RU2308220C2 - Method for detecting the pliability of prosthesis bed mucosa - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: the present innovation deals with the ways for diagnostics due to registering bioelectrical signals of the body and its parts and, also, to ways for studying the material due to detecting and studying magnetic leakage fields and could be applied in orthopedic stomatology for detecting the pliability of prosthesis bed mucosa. As a controlled parameter one should apply the index of bioelectromagnetic reactivity which should be measured in controlled points of prosthesis bed mucosa both before and during mechanical loading, after that it is necessary to obtain the difference in the values of corresponding measurements, moreover, if the difference of measured values is equal of above 1 one should characterize mucosa in the controlled point to be loose, and if the difference of the measured values is below 1 one should characterize mucosa to be dense, then one should calculate the value of mechanical coefficient of pliability (Cm) according to the following formula: Cm=((X₂-X₁)/M)×100(mm), where X₁, X₂ - the values of the indices of bioelectromagnetic reactivity in the controlled point of prosthesis bed mucosa both before and after the loading, correspondingly; M - the coefficient that takes into account the character of mucosal density which should be taken to be equal to 6.6 for the loose mucosa and 6.4 for the dense one. Application of the present innovation enables to increase the significance in detecting the pliability and simplify the method to increase the significance of the obtained information at measuring electromagnetic field in the point under studying.

EFFECT: higher accuracy of detection.

1 dwg, 1 ex, 1 tbl

Description

The invention relates to medicine, namely to methods and devices for diagnostics by recording bioelectric signals of an organism and its parts, as well as to methods and devices for studying material by detecting and studying magnetic fields of scattering, and can be used in orthopedic dentistry to determine mucosal compliance shell prosthetic bed.

A complete laminar prosthesis in the mouth perceives chewing pressure. Pressure is transmitted to the mucous membrane, it is compressed and then transforms the pressure on the bone. In the manufacture of the prosthesis, it is necessary to ensure that the prosthesis uniformly loads the mucous membrane of the prosthetic bed. This can be achieved only if initially the basis of the prosthesis will squeeze the mucous membrane in the area of the most compliant mucous membrane tissues, and then in the areas of less malleable and, finally, in the areas of almost mucous mucosa. Due to the variability of the compliance of the mucous membrane of the prosthetic bed, each time before the impression for the prosthesis is taken, the orthopedic practitioner faces the need to determine the compliance of the mucous membrane sections of the prosthetic bed.

The results of a patent search for a method for determining mucosal compliance of the prosthetic bed showed the following. A known method for determining the compliance of the mucous membrane of the prosthetic bed, according to which on the day of applying the removable prosthesis after its fixation, determine the overload zones of the mucous membrane of the prosthetic bed, using the color of the prosthetic bed with Schiller-Pisarev solution and 1% solution of toluidine blue (Definition of zones overload of the mucous membrane of the prosthetic bed after fixing the removable prosthesis // Dentistry, 1987, t.66, No. 6, p.55-57).

The disadvantage of this method is the complexity, since its implementation requires a ready-made prosthesis. In addition, since the prosthesis is not adjusted for compliance, then after it is fixed in the patient's mouth, the boundaries of the mucous membrane irritation can be slightly increased, which reduces the reliability of determining compliance zones.

Closest to the proposed is a method for determining the compliance of the mucous membrane of the prosthetic bed, described in the patent of the Russian Federation No. 2159595, A61C 9/00, 11/27/2000, in accordance with which the mucous membrane of the prosthetic bed is examined in ultraviolet rays. The mucous membrane of the oral cavity is able to luminesce or glow in ultraviolet rays. The nature of luminescence depends on the blood supply: the more intense the blood supply to the mucous membrane, the darker the shade of the glow. By the nature of the luminescence of the mucous membrane, areas with different compliance are determined. Then, a device for determining the compliance of the mucous membrane of the oral cavity determines a numerical value characterizing the degree of compliance of zones with different glows. The mucous membrane, luminescent in purple, had a compliance of 1.5-2 mm, gray-violet - 0.9-1.4 mm, gray - 0.5-0.9 mm, light gray - 0.3-0, 5 mm, white 0.1-0.2 mm.

A disadvantage of the known method for determining the mucosal compliance of the prosthetic bed of the method consists primarily in the fact that compliance zones are determined not by the functional state of the mucous membrane, but by the blood filling of its vessels, while the edematous mucosa can also have an increased blood supply to the vessels. That is, in the known method, the condition of the connective tissue - directly the tissue of the mucous membrane - is controlled indirectly, which introduces an error in the final results. In addition, analysis of the appearance of the mucous membrane in ultraviolet rays in determining the areas of compliance adds to the main source of error subjective error. The known method is difficult to perform, because it requires for each patient to perform complex operations: analysis of the appearance of the mucous membrane in ultraviolet rays; the need for additional determination using a special device of the numerical value of the degree of compliance.

