be stored together in a single blister. FIG. 9A shows two dispensers 69a, 69b joined together; the dispensers could contain any of airways described above. The dispensers are cut out as a joined pair, rather than individual dispensers. The user tears off the detachable part 66, thereby exposing both of the air outlets, which are close enough together that the user can put both of them between their lips and inhale. The dispensers 69a, 69b could also be folded, for example, after the detachable part has been removed, so that one lies on top of the other (i.e. with the lids 11 touching each other). The air outlets 63a, 63b are thereby arranged one above the other, as shown in the side view of FIG. 9B.
The dispensers may be provided as a strip of several (e.g. six or ten) dispensers 79a-f, shown in FIG. 10. In FIG. 10A, the dispensers are all oriented in the same direction; in FIG. 10B, adjacent dispensers are oriented in opposite directions. Since in the embodiments shown the main part of the dispenser is wider than the neck, this alternating arrangement allows for closer packing. Each dispenser is detachable from the rest of the strip, for example by a line of perforations, so that individual dispensers can be detached as needed. A number of strips of dispensers may be provided in a pack, for example 30 days' supply of drug in the form of five strips with six dispensers per strip.
The medicament is suitable for administration by inhalation, for example for the treatment of a respiratory disease. It may include one of more of the following classes of pharmaceutically active material: anticholinergics, adenosine A2A receptor agonists, B2-agonists, calcium blockers, IL-13 inhibitors, phosphodiesterase-4-inhibitors, kinase inhibitors, steroids, CXCR2, proteins, peptides, immunoglobulins such as Anti-IG-E, nucleic acids in particular DNA and RNA, monoclonal antibodies, small molecule inhibitors and leukotriene B4 antagonists. The medicament may include excipients, such as fine excipients and/or carrier particles (for example lactose), and/or additives (such as magnesium stearate, phospholipid or leucine).
Suitable B2-agonists include albuterol (salbutamol), e.g. albuterol sulfate; carmoterol, e.g. carmoterol hydrochloride; fenoterol; formoterol; milveterol, e.g. milveterol hydrochloride; metaproterenol, e.g. metaproterenol sulfate; olodaterol; procaterol; salmeterol, e.g. salmeterol xinafoate; terbutaline, e.g. terbutaline sulphate; vilanterol, e.g. vilanterol trifenatate or indacaterol, e.g. indacaterol maleate. Suitable steroids include budesonide; beclamethasone, e.g. beclomethasone dipropionate; ciclesonide; fluticasone, e.g. fluticasone furoate; mometasone, e.g. mometasone furoate. Suitable anticholinergics include: aclidinium, e.g. aclidinium bromide; glycopyrronium, e.g. glycopyrronium bromide; ipratropium, e.g. ipratropium bromide; oxitropium, e.g. oxitropium bromide; tiotropium, e.g. tiotropium bromide; umeclidinium, e.g. umeclidinium bromide; Darotropium bromide; or tarafenacin.
The active material may include double or triple combinations such as salmeterol xinafoate and fluticasone propionate; budesonide and formoterol fumarate dihydrate glycopyrrolate and indacaterol maleate; glycopyrrolate, indacaterol maleate and mometasone furoate; fluticasone furoate and vilanterol; vilanterol and umeclidinium bromide; fluticasone furoate, vilanterol and umeclidinium bromide.
The invention provides a very simple unit dose dry powder inhaler. It can be manufactured using an adapted version of the conventional process for producing blisters, and only one simple additional component (the airway) is required. Consequently, the dispenser is inexpensive and easy to produce.