RU2002467C1 - Inhaler for inspiring powdery medicaments - Google Patents

Abstract

Use, the invention relates to devices for inhalation of drugs. and more specifically, to metered dose inhalers of drugs in the form of a powder, driven by an air stream generated by a person upon inhalation. The invention improves the efficiency of the use of drugs by reducing the loss of powder particles during transportation to the affected areas of the respiratory system. In addition, the hydraulic resistance is reduced in the device. SUMMARY OF THE INVENTION: in a medication powder inhaler, comprising a housing with holes for supplying air and aerosol exit, connected by an air duct, a dispersant installed therein, and also including a powder hopper and a dispenser containing plastic with metering holes, configured to moving the dose of powder from the hopper to the air duct, the dispersant is made in the form of a flow-through cyclone with a tangential inlet of air flow in the bottom of which a hole is made in the center. In the device, the dispersant is equipped with a flow straightener installed at the outlet of the cyclone. The dispenser is made in the form of a stack of plates rigidly interconnected, alternating with fixed plates with holes. A stack of plates is installed at the base of the hopper and dispersant, and the holes in the fixed plates are aligned with the holes in the bottoms of the hopper and cyclone. The metering holes in the movable plates are aligned with the holes in the fixed plates, forming a hole for dispensing and feeding the powder. 7 ea ez

Description

The invention relates to medical devices for administering drugs to the patient through the respiratory tract, and more particularly to metered dose inhalers for administering drugs in powder form,

The invention is intended for use in medical facilities.

A known inhaler for administering drugs in a powder bowl is provided, comprising a collapsible housing with openings for air passage and aerosol exit, in which a hard gelatin capsule is placed, filled with a dose of powder and mounted in a holder on the axis of a freely rotating turbine, which is located in the air duct, a hole for air passage and aerosol exit; and a tsuke piercing mechanism. When using the inhaler, the housing is disassembled, a capsule with a dose of powder is inserted into the holder on the axis of the turbine. Then, the inhaler is collected and, while idle on the piercing mechanism, 1 puncture is made on the lateral surface of the capsule, after which the inhaler is brought up with a hole and an aerosol exit to the oral cavity, and a full breath is taken. The airflow created by the print spins the turbine with a capsule attached to it. PBB by the action of centrifugal force, the powder flows out of the holes on the side surface of the capsule. Powder particles are entrained in the air stream and the human respiratory system is introduced. At the same time, aggregates of powder particles are destroyed as a result of their collision with the turbine blades and the walls of the air duct,

The disadvantage of this design of the inhaler, which has the brand name Spinhaler, is that it cannot be used for reproducible dispersion of small doses of powder (less than 15-20 mg), and also that it takes several breaths to empty the capsule, containing a single dose. In addition, a serious drawback of this design is the risk of fragments of the gelatin capsule getting into the airways and lungs of the patient, which can cause cramping and various infectious diseases.

The closest in technical essence and the achieved result is an inhaler for administration of drugs in powder form.

The inhaler comprises a housing with openings for air passage and aerosol exit, connected by an air duct with a dispersant installed in it, made in the form of a spiral insert, a powder hopper and a movable metering element made in the form of a plate with calibrated openings,

mounted to move a dose of powder from the hopper to the air duct.

When using this inhaler, the plate of the metering element is moved so that the holes in the plate filled with a dose of powder move from the hopper into the air duct. The inhaler is then brought up with an aerosol exit opening

5 to the oral cavity and take a full breath. The air stream created during inhalation blows off powder particles from the holes in the plate of the metering element. The mixture formed from the air-powder mixture enters the dispersant, passes through the spiral channels, as a result of repeated collisions of the powder particles with the walls and between themselves, the aggregates are destroyed, and the generated aerosol enters the respiratory

5 human system.

A disadvantage of this design of the inhaler, under the trade name Turbohater, is the large loss of powder particles in the oral cavity. Business

0 in that the drugs used by inhalation have a therapeutic effect only when introduced into the respiratory tract and lungs of a person. If particles are deposited on the mucous membrane of the oral cavity, they are then swallowed together with saliva and enter the stomach without causing the expected therapeutic effect.