Thus, the methods of determining the compliance of the mucous membrane of the prosthetic bed, revealed as a result of a patent search, do not ensure the achievement of a technical result, which consists in increasing the reliability of determining compliance and in simplifying the method.

The results of a patent search conducted in relation to a measuring inductor, which is used to implement the method for determining the compliance of the mucous membrane of the prosthetic bed, showed the following.

Known inductive proximity sensor Shpinova I.N., comprising a housing located in the housing an armored core of magnetic material and located in the plane of the core measuring inductance coil wound on the Central protrusion of the core (RU patent No. 1837153, G01B 7/00, H03K 18 / 945, 08/30/93.).

A disadvantage of the known device is that the electromagnetic field (EMF) of such a sensor contains mainly a magnetic component, the change of which is relatively uniform and the impact on such a field from outside (for example, the appearance of an object in the electromagnetic field) causes minor changes in its structure. This reduces the information content of the measurement results, leads to a decrease in the sensitivity of the sensor. As a result, the reliability of the information received is reduced.

Closest to the proposed is a measuring inductor containing a core of magnetic material with high magnetic permeability, and an inductor that is wound on the core and made multilayer. The thickness of the coil winding is close to or equal to the thickness of the core ring, and the length of the coil is close to or equal to the height of the core ring (RU, patent No. 2107964, H01F 17/04, 5/00, 03/27/98.).

A disadvantage of the known device is as follows. In the known device, the coil is wound around the circumference of the outer surface of the core, having the shape of a flat ring. As a result, for such a coil, the EMF is focused in the form of a sphere on the outer surface of the meter. This does not allow to minimize the area of the controlled area around the controlled point. As a result, when a biosignal is measured by a known coil at a controlled point, adjacent tissue sections are captured, which introduces into the measurement result information that is not related to the biosignal information at the studied point. This reduces the reliability of information about the EMF at the studied point.

Thus, the measuring inductance coils identified as a result of a patent search during implementation do not provide the achievement of a technical result consisting in increasing the reliability of the information obtained when measuring the electromagnetic field at the point under investigation.

The proposed method for determining the compliance of the mucous membrane of the prosthetic bed solves the problem of creating an appropriate method, the implementation of which ensures the achievement of a technical result, which consists in increasing the reliability of determining compliance and in simplifying the method.

The essence of the claimed method for determining the compliance of the mucous membrane of the prosthetic bed is that the bioelectromagnetic reactivity index is used as a controlled parameter, which is measured at the controlled points of the mucous membrane of the prosthetic bed before and during mechanical load, after which the difference in the values of the corresponding measurements is performed, while if the difference in the measured values is equal to or greater than 1, then the mucous membrane at the controlled point is characterized as loose, and if the difference is measured values less than 1, then the mucous membrane is characterized as dense, then the value of the mechanical compliance coefficient Km is calculated by the formula: Km = ((X2-X1) / M) × 100 (mm), where X1, X2 are the values of the bioelectromagnetic reactivity indices at the controlled point the mucous membrane of the prosthetic bed before and after the load, respectively; M - coefficient taking into account the nature of the density of the mucous membrane, which is taken equal to 6.6 for loose mucosa and equal to 6.4 for dense mucosa.

The technical result is achieved as follows.

It is known that receptor systems, in particular, on the surface of the mucous membrane, which have high reactivity, transform the effects of both positive and negative factors on them into nerve impulses. Nerve impulse reaches the central nervous system and serves as the basis for the formation of the body's response for the zone of action of the negative factor, forming a protective and adaptive reaction by changing the functional and morphological state of the tissues. This property of the body and allows you to use the result of mechanical action on it to determine the compliance of the mucous membrane of the prosthetic bed.

