UA141077U - PULMONARY EXPERT COLLECTION DEVICE - Google Patents

Abstract

Device for collecting pulmonary expiratory, consisting of a tube, one end of which is intended for exhalation, and the other is connected to a container for collecting condensate-expiratory, the inner cavity of the tube contains a series of rounded grooves in contact with the refrigerant and the housing in one the wall of which has a hole at the level of the location of the tank for collecting condensate, according to the utility model in the structure of the device includes two holders of refrigerant.

Description

The useful model belongs to the field of medicine, namely pulmonology and allergology, and can be used to improve the results of treatment of patients with respiratory diseases.

Recently, there has been increasing interest in noninvasive lung research, including sputum induction and measurement of biomarkers in lung aspirate. Collection of exhaled air is a completely non-invasive method of sampling from the respiratory tract, which can be repeated even several times a day with a short interval. Devices for collecting pulmonary expiratory can be portable (portable) and used even in intensive care units, outpatient clinics and at home. These criteria of the device for further analysis of the obtained biomaterial make it a useful tool for research and significantly help to determine the features of pathological processes (oxidative stress, inflammation). When a person breathes into a cooled collection device, pulmonary exhaled breath is released from the lungs, thus condensing the vapors and aerosol droplets produced with each exhalation (Nogmaii I, 2005).

At present, more than 200 compounds have been detected in lung expiratory air, and some researchers consider the analysis of exhaled air condensate "an instant photograph of the processes in the alveoli and bronchi" (Knapopom 5.A., 2001; Noiitapp N., 2008). It has been investigated that changes in its physicochemical properties, imbalance of acid-base balance, accumulation of nitric oxide, hydrogen peroxide, aldehydes, isoprostanes, eicosanoids, cytokines, electrolytes, peptides, protons and various ions, etc. "9.I., 2006; E. Napitroig, 2018). It is their content that allows diagnosis and monitoring of diseases, as it is a non-invasive and informative method of studying the activity of the inflammatory process (Oamid5zop A., 2007; Oamiv M.O., 2018).

In general, lung aspirate analysis has significant potential to address unmet medical needs by expanding non-invasive testing capabilities for many pathological conditions, particularly of the respiratory system. From this position, the analysis of lung expiratory parameters in combination with other clinical and laboratory data can be considered very promising for the improvement of individual treatment and prevention measures.

The first analog of a useful model is a device for collecting exhaled air liquid

Co.) (0507659490, 055081871А Ab1 B5/083, 21.01.1992 "Vgeaiy zatrieg", ipu. Vobrep A. Spazeg. - O5

Reraptepi oi Neay apa Nytap 5eguisez (NN5B)), which is a U-shaped tube immersed in a container with ice.

The disadvantages of this analogue device are that the need to use ice and the rather fast time of its melting require changing the capacity after a short period of time.

Another analogue of the useful model is a device for collecting the components of exhaled air (0508827703, 056010459А AbЭІ185/097, 04.01.2000 "Meitosy apa arragaishv5 yog te teazigetepi oi sotropepiv oi ekhpaiei Bgeai ip Pitapve", Ipu. RNyir E. 5iYikoi, Raisia, A. 5 biemeg5

Ipvigitepiv Ips.), which consists of a cooled tube connected to a compressor and a monitor.

Disadvantages of this analogue device are that it requires special equipment, such as nearby DC sources; to work with this device requires trained personnel, which, in the vast majority, is not available for practical health care facilities, especially primary and secondary health care.

Another analogue of a useful model is a device for adsorbing the moisture of exhaled air when a patient breathes into a breathing bag (patent of the Russian Federation NO 2243720 (13) C2, 2005.01.10 "Method of moisture adsorption from a unit volume of air-discharged air and a device for its implementation", author Borisova M.A., Alekseeva Yu.A., Koroliuk E.G., Kurochkin A.V.,

Borysov V.S. - Tver, Tver State Medical Academy.), which has the form of a tube, one end of which is intended for exhalation, and the moisture of the exhaled air is collected for 15 minutes, which is controlled by turning on the timer, with the help of a microcompressor that pumps air. After turning off the timer, 0.5-1.0 ml of condensate adsorbed on silica gel is obtained in a disposable tube, which is stored in a freezer.

The disadvantages of this analogue device are that it requires special equipment: a microcompressor, a timer; the use of silica gel for condensate adsorption can change biochemical indicators and cause false results; in addition, children's patients are sometimes not able to continuously breathe into the condenser for 15 minutes, and the methodology does not provide for a break in the study.

As the closest analog, a device for collecting exhaled air condensate (Device for collecting exhaled air condensate: pat. 45346 Ukraine. Mo. 200904537; 60 application. 05.07.2009; publ. 11.10.2009, Bull. Mo. 21), which has the form of a tube, one end of which is adapted for exhalation, and the other is connected to a container for collecting exhaled condensate, and the inner cavity of the tube part contains a number of rounded grooves that are in contact with a means for cooling the exhaled condensate in the form of cryogel, and the device itself is equipped with a housing, one the wall of which has a hole placed at the level of the location of the container for collecting condensate.

The disadvantages of the device are that during the examination period, the cold gel can slide down the device and fall, which worsens the collection of lung expiratory air, since the inner cavity of the part of the tube with rounded grooves does not cool enough, this requires constant monitoring of the location of the cold gel, which during the examination should be exactly on the central part of the device.