The large loss of powder particles is due to the fact that the aerosol flow exiting the inhaler is strongly swirling as a result of the passage of air through the spiral channels of the dispersant. Centrifugal

5, the forces of the rotating powder particles drift in the radial direction and are deposited on the mucosa against the oral membrane.

The deposition efficiency and magnitude

The 0 loss depends on both the speed of rotation (the tangential component of the speed of movement) and the size (diameter) of the particles.

The disadvantages of this design should also include increased hydraulic resistance, which complicates the use of the inhaler by people with greatly weakened functions of the respiratory system.

The purpose of the invention is to increase the effectiveness of the use of drugs

means by reducing the loss of powder particles during transportation to the affected areas of the respiratory system and reducing the hydraulic resistance of the inhaler.

This goal is achieved by the fact that in the inhaler for the administration of drugs in the form of a powder, comprising a housing with holes for air passage and aerosol exit, connected by an air duct with a dispersant installed in it, a powder hopper and a movable metering element installed with the possibility of moving the dose of powder from the hopper to the air duct, the dispersant is made in the form of a straight-through cyclone with tangentially arranged holes for the passage of air and an axial hole in the bottom for the passage of powder and it is fitted with a flow scraper installed at the outlet of the cyclone, and the metering element is made in the form of parallel plates with eo-axially arranged metering holes, the plates being rigidly connected and installed with a gap relative to each other, and fixedly connected to the gaps between the plates housing guide plates. in which holes are made, eaxial with holes in the bottoms of the hopper and cyclone.

In FIG. 1 shows an inhaler, side view; and FIG. 2 - inhaler, top view, section AA; in FIG. 3 - inhaler, top view, section BB; Fig. 4 - inhaler, top view, section BB; in FIG. 5 is a side view of a second embodiment of a metering element; in FIG. 6 - dosing element, section AA; Fig. 7 is a dosing element, section BB.

The powder inhaler contains a housing 1 with openings 2 for air passage and an aerosol outlet 3. Holes 2 and 3 are connected by air duct 4, in which dispersant 5 is installed.

A powder hopper b and a metering element 7 are also located in the housing 1. The dispersant 5 is made in the form of a straight-through cyclone with tangentially located openings 8 for air passage. An axial hole 10 is provided at the bottom of 9 cycles for the passage of powder. At the outlet of the cyclone is placed a blade spinner flow 11.

The metering element 7 is located at the base of the hopper 6 and dispersant 5 and is made in the form of a stack of tightly adjacent alternating fixed 12 and movable 13 plates

The plates 12 are rigidly connected with the wall of the housing 1 and have holes 14, eaxial with the hole 10 in the bottom 9 of the cyclone and holes 15, eaxial with the hole 16 in the bottom

17bunker 6.

The plates 13 are rigidly interconnected by a handle 18 and have e-axial holes 19.

According to the second variant (see FIGS. 5-7), the metering element is made in the form of a stack of tightly adjacent alternating plates in the form of disks, fixed 12 and movable 13. In the fixed plates 12, four holes 14 are made, axial with an opening 10 in the bottom 9 of the cyclone, and holes 15, coaxial with a hole 16 in the bottom 17 of the hopper 6.

The fixed plates 12 are rigidly connected to the wall of the housing 1, and the movable plates 13 are fixed on a common shaft 20 with a handle 21 and have e-axial holes 19.

The inhaler works as follows, I will act mechanically on the handle

18 of the metering element 7, move the movable plate 13 so that the holes

19 in them were combined with the hole 16 in the bottom 17 of the hopper 6.

Under the action of gravity, the powder located in the hopper 6 is poured through the hole 16 in the bottom 17 of the hopper b into the dosage well, which is formed by the combined holes 19 of the movable plates 13 and the holes 15 of the fixed plates 12. Then they are mechanically acted on the handle 18, movable plates 13 so that the holes 19 with a measured dose of powder are aligned with the holes 14 in the fixed plates 12 located under the hole 10 in the bottom 9 of the cyclone. When the plates 13 are shifted and the holes 19 with the dose of powder are moved from the hopper 6 to the dispersant 5, the granules of the powder are destroyed by cutting them into thin layers by the plates so that after combining the holes 19 of the moving plates 13 with the holes 14 of the fixed plates 12, the cut powder layers are crumbled onto the bottom of the formed hole for feeding the powder into the dispersant 5. After that, the opening 3 for the exit of azrozole is brought to the oral cavity and a full breath is taken.