The basis of the proposed method for determining the compliance of the mucous membrane of the prosthetic bed is the use of the diagnostic properties of weak pulsed complex-modulated electromagnetic fields (IMS EMF) of low frequency natural background (geo- and heliomagnetic fields), interacting with the body as a whole and with individual organs. The physiological mechanism of diagnosis is based on the analysis of changes in the parameters of the induced ISM EMF directly in living tissues of organs. As a controlled parameter, the bioelectromagnetic reactivity index (BEMR) is used, the measurement of which is the property of living tissue to convert electromagnetic waves induced in it by external natural and artificial IMS EMFs of low frequency, which are most appropriate for a living organism. When exposed to a living organism (organ) of external ISM EMF of low frequency in tissues, a response low-frequency ISM EMF is induced in the form of electromagnetic oscillatory processes. But its spectral composition is significantly different from the spectral composition of the acting EMF. This is due to a well-defined functional and morphological state of living tissue. In addition, living tissue always has its own oscillatory processes due to metabolic processes and microcirculation, which is based on certain parameters of homeostasis (Sent-Dieri A. "Bioenergy" Theory of energy transfer. M .: Publishing house FIZMAT, 1960, p.3 .. .14; Better BC Essays on General Physiotherapy. - Minsk: Navuka i tehnika, 1994, p. 87-90). The response of living tissues to the biotropic parameters of the low-frequency EMF ISM is called bioelectromagnetic reactivity of tissues, and the measurement, which is based on the analysis of the appearance or disappearance of one or another harmonic interacting with the tissue, affects the EMF, called measurement of the BEMR index (V.I. Bankov and etc. "Low-frequency pulsed complex-modulated electromagnetic fields in medicine and biology", Ekaterinburg: Publishing house of Ural State University, 1992, p.33 ... 43).

The electromagnetic vibrations of living tissue, recorded by measuring the BEMR index, are the sum of the electromagnetic vibrations generated by living tissue cells. Since each living cell is a source of its own electromagnetic waves, the structure of which is determined by the biochemical processes taking place in it, the frequency characteristics of the cell’s own electromagnetic waves contain information about the biochemical processes taking place in it. Therefore, the parameters of electromagnetic vibrations of living tissue, which corresponds to the measured BEMP index, contain information on the functional and morphological state of the tissue at the cellular level (Sent-Dieri A. "Bioenergy" Theory of energy transfer. M: Publishing house FIZMAT, 1960, p. 3 ...; V.I. Bankov et al. "Low-frequency pulsed complex-modulated electromagnetic fields in medicine and biology", Ekaterinburg: Ural State University Publishing House, 1992, p. 33 ... 43; Ulashchik BC Essays on General Physiotherapy. - Minsk: Navuka i technology, 1994, p. 87-90). As a result, due to the fact that the bioelectromagnetic reactivity index is used as a controlled parameter, the method has high sensitivity, since it is possible to control the functional and morphological state of the tissue at the studied points before and during mechanical loading. This increases its information content of the research results, and therefore, the reliability of the claimed method.

It is known that the state of the inner layers of tissue is determined by homeostasis, while the receptor systems on the surface of the organ are highly reactive. The inner layers of the tissue, in addition, are more inert and their relaxation time is longer than the surface tissues ("Human Physiology" edited by Pokrovsky VM and Korotko GF, M .: Medicine, 1998). As a result, due to the fact that the proposed method measures BEMR indices at the studied points on the surface of the mucous membrane of the prosthetic bed, it is possible to reliably fix any changes in the functional and morphological state of the studied tissues, including during mechanical loading, which increases the sensitivity, and therefore, the information content and reliability of the proposed method.

In addition, the basis of the claimed method is to control the reaction of the mucous membrane of the prosthetic bed to mechanical stress, i.e. checking the functional and morphological state of the mucous membrane of the prosthetic bed under conditions of exposure to the future prosthesis: under mechanical stress. Due to the fact that in the proposed method the BEMR indices are measured at the studied points before and during the mechanical load, it is possible to comparatively evaluate the functional and morphological state of tissues in dynamics, i.e. it is possible to assess the response of mucosal tissues to mechanical stress. In the prototype, the compliance zones are determined without load on the blood supply to the vessels of the mucous membrane. Due to the fact that in the claimed method, the compliance of the mucous membrane of the prosthetic bed is determined under conditions close to the real conditions created by the prosthesis, an increase in the reliability of the method compared to the prototype is provided.

Moreover, due to the fact that the values of the BEMP index reflect the functional and morphological state of a particular test tissue, the claimed method is individual, allows you to take into account the individual characteristics of the patient’s body, which increases the reliability of the results of studies to determine the compliance of the mucous membrane of the prosthetic bed.

In addition, the operation of measuring the BEMR index itself is indifferent, does not require any additional effects on the body and does not have an irritating effect on the receptors of the mucous membrane and internal tissues of the prosthetic bed, which initiates a protective and adaptive reaction of the body. As a result, the studied tissues respond only to mechanical action, which provides the possibility of obtaining a reliable picture of the results of exposure, increases the information content and reliability of the proposed method.

