FI81762C - FUEL ADJUSTMENT FOR EFFECTIVE EFFECTS. - Google Patents

Description

1 81762

Nozzle for metered dose aerosol to enhance propellant gasification - Munstycke avsett för dosaerosol för effektivering av bärgasens förgasning

The present invention relates to a nozzle for a metered dose aerosol for enhancing the gasification of a propellant by transferring heat to the propellant and / or to the atomizer contained therein before the spray is discharged.

A wide variety of substances are sprayed mixed with propellant in industry on a large scale as well as in households as various aerosol preparations. The substance may be dissolved in, mixed with, or suspended in the propellant, or the substance and propellant may be from different containers with mixing just prior to or during dosing. The dosing takes place via an openable valve which can be made to work according to each purpose, it can be continuous or it can release only a certain amount of sprayable substance at a time; this is a dose valve. The substance to be sprayed is finally discharged from a nozzle, the properties of which together with the properties of the substance to be sprayed determine the properties of the spray.

When the spray is released from the pressurized aerosol, some of the propellant gasifies immediately upon entering the valve and nozzle passages. In this case, the temperature of the discharged substance drops sharply. The heat is then transferred from the warmer substance to the colder one, i.e. to the spray discharged from the valve and nozzle structures. Therefore, the proportion of the propellant immediately gasifying from the propellant of the spray discharged from the nozzle is always higher than the theoretical calculations based on the heat capacity and the heat of vaporization of the propellant show.

In fractional aerosols, the effect of heat transfer is small because the structures' own heat content is relatively small relative to the mass of the discharge spray and the thermal conductivity of conventional structural materials is poor. It is known to enhance the transfer of heat to the discharge material by heating the structures, e.g. with electricity.

The situation is different for dose aerosols. The amount of propellant released in these devices is, for example, 25 to 100 microliters.

If the valve / nozzle structures are a highly thermally conductive material, the transfer of heat to the discharge dose is very significant.

DE-A-27 11 060 discloses a collision-based heat exchanger, although it is also mentioned that heat transfer takes place in discharge channels, especially if the inner surface of the ductwork is rough. In a collision, the contact between the discharging substance and the contact surface is very good, but the heat content of the collision site is quickly applied and the additional heat is not applied to the collision site quickly enough. A corresponding collision-based heat exchanger is also known, since a conventional single-hole valve cone pin is such. In our calorimetric measurements, we have found that such a stainless steel beam pin increases the gasification of the inhalation aerosol propellant by a few percent compared to the corresponding plastic.

In the device according to the invention, the power is based on a sufficient contact surface as well as a sufficient amount of structural material, i.e. 1 heat content and 1 heat conductivity.

In the following, reference is made to an aerosol for inhalation use with a dose valve, i.e. an inhalation aerosol.

Inhalation aerosols use a metering valve that usually releases 20 to 50 μΐ of nebulizer, which is

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3 81762 suspension or solution between gas and drug. The dose is discharged from the metering valves into the nozzle. The purpose of the nozzle is to provide a nebulizer in which as much of the droplets or particles as possible are between 1 and 5 microns in size at the stage when the nebulizer is inhaled into the lungs. According to the current understanding, only particles of this size can penetrate their point of action up to the small bronchi. In inhalation aerosols in use, the propellant pressure is generally 350 to 450 kPa and the maximum is a simple plastic nozzle.

I nhalation aerosol is the most important form of treatment for asthma, although it is generally known that only about 10% of the dose reaches its site of action. About 80% remains in the oral cavity, which is explained to be mainly due to the fact that the size of the particles / droplets discharged from the nozzle is too large.

It has been reported in the literature that the nebulizer discharged from a nozzle of a conventional inhalation aerosol contains mainly drug-containing non-vaporized droplets of propellants which are considerably larger in size than 5. It has also been shown that when discharged from the nozzle, only 14 to 20% of the propellant gas has evaporated. It has further been shown that the heat required for this evaporation comes from the propellant's own heat content, and there is no time for heat transfer from the structures to the propellant during discharge.

