NL1006858C2 - System for condensing moisture from exhaled breath - Google Patents

Abstract

Uses cooling system to reduce temperature of exhaled breath to dew point

Description

Method and device for condensing a fluid.

The present application relates in a first aspect to a method for condensing the breath of a human or animal, or collecting a condensate or a condensed fraction from the breath of a human or animal.

It is known in the prior art to condense the breath of certain patients and then analyze the condensate. Various information can be derived from the composition of the condensate, including information about the patient's state of health and the presence of certain components in the bloodstream (blood levels). On the basis of this a diagnosis can be made or a therapy determined, for instance the correct dosage of medications to be prescribed to a patient.

In the prior art, so-called centrifuge condensing devices are generally used for condensing breath. In order for these condensing devices to function properly, it is required that the patient blows into the device with relatively great force and for some time continuously.

However, for a large number of patients, it is not possible to blow into the prior art condensing device with sufficient force to collect sufficient condensate. Especially for patients with severe lung abnormalities, it is necessary that they can also blow out without any resistance when collecting breath condensate.

It is the object of the present invention to provide a method in which the breath of a patient can be condensed, while the patient himself experiences less resistance when exhaling than in the prior art methods.

That object is achieved according to the present invention in that said method comprises supplying the breath from an inflow end to a cooled and slightly angled to the horizontally disposed condensation tube which is provided with a free outflow end, said condensation tube at a temperature is held - that is by cooling in the range from -10 ° C to + 10 ° C, and preferably in the range from -1 ° C to + 1 ° C, such that condensable components can condense out of breath against the wall of that condensation tube after which the condensed components are collected at that free outflow end.

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The advantage of this method is that breath condensate can be collected from a person or an animal, without this person or animal being subjected to additional resistance when exhaling.

Experiments have shown that the present process can be used particularly advantageously if the above temperature ranges are observed. The temperature used is preferably not so low that the components of interest remain as a sublimate on the wall of the tube, as this could decrease the reliability of the determination. Incidentally, the solid components to be determined under the temperature used will usually be present in the condensate in dissolved or solvated form.

The method according to the invention is in particular used to determine in the (condensed) breath the presence and / or the amount / concentration of certain components of interest, in particular components that provide information about the patient's health status and / or the presence of administered drugs and / or their metabolic products. Important examples of this are hydrogen peroxide and / or proteins. To this end, the collected condensate can be analyzed in a manner known per se, using known analytical techniques, such as chromatographic techniques (GC, HPLC), immunological techniques (in particular with proteins), and spectroscopic techniques. The data thus obtained can optionally be used by a treating physician to formulate or change a treatment regimen, such as the dosage of drugs.

In a second aspect, the present invention relates to a device for performing the above method. Said device is characterized in that said device comprises a condensation tube, one end of which has an inflow end and is provided with connecting means for mounting a hose for supplying the breath to be condensed, said hose preferably comprising a mouthpiece and more preferably a replaceable nozzle, the other end of the condensation tube forming a free outflow end, and wherein a cooling element for cooling the wall of said condensation tube is arranged in the vicinity of said condensation tube. The advantage of the use of this device is that this device has a very simple construction and a compact design.

In a preferred embodiment of the present device, said cooling element forms the evaporator of a compression cooling circuit, said evaporator being designed as a tubular evaporator arranged spirally around the condensation tube. The advantage of such a construction is that it is possible to work with a cooling device whose usefulness has amply proven itself in practice.

The present invention is further improved in that said condensation tube in that cooling element is enclosed by insulating material.

The measure has in particular the advantage that the energy consumption of the present device can be considerably saved by using the insulating material.

In a preferred embodiment, said condensation tube is placed at an angle to the horizontal, the free outflow end being positioned lower than the inflow end. The advantage of this measure is that the condensate flows under the influence of gravity to the free outflow end of the cold store to be collected there.

In an advantageous embodiment, the condensation tube is made of stainless steel. The advantage of the use of stainless steel is firstly the good thermal conductivity of the material, secondly the fact that the cold store can be made thin-walled by the use of stainless steel, thirdly that the cold store will not corrode even in contact with the breath.

According to an advantageous embodiment of the present invention, collecting means are arranged under the free outflow end of the tube for collecting the condensed fluid. This has the advantage that the breathing condensate can simply be collected at the free outflow end of the cold store.

In addition, it is advantageous if the device according to the present invention is provided with an electronic timer. The duration of a breath test can be set using this timer. Namely, the time over which a patient's condensate must be collected can differ per patient.

The use and application of the device according to the present invention can be further improved in that a disposable is placed in the present invention, characterized in that the disposable is adapted to be placed against the inner wall of the condensation tube, the disposable being inner wall of the condensation tube is substantially covered. It is also advantageous that it is made disposable from plastic.

The use of the disposable has a number of advantages. The first is that the condensation tube does not need to be cleaned after the device has been used to collect breath condensate from a patient. Secondly, some components of the breath condensate (including hydrogen peroxide and proteins) will react with metal. When the cold store is not covered on the inside with a plastic, those components, including the protein already mentioned, will be lost in the condensate. By using a plastic disposable, the breath condensate remains intact and the information value of the breath condensate therefore increases.

In addition, it is advantageous that the device comprises a housing in which the condensation tube and the cooling means are accommodated. The device according to the present invention can therefore be moved, used and stored as a whole and thereby user-friendly.

