RU2740727C1 - Model of human respiratory tract - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine. Human respiratory tract model comprises elements imitating body parts. Model comprises sequentially and removably connected nose, pharynx, larynx and trachea, which are equipped with longitudinal cavities communicated with each other. Pharynx is rigidly attached to an upper jaw, to which a lower jaw is connected with a possibility of rotation in a vertical plane. In the pharynx and larynx walls on the side of jaws and nose there are through holes communicated with corresponding cavities. Removable indicator composition is applied on cavity surface.

EFFECT: technical result consists in improvement of quality and objectivity of control and correctness of instrument action, expansion of application area and display of results of introduction both on tool and on model.

3 cl, 8 dwg

Description

The invention relates to medicine and biology and can be used for mastering and / or practicing the skills of performing manipulations on the airways, including in the process of teaching and / or training specialists or during research.

The causative agents of acute respiratory diseases affect the epithelium of various parts of the respiratory tract of their potential hosts and are able to adapt to deeper parts of the respiratory tract, becoming a direct etiological agent of lethal pneumonia [1, 10, 15]. The absence of contamination for conducting highly specific diagnostics is extremely important for microbiological research methods; therefore, special attention should be paid to this condition.

Known application of silicone otorhinolaryngological simulators (ORLS) of various designs in educational activities both in Russia [3, 4, 11, 12] and abroad [17, 18, 20, 21].

The disadvantages of analogs are:

- high cost and lack of natural appearance of the human respiratory tract [3];

- increased requirements for storage and operation of dummies and biological material;

- the inability to simulate the individual characteristics of a particular patient and the diagnostic tasks to be solved.

As the closest analogue, a simulator was adopted for mastering the skills of performing operations on the kidney, containing elements that imitate parts of the human body (see patent 2691524, IPC G09B 23/28, publication date 06/14/2019).

The disadvantage of the closest analogue is the lack of the possibility of a qualitative assessment of the trainee's manipulations when controlling the immersion depth and the amplitude of movement of the tools for marking target and non-target zones on the surface of the organ.

The problem to be solved by the present invention is the development of a modifiable reusable airway model with a low cost.

The technical result, which is achieved when solving the task, is expressed in improving the quality and objectivity of control and the correctness of the impact of the instrument, expanding the scope and displaying the results of the introduction both on the instrument and on the layout itself.

The problem is solved by the fact that the model of the human respiratory tract, containing elements that mimic body parts, differs in that it contains a series and removably connected nose, pharynx, larynx and trachea, which are equipped with longitudinal cavities communicated with each other, while the pharynx is rigidly connected with the upper jaw, to which the lower jaw is connected with the ability to rotate in the vertical plane, and in the walls of the pharynx and larynx from the jaws and nose, through holes are made, communicating with the corresponding cavities, in addition, a removable indicator composition is applied to the surface of the cavities.

In addition, a removable colored indicator composition is used.

In addition, elements that mimic parts of the human body are made using 3D printing.

Comparative analysis of the totality of essential features of the proposed technical solution and the totality of essential features of the prototype and analogues indicates its compliance with the "novelty" criterion.

In this case, the distinctive features of the claims solve the following functional problems.

Features the layout “contains a series-connected nose, pharynx, larynx and trachea”, “the pharynx is rigidly connected to the upper jaw with teeth, to which the lower jaw with teeth is attached” and “through holes are made in the walls of the pharynx and larynx from the side of the jaws and nose” and signs of the second dependent claim of the formula allow you to create an anatomically correct model of the human respiratory tract or modify it taking into account the research tasks to be solved in front of a specialist.

The signs "nose, pharynx, larynx and trachea ... are provided with longitudinal cavities communicated with each other", "through holes in the walls of the pharynx and larynx are communicated with the corresponding cavities" and "the lower jaw is connected to the upper jaw with the possibility of rotation in the vertical plane" introducing the tool into the layout without the ability to see the elements in a vertical section.

This feature of the created model is due to the fact that in a real situation, when carrying out this manipulation, a specialist should develop a spatial understanding of the location of his hand and instrument inside the patient's airways with respect to their constituent elements, taking into account the anatomical and topographic features and fundamental knowledge of the researcher.

The features "contains a removably connected nose, pharynx, larynx and trachea" and "a removable indicator composition is applied to the surface of the cavities" provide the possibility of modification, reusable use of the model, as well as direct viewing of the results of the task assigned to the specialist, and application of the removable indicator composition to the area "Interest" and "mistakes" taking into account the type of tasks being performed.

The sign "an indicator composition is applied to the surface of the cavities" and the signs of the first dependent paragraph of the formula allow simulating the features of the anatomical and physiological character of the patient (for example, the intensity of secretion of the salivary glands in the oral cavity and the activity of the mucociliary apparatus in the nasal cavity) the mucous membrane of the respiratory tract and assess the correctness of the effect of the introduced tool, improve the quality and objectivity of control of such parameters as depth, trajectory and location of the tool impact.