The evaporation of the propellant gas before inhalation has been enhanced by increasing the evaporation time. Without spraying the dose into a separate vaporization chamber (so-called spacer), the propellant is effectively made to vaporize and more medicine into the lungs. Such devices are commonly used in clinical use.

It has now been found that the operation of the nozzle can be considerably enhanced by transferring heat to the propellant and / or the substance to be sprayed before it discharges from the nozzle.

4,81762

The nozzle according to the invention, for example, enhances the evaporation of the propellant gas of the inhalation aerosol spray at the moment of discharge by many times compared to a conventional nozzle. In this case, the amount of propellant-free drug particles of the correct particle size is correspondingly increased and correspondingly more drug can be inhaled into the lungs. This occurs in both suspension and solution based inhalation aerosols. Correspondingly, as the amount of drug remaining in the oral cavity decreases, a reduction in side effects through this is expected.

When connected to an inhalation aerosol, the nozzle of the invention improves the efficacy of the drug and reduces side effects. It can also be attached as a fixed so-called. the spacer. In addition, it can be applied to all cases in which it is desired to enhance the evaporation of the carrier or propellant gas carrying the active substance. The efficiency of the nozzle according to the invention can be further improved by external heating.

The nozzle according to the invention is characterized in that the nozzle, which is a highly thermally conductive material, has a discharge-duct system, the inner walls of which form a contact surface between the nozzle and the propellant for transferring heat to the propellant.

The nozzle according to the invention is made of a highly thermally conductive material, such as metal, and the contact surface between the propellant and the metal is large enough to allow a significant heat transfer. By adjusting the size of the discharge valves of the metering valve and the nozzle, the discharge time of the spray can be optimally adjusted empirically. When the valve is triggered from the dose chamber, the dose is discharged inside the nozzle. Since partial Gasification then occurs, a strong temperature drop occurs inside the nozzle. This allows significant heat transfer from the metal to the propellant.

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Other features of the invention will become apparent from the following claims. The invention will be explained in more detail with reference to the accompanying drawings, in which Figure 1 shows cross-sections of a known nozzle and three nozzles according to the invention, Figure 2 shows the power values of the nozzle according to Figure 1, Figure 3 shows some further nozzle applications according to the invention, and Figure 4 shows comparative test results.

Figures 1 and 3 show some basic structures of a nozzle according to the invention. Figure 1a shows longitudinal sections of a conventional nozzle. Figures 1b, c and d show a nozzle with a central supply channel 3 which communicates with the valve of the aerosol container through a recess 2 in the nozzle. The feed channel 3 runs in the central part of the nozzle from its upper part to the lower part and this channel 3 is surrounded by an annular space 4 extending upwards from the bottom of the nozzle. application, however, with different dimensions. With the duct system shown in the figure, the heat exchange surface a1 aa can be increased.

Figure 3 shows still further alternatives, in which together there is one more ring 1a compared to Figure 1. The discharge opening 5 is located in the lower part of the outer ring space. The middle option has a nozzle feed channel, which continues as a bend 6. As this also increases the heat exchange area in this case as well. In the third alternative, Fig. 3 6 81762 shows a structure in which the supply channel continues as a helical channel 7 terminating in the discharge opening.

These presented embodiments are only examples of nozzle adapters according to the invention. It is natural that the nozzle, and in particular its channel arrangements, can be implemented with a solution that differs from the present ones.

The evaporation efficiency of the heat exchanger nozzle compared to a conventional plastic nozzle was proved by two methods:

Method 1

The relative amount of non-gaseous propellant in the sprays was measured. The spray was directed at a distance of about 2 cm to a copper plate about 7 cm in diameter. Only the liquid propellant hinges collide with the plate, from which they get the heat of vaporization they need. The change in the electrical conductivity of the thermal resistor indicates the decrease in heat that is taken to the plotter. The higher the peak, the greater the temperature drop and the more non-volatile propellant. Five different nozzles (Figure 1) were used in the experiments: a conventional plastic nozzle as well as a similar copper nozzle (a) and three different sized heat exchanger nozzles (b, c, d). The aerosol can was equipped with a 50 or 25 μΐ metering valve.