The present invention is further elucidated with reference to the annexed drawings, in which:

Figure 1 is a partial cross-sectional view of the condensation tube 20 of the present invention.

Figure 2 is an exploded view of the breath condensing device of the present invention.

In figure 1, the condensation tube 1 is shown partly in cross-section. The condensation tube 1 is, for example, a thin-walled stainless steel (stainless steel) tube. This tube 1 has, for example, a diameter of approximately 54 mm. The condensation pipe 1 is wrapped with a red copper cooling pipe 2. By means of this cooling pipe 2, the condensation pipe 1 is cooled from the outside. The cooling pipe 2 is in turn wrapped with an insulating layer 3. The inflow opening 4 of the condensation pipe 1 is connected to a hose or a nozzle 5. It is advantageous to design the nozzle 5 as disposable, so that the hose after use can be removed and does not require cleaning. A condensate container 7 is placed at the bottom of the outflow opening 6.

The operation of the condensation tube 1 during use is as follows: With 1006858 5 using the mouthpiece 5, a patient breathes for some time through the cooled condensation tube 1. The breath flows from the mouthpiece 5 through the tube 1 in the direction of the free outflow end 6. Because the condensation tube 1 has cooled, part of the moisture from the breath will condense. This condensed breath-moisture will move through the inner wall of the condensation tube 1 towards the condensate container 7. The condensate can then be removed in the condensate container 7 for analysis. In order to prevent parts of the condensate (for example the proteins) from settling against the inside of the condensation tube 1, and thereby not getting into the condensate holder 7, a plastic disposable insert 8 can be placed in the condensation tube 1. The use of this plastic disposable insert 8 also has the advantage that the condensation tube 1 does not have to be cleaned on the inside after use.

Figure 2 shows an exploded view of the breath condensing device of the present invention. Figure 2 shows the condensation tube 1, provided with the insulating outer layer 3 and a nozzle 5, which is built into a housing 20. Furthermore, the cooling system with which the condensation tube 1 is cooled is arranged in the housing 20. The cooling system comprises a capillary tube 21 through which coolant is injected into the cooling pipe 2 (see figure 1). In the cooling line 2, the coolant evaporates, taking up heat. After the refrigerant has left the refrigerant line 2, it flows to the compressor 22. The refrigerant then condenses in the condenser 23, releasing its heat to the environment. In addition, to remove the heat from the housing 20, a fan 24 is placed next to the condenser 23. The coolant then flows from the condenser 23 via a dryer 25 in the direction of the capillary tube 21 and so on.

Figure 2 also shows that the housing 20 is provided with an adjustable electronic temperature control with a digital indication. An electronic timer is also mounted to set the duration of the breath test, which can be different for each patient. The adjustable electronic temperature control and the electronic timer are symbolically shown in the display 30. Experiments have shown that the best results are obtained when the condensation tube 1 is cooled to a temperature in the temperature interval plus 10 ° C to minus 10 ° C . The operation of the device is particularly good at the temperature interval plus 1 ° C to 1006858 6 minus 1 ° C.

It is clear that only one possible embodiment is shown in the above drawings. Numerous variations are possible without departing from the premise of the present invention.

1006858

Claims (11)

A method for condensing the breath of a human or animal, or collecting a condensate or condensed fraction from the breath of a human or animal, characterized in that the breath from an inflow end to a cooled and is fed slightly at an angle to the horizontally positioned condensation tube which is provided with a free-flow end, the condensation tube being kept at a temperature in the range from -10 ° C to + 10 ° C, preferably in the range from -1 ° C to + 1 ° C, such that condensable components can condense from the breath against the wall of the condensation tube, after which the condensed components are collected at that free outflow end. 2. Device for carrying out the method according to claim 1, characterized in that said device comprises a condensation tube, one end of which comprises an inflow end and is provided with connection means for mounting a hose for supplying the condensation to be condensed breath, said hose preferably comprising a mouthpiece and more preferably comprising a replaceable mouthpiece, the other end of the condensation tube forming a free outflow end 20, and in the vicinity of said condensation tube a cooling element for cooling the wall of that condensation tube. 3. Device as claimed in claim 2, characterized in that said cooling element forms the evaporator of a compression cooling circuit, wherein said evaporator is designed as a tubular evaporator which is arranged spirally around the condensation tube. Device according to claim 2 or 3, characterized in that said condensation tube in said cooling element is enclosed by insulating material. 30 Device as claimed in claim 2, 3, or 4, characterized in that said condensation tube is placed at an angle with respect to the horizontal, the free outflow end being placed lower than the inflow end. 1006858 Device according to any one of claims 2 to 5, characterized in that said condensation tube is made of stainless steel. 7. Device as claimed in any of the claims 2-7, characterized in that collecting means are arranged under the free outflow end of the tube for collecting the condensed fluid. Device according to one of claims 2 to 7, characterized in that the device is provided with an electronic timer. 10 Disposable for application in the device according to any one of claims 2 to 8, characterized in that the disposable is adapted to be placed against the inner wall of the condensation tube, the disposable in the inner wall of the condensation tube essentially covered. 15 Disposable according to claim 9, characterized in that it is made of plastic. 11. Device as claimed in any of the foregoing claims, characterized in that the device comprises a housing in which the condensation tube and the cooling means are accommodated. 1006858