Figure 1 shows a side view of a mock airway.

Figure 2 shows a front view of a mock airway.

Figure 3 shows a bottom view of a mock airway.

Figure 4 shows the beginning of the introduction of the tool into the layout.

Figure 5 shows the larynx with a removable indicator composition.

Figure 6 shows the tool after the correct impact on the layout.

Figure 7 shows the tool after incorrectly influencing the layout.

Figure 8 shows a colored removable indicator composition of the larynx after exposure to the instrument on the model.

The drawings show nose 1, pharynx 2, larynx 3, trachea 4, upper 5 and lower 6 jaws, through holes 7 and 8 of pharynx 2 and larynx 3, respectively, colored removable indicator composition 9.

The nose 1, the pharynx 2, the larynx 3 and the trachea 4 are connected in series and removably (for example, according to the thorn-groove principle) and are provided with longitudinal cavities communicated with each other.

The pharynx 2 is rigidly connected to the upper jaw 5, to which the lower jaw 6 is connected with the possibility of rotation in the vertical plane.

In the walls of the pharynx 2 and larynx 3, from the side of the jaws 5 and 6 and the nose 1, through holes 7 and 8 are made, connected with the corresponding cavities.

Removable colored indicator composition 9 is applied to the surface of the cavities.

The claimed device operates as follows.

1. Pre-fabricated airway layout elements and removable colored indicator composition.

The airway model is created in several stages.

At the first stage, the results of computed and / or magnetic resonance imaging are collected in the form of digital data.

At the same time, a 3D model of the skull with the frontal, sphenoid, ethmoid, lacrimal, zygomatic and temporal bones, the upper and lower jaws, fixed in accordance with their anatomical location, is distinguished on the images.

The authors carried out research using a multislice computed tomograph Toshiba Aquilion multi 320 (Japan). Protocol of the 3 Phase Head study, with the patient lying on his back (shooting parameters: spiral study mode, slice thickness 0.5 mm, voltage 120 kV, current strength 80 mA, tube rotation speed 0.5 sec) followed by the construction of multiplanar reconstructions and 3D models of the skull and cartilage in the free software Slicer 3D [8, 13].

At the second stage, the general combined shape of all the obtained models of the airway elements of a particular patient is simulated, or images of different patients are used.

3D models are processed, for example, in free programs: Meshmixer (Autodesk, Inc., San Rafael, CA, USA) and Blender (Blender Foundation, Netherlands, open source software).

You can use the data of a particular patient, taking into account the individual characteristics of his body, or, on the contrary, create the most universal and general model.

At the third stage, the authors printed the layout elements on a 3D printer. All parts can be printed in a single cascade or separately with the possibility of assembly and disassembly.

To obtain 3D models, software was used, such as open source "Cura".

As a material for 3D printing, you can use PLA plastic or acrylonitrile butadiene styrene, which allows you to obtain samples at an affordable price, as well as transparent materials (for example, VisiJet, PETG T-Glass, ABS plastic, etc.).

The digital model allows printing at any scale. Of particular value for the educational process are the models of the airways, enlarged in comparison with real objects, which makes it possible to increase the clarity of the detailing of the objects under study and the medical procedures performed.

The sequential application of mock-ups with a gradually decreasing scale is a convenient methodology for eliminating unnecessary movements that increase the risk of damage to the mucous membranes.

The optimal properties of the indicator composition to be removed are:

- high adhesion properties (with a surface energy of 97-108 J / m) - so that the composition does not drip from the surface of the cavities;

- neutral pH level (6.8-7.2), so that it does not react with other substances;

- the base must be colorless, with the possibility of staining;

- the possibility of easy removal of the composition, without the use of special substances or tools;

- average viscosity - Brookfield value 16.0-20.0 Pa · s, so that visible traces of the impact of the introduced tool remain and remain;

- the composition must maintain its viscosity, i.e. do not harden for 1.5-2 hours - this time is generally enough for medical manipulation or for 1 pair of training.

As an indicator composition, for example, you can use removable colored gels based on silicone, manufacturers are etelec (https://www.directindustry.com.ru/prod/etelec-italia-spa/product-119681-1904024.html), Megatraction (https : //www.medicalexpo.ru/prod/mentor/product-85083-569243.html), Advanced Antivibration Components (https://www.directindustry.com.ru/prod/advanced-antivibration-components/product-67639- 852877.html) or agarose from manufacturers such as Accuris (https://www.medicalexpo.ru/prod/accuris-instruments/product-128620-947077.html), Canvax (https://www.medicalexpo.ru/ prod / canvax / product-128474-946602.html), Bulldog Bio (https://www.medicalexpo.ru/prod/bulldog-bio-inc/product-128360-945257.html), Genetics (https: // www .medicalexpo.ru / prod / nippon-genetics / product-128292-944221.html), ATCGene (https://www.medicalexpo.ru/prod/actgene-inc/product-128125-947093.html), etc.