The basis of the useful model is the task of improving the device for collecting lung expiratory air by having two cold gel holders in the structure of the device.

The common features of the closest analogue and the useful model are that the device has the form of a tube, one end of which is intended for exhalation, and the other is connected to a container for collecting condensate-expiration, the inner cavity of the tube part contains a number of rounded grooves in contact with the cryogel; the device has a case, in one wall of which there is a hole at the level of the location of the container for collecting condensate.

Distinctive features of the useful model from the closest analogue are that the structure of the device includes two cold gel holders.

Definition of terms used in the description of the useful model: pulmonary expiratory, exhaled air, tube, container for collecting condensate, row of rounded grooves, cryogel, cryogel holders.

Theoretical prerequisites for the implementation of a useful model.

In a useful model, collection of lung expiratory fluid is carried out, which can be used in the future in the diagnosis and monitoring of respiratory diseases.

The proposed device is quite small (30x10x10 cm), which allows collection of exhaled condensate directly in the ward, which is of significant importance for the examination of seriously ill patients and children. Also, this device allows you to collect pulmonary aspirate with periodic breaks at the request of the patient, since the bag with cryogel provides the opportunity

From keeping the low temperature necessary for liquid condensation for a long enough time.

As a cold gel, silica gel or other cold gel produced by the industry can be used.

The practical application of the closest analogue showed frequent shifting of the cooling gel to the bottom of the device, which worsened the cooling of the air exhaled by the patient and required constant monitoring by the researcher of the location of the cooling gel.

Glass cold gel holders as an extension of the inner cavity of the part of the tube allow you to maintain the central location of the cold gel around the tube throughout the entire period of collection of lung expiratory air and speed up its collection by ensuring the constant cooling of air exhaled by the patient, which passes through the inner cavity of the part of the tube.

Pulmonary aspirate is collected in a clean container for collecting condensate-expirate, which is removable and processed at the end of each examination, and poured into a disposable tube without adsorbent or other additional substances, which is stored in a freezer until the beginning of the study.

Due to the use of this principle of cooling and collection of lung expiratory air, the proposed device is convenient and cheap to use, and, taking this into account, it can be used for the diagnosis and monitoring of respiratory diseases in almost all institutions of a medical and preventive profile, it will allow to rationalize the selection of individualized treatment for such patients.

A useful model is implemented as follows.

The drawing shows a device for collecting lung exhaled breath, which has the form of a tube 1, one end 2 of which is intended for exhalation, and the other end C is connected to a container 4 for collecting exhaled condensate, the inner cavity of part of the tube contains a number of rounded grooves 5 that contact with a cold gel 6 fixed on two holders 7. The device has a body 8, in one wall of which there is a hole 9 at the level of the location of the container for collecting condensate.

Principle of application of the proposed device

With the help of the device, lung exhaled breath is collected from patients with respiratory diseases as follows: The patient exhales air, breathing calmly through the end 2 of tube 1. Vapors 60 of exhaled air, passing through the middle part of tube 1, condense when cooled by cold gel b and settle on the inner walls of the rounded grooves 5, further draining into container 4. Control of the amount of collected condensed liquid is carried out through hole 9 in housing 8.

Examples of the use of a useful model

Child K., born on January 15, 1993, was being treated in the allergy-pulmonology department

ODKL Mo 1 from 11/13/2007 to 11/29/2007 with the diagnosis: Bronchial asthma, atopic form, persistent course, severe degree, exacerbation period, DN I-II, chronic allergic rhinitis.

On November 26, 2007, the child exhaled air into the proposed device-condenser for collecting pulmonary expiratory air for 20 minutes with a 4-minute break, as a result of which 1.6 ml of exhaled air condensate - expiratory air was obtained. According to exhaled air condensate data (protein fractions, nitric oxide metabolites), high activity of respiratory tract inflammation was determined in the child and a severe degree of bronchial asthma was verified.

Child 3., born on June 25, 1994, was being treated in the allergy-pulmonology department

ODCL Mo 1 from 08/29/2007 to 09/11/2007 with the diagnosis: Bronchial asthma, atopic form, persistent course, medium-severe degree, period of exacerbation. On September 3, 2007, the child exhaled air into the proposed condenser device for 23 minutes with an 8-minute break, as a result of which 1.5 ml of exhaled air condensate was obtained - expiratory air. According to exhaled air condensate data (protein fractions, nitric oxide metabolites), moderate activity of respiratory tract inflammation was determined in the child and a moderate degree of bronchial asthma was diagnosed.

Therefore, the claimed device has better qualities in relation to the nearest analogue due to the fact that the cold gel holders allow to maintain the central location of the cold gel around the inner cavity of the tube part, which eliminates the identified shortcoming of the prototype.

Technical result. The proposed device allows you to effectively collect lung expiratory air and, thanks to this, makes it possible to diagnose and monitor respiratory diseases, and subsequently to rationalize the selection of individualized treatment for patients and reasonably prescribe therapeutic and preventive measures.

Claims (1)

UTILITY MODEL FORMULA Koo) A device for collecting pulmonary expiratory tissue consisting of a tube, one end of which is intended for exhalation, and the other is connected to a container for collecting exhaled condensate, the inner cavity of the tube part contains a number of rounded grooves in contact with cryogel; and the body, in one wall of which there is a hole at the level of the location of the container for collecting condensate, which differs in that the structure of the device includes two cold gel holders.