Score

It can be seen from Figure 2 that the heat exchanger nozzles are clearly better than a plastic nozzle or a copper nozzle of this kind. The evaporation capacity of the heat exchanger nozzle improves as the amount of copper increases. Because the heat exchanger nozzles vaporize the 50 μΐ dose more efficiently than the 25 μΐ dose of the plastic nozzle, the heat exchanger nozzles evaporate more than 50% of the 50 μΐ dose. If

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7 81762 a dose volume of 25 μΐ is used, the heat exchanger nozzle then evaporates practically all the propellant.

Method 2

The amount of drug obtained from two spacers of different sizes (bioavailability) was measured with a-plastic nozzle time 11 a and a 1 heat exchanger nozzle c. A device that fractionates drug particles by size (Andersen 1 AFTM Cascade Impactor) was used for the measurements. Fractions were analyzed by HPLC. In this case, the average particle size (MMAD = mass media aerodynamic diameter) could also be calculated. An improvement in the heat exchange capacity of the nozzle correlates with an improvement in the bioavailability.

_Table_

Bioavailability% _of_dose_MMAD μm

Spacer 1 nozzle a-plastic_20.0_2.32

Spacer 1 nozzle c_54.2_2.21: Spacer 2 nozzle a-plastic_37.9_2.54

Spacer 2 nozzle c_79.5_2.37

Spacer 1 = 88 cm3

Spacer 2 = 250 cm3

Score

It can be seen from the results in the table that the heat exchanger nozzle c improved the efficiency of both spacers by about twice compared to the plastic nozzle a, as well as somewhat reduced the average particle size, which is also a positive result. As the bioavailability is proportional to the amount of drug entering the lungs, an improvement in efficacy and a reduction in the amount of drug remaining in the mouth and the resulting side effects are expected.

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The device according to the invention can be applied directly as an inhalation aerosol nozzle. It can also be connected to a fixed spacer, which improves the concept and the size of this concept compared to previous solutions. The heat exchanger nozzle discussed here is compact, efficient and suitable for series production. However, other known heat exchanger designs give similar results, provided that the flow inside the nozzle is arranged so as to prevent the adhesion of the drug inside the nozzle. Some such structures are shown in Figure 3.

In the above applications, it should be noted that when the valve is open, there is an open connection from the nozzle to the tank containing the substance to be sprayed. Thus, the pressure inside the nozzle cannot be higher than the pressure inside the tank, but the heat content of the substance in the discharge spray is higher than when using a conventional nozzle.

Worth 1ukoe

Comparative experiments compared the amount of non-gaseous propellant in a dose aerosol spray. The measurements were performed with a calorimeter, the measuring element of which is placed 1, 2, 3 and 4 cm from the nozzle opening. ° C is directly proportional to the amount of non-useful propellant, i.e. the lower the ° C the better the propellant is gassed.

For comparison, a plastic or metal nozzle according to Figure 1a and a nozzle according to Figure 1b were used. The curves in Figure 4 show that the nozzle provided with a plastic spindle gave a worse result, the metal spindle gave a slightly better result, and the nozzle according to the invention is clearly the most efficient of the reference nozzles.

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Claims (3)

9 81762 A nozzle for a metered dose aerosol for enhancing the gasification of a propellant by transferring heat to the propellant and / or the atomizer contained therein before discharge, characterized in that the nozzle, which is a highly thermally conductive material, has a discharge duct system . Nozzle (1) according to claim 1, with a supply channel (3) communicating with the valve of the aerosol container, characterized in that the supply channel (3) continues as one or more interconnected annular valves (4), meandering (6) , as a helical (7) or similar channel or a combination thereof, the channel having a discharge opening (5). Nozzle according to Claim 2, characterized in that there is a space in the nozzle and / or between it and the valve for dispensing the substance to be sprayed for propellant gasification or partial gasification. 10 81 762