As one of the possible examples in Table 1, the authors cite their own recipe for the preparation of a removable colored indicator composition.

Table 1

Removable indicator composition

Component name, unit of measurement Quantity per 100 g of removable colored indicator composition Distilled water, ml fifty Carboxymethylcellulose, g 15.9-17.5 Glycerin, ml 5.8-6.5 Diethylene glycol, ml 4.5-5.5 Sodium hydroxide, g 10-11 Menthol (flavoring), ml 4-4.5 Preservatives (benzoic, lactic and citric acids in% ratio 27:42:31), ml 5.4-6 Dye (gum arabic, dextrin, gum, bovine bile, antiseptic in% ratio 15: 25: 13: 30: 17), ml 3.5-4

2. A colored removable indicator composition is applied to the surface of the cavities (see Fig. 5).

To increase the objectivity of assessing the correctness of the impact of the introduced tool, the composition can be applied in the form of a target with the highlighting of zones in different colors.

If necessary, real hard-to-remove foreign bodies can be added to the cavity.

3. Assemble a model of the airways.

4. Enter the tool into the layout (see figure 4).

The instrument is inserted into the cavities of the elements of the model through the nose 1 or the through hole 7 of the pharynx 2 or the through hole 8 of the larynx 3, for access to which the lower jaw 6 is turned downward.

For example, tweezers with a cotton swab or a cotton swab can act as a tool.

5. Carry out medical manipulation.

An example is the taking of upper respiratory tract swabs for diagnostic testing.

Since the layout is made without the ability to see the elements in a vertical section, the specialist learns to mechanistically feel the position and orientation of the instrument relative to the layout elements and develops his spatial imagination.

6. Disassemble the model of the airways.

7. Analyze the impact of the tool.

To do this, examine the tracer composition to be removed (see Fig. 8), and the depth, trajectory and location of the tool impact are estimated from the traces remaining on it.

When using a removable colored indicator composition, it visually remains on the instrument (see Figs. 6 and 7), which also makes it possible to understand which surfaces were touched by the instrument in the course of medical manipulation.

In the case of using a target, students' assessments can be ranked depending on the distance from its central part.

If the trace remains in the area (in the drawings it is colored in yellow) outside the target, this indicates an unsatisfactory assessment and violation of the exposure standards by the instrument.

8. Remove the indicator composition from the model (for example, manually) and clean or change the instrument.

Further, if necessary, make new ones or replace the previously used elements of the layout and the process is repeated.

The inventive model of the respiratory tract has a low cost, it can not only be reused, but also modified to consider various options for clinical cases.

This allows the specialist not to get used to the "average mannequin" and to be ready to constantly face the age characteristics and anatomical diversity of the human population, as it happens in practice.

In addition, it becomes possible to create individual models to prepare for complex surgical procedures. For example, tracheal intubation, used in artificial ventilation of the lungs in connection with acute respiratory failure in the development of pneumonia associated with infections of the respiratory tract [1-3, 7], in particular, associated with coronavirus infection COVID-19 [9, 14, 16 ].

At the same time, a specialist can independently, without the involvement of other experts (for example, a teacher), not only assess the correctness of the tool's impact, but also control the process of performing medical manipulations. After performing the manipulation, the specialist can see the remnants of the composition of various colors on the instrument, and, directly disassembling the layout, identify the areas and find out the exact location of the instrument's impact.

The use of transparent plastics for 3D printing provides additional detail and increased clarity of the manipulations. For example, in the case of applying a colored removable indicator composition to the elements of the model made of transparent plastic or when using additional cameras located in the cavity of the model.

The use of a removable indicator composition on various zones (“target areas”) of the inner side of the model allows practicing the skills of taking biota from certain areas without contamination by contacts with mucous membranes of other sections (“error areas”) of the respiratory tract, painted in other colors [5, 6 , 19]. Also, the use of this model is necessary in the training of medical specialists in the important manipulation of tracheal intubation, used in artificial ventilation of the lungs in connection with acute respiratory failure in the development of pneumonia associated with infections of the respiratory tract [1-3, 7], in particular, associated with coronavirus infection COVID -19 [9, 14, 16].

The claimed invention can be implemented in the processes of education and / or training of specialists and / or the development of automated systems for taking biological samples from various parts of the human respiratory tract.

Bibliography

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Claims (3)

1. A model of the human respiratory tract, containing elements that mimic body parts, characterized in that it contains in series and removably connected nose, pharynx, larynx and trachea, which are equipped with longitudinal cavities communicated with each other, while the pharynx is rigidly connected to the upper jaw, to which the lower jaw is connected with the possibility of rotation in the vertical plane, and in the walls of the pharynx and larynx from the side of the jaws and nose there are through holes communicated with the corresponding cavities, in addition, a removable indicator composition is applied on the surface of the cavities. 2. The model according to claim 1, characterized in that a colored removable indicator composition is used. 3. The layout according to claim 1, characterized in that the elements imitating parts of the human body are made using 3D printing.

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