Under the influence of the vacuum created in the housing 1, atmospheric air through the openings 2 is supplied to the openings 8 for the passage of air through which it enters the cyclone. The vortex air flow arising in the cyclone through the hole 10 in the bottom of the cyclone 9 enters the well with a dose of powder formed by holes 19 in the movable plates 13 and holes 14 in

fixed plates 12. The powder particles are entrained by the air flow and enter the cyclone from the hole, where, as a result of repeated collisions between themselves and the cyclone wall, aggregates are destroyed. Exiting the cyclone, the aerosol stream passes through the blade spinner 11. In this case, there is a sharp braking of the rotational movement of the stream and the associated partial restoration of the pressure loss spent on swirling the stream. At the same time, additional dispersion of the particles occurs due to their inertial collisions with the blades of the spinner 11 with a sharp change in the direction of the air flow.

The aerosol of the drug generated by the currents through the air duct 4 exits the inhaler through the opening 3 and enters the respiratory tract and lungs of a person.

In the second embodiment, the inhaler operates as follows. By turning the handle 21, the movable plates 13 are turned so that the holes 19 in them are aligned with the holes 14 and 15 in the fixed plates 12 located under the hopper 6 and the cyclone.

Under the action of gravity, the powder located in the hopper 6 is poured into the hole formed by the aligned holes 19 and 15 in the plates 12 and 13. Then, by turning the handle 21 in the same direction, the plates 13 are turned so that the holes 19 with the measured dose of powder

Claims (1)

The claims INHALATOR FOR THE ADMINISTRATION OF MEDICINES AS A POWDER KA containing a body with holes for the passage of air and aerosol exit, connected by an air duct with a dispersant installed in it, a pig hopper and a movable metering element installed with the possibility of moving the dose of powder from the hopper to the air duct, characterized in that the dispersant is made in the form of a flow-through cyclone with tangential openings 0 5 0 5 0 5 0 fifty aligned with holes 14 in the fixed plates 12 and hole 10 in the bottom of the cyclone 9, and the empty holes aligned with holes 15 and 16, When turning the plates 13 and moving the powder, granules are further destroyed by cutting them into thin layers by the plates. that after aligning the openings 19 and 14, the cut-out layers of " powder " are crumbled to the bottom of the formed hole to supply powder to the cyclone. At the same time, a new dose of powder is measured as a result of its transfer from the hopper 6 to the well, which is formed after combining the openings 15 and 19. Compared to the prototype, an inhaler for administering drugs in the form of a powder allows to reduce particle loss during transportation to the affected areas of the respiratory system. By eliminating the rotation of the air flow at the outlet of the inhaler, a significant (5-fold) reduction in the loss of respirable particles (5 µm) of the drug powder is achieved. At the same time, a significant decrease in the hydraulic resistance of the inhaler (by 1.5 times) is achieved. As a result of a more thorough destruction of the powder particle aggregates, the inventive inhaler design allows to increase the yield of the respirable fraction of particles, which in turn leads to drug savings. (56) U.S. Patent No. 4,907,583, cl. 128-203.15. 1990. for the passage of air and an axial hole in the bottom for the passage of powder and is equipped with a flow straightener installed at the outlet of the cyclone, and the metering element is made in the form of parallel plates with coaxial metering holes, the plates being rigidly connected and installed with a gap relative to one another, and between the plates, guide plates are fixedly connected to the housing, in which holes are made, which are aligned with the holes in the bottoms of the hopper and cyclone. 4i  A r to T CN oh oh CN " f 1 Jl  i Csj Ј  4i s 3 t. x o 21 2002467 W g thirteen thirteen Editor T. Melnikova Compiled by E, Babarskoye Tehred M. Morgentap Fie Proofreader M. Kul