Since the method allows you to form any array of the studied points necessary to obtain a reliable result, this provides complete information for reliable determination of the compliance of the mucous membrane. The selected array of the studied points, as well as the aggregate information from the selected array of the studied points, provide complete information on the functional and morphological state of the mucous membrane of the prosthetic bed before and during mechanical exposure. This increases the information content and reliability of the proposed method.

Since the values of the BEMP index measured at the studied points of living tissue (organ) correspond to the functional and morphological state of the tissues at these points before and during mechanical loading (X1, X2), this makes it possible to differentiate the measurement results. In turn, the differentiation of the measurement results of the BEMR indices provides the possibility of mathematical operation, namely, it provides the possibility of comparing the functional and morphological state of the mucous membrane at the point under study by performing the difference of the corresponding measured values of the BEMR indices. Moreover, if the difference in the measured values is equal to or greater than 10, then the mucous membrane at the controlled point is characterized as loose, and if the difference in the measured values is less than 1, then the mucous membrane is characterized as dense.

A quantitative criterion of 1 is the result of processing statistical data.

Using for the quantitative assessment of compliance the mechanical compliance coefficient Km allows you to translate the results of measuring the bioelectric signal into a mechanical parameter and as a result obtain quantitative information about the compliance of the mucous membrane of the prosthetic bed in the area of the point under investigation in linear units. The calculation of the degree of compliance using a mathematical formula eliminates subjective error, which increases the reliability of the method.

The mechanical compliance coefficient Km is determined by the formula: Km = ((X2-X1) / M) × 100 (mm), where X1, X2 are the values of the bioelectromagnetic reactivity indices at the controlled point of the mucous membrane of the prosthetic bed before and during the mechanical load, respectively; M - coefficient taking into account the nature of the density of the mucous membrane, which is taken equal to 6.6 for loose mucosa and equal to 6.4 for dense mucosa.

The mathematical formula is obtained as a result of computer processing of research results. The quantitative criteria used in the mathematical formula are also obtained empirically by processing statistical data.

In the proposed method, all measurements of the BEMP index are carried out on the surface of the mucous membrane of the prosthetic bed at easily accessible points by simply applying the sensor to the points being studied, and mathematical calculations are simple. As a result of using the BEMP index as a controlled parameter in the claimed method for determining the mucosal compliance of the prosthetic bed and using the calculation formulas for determining the compliance coefficient, the claimed method simplifies the claimed method, as well as completely eliminates the participation of the subjective factor in the research results, which increases the reliability way.

Thus, from the foregoing, it follows that the claimed method for determining the compliance of the mucous membrane of the prosthetic bed during implementation ensures the achievement of a technical result, which consists in increasing the reliability of determining compliance and in simplifying the method.

The present invention, "Measuring inductor" used to implement the method for determining the compliance of the mucous membrane of the prosthetic bed, solves the problem of creating a measuring inductor, the implementation of which ensures the achievement of the technical result, which consists in increasing the reliability of the information obtained when measuring the electromagnetic field at the point being studied.

The essence of the invention "Measuring inductor" is that in a measuring inductor containing a core of magnetic material with high magnetic permeability, and an inductor that is wound on the core and made multilayer, new is that the core is a cylindrical rod, turning into a truncated cone, while on the cylindrical end of the rod the coil of the inductance coil is placed, and the end of the cone-shaped part of the rod is made straight or curved angle d, while in the redistribution error meter rod length is five maximum diameter rod, coil length is equal to the maximum diameter of the rod, and the thickness of the coil winding - maximum diameter of 0.4 bar. The technical result is achieved as follows. Due to the fact that the winding of the inductor is located on the cylindrical end of the rod, the length of the coil is equal to the maximum diameter of the rod, and the thickness of the coil is 0.4 maximum diameter of the rod induced in the coil of the EMF has an elongated shape, externally pressed against the coil of the coil, and concentrated inside the coil .

It is known that a change in the EMF of the magnetic component of the core field leads to a change in the electrical component of the field of the winding of the inductor. When the core of the coil interacts with the object under investigation, the magnetic component of the electromagnetic field changes. Due to the fact that the EMF field is concentrated inside the coil, and the core is made of a material with high magnetic permeability, which allows working with weak magnetic fields by reducing hesteresis, any changes in the core magnetic field lead to noticeable changes in the electric component of the coil EMF, which increases the reliability of the information when measuring EMF at a point.

Thus, the action of the measuring coil is based on a change in the magnetic component formed by the MP field of the core during the interaction of the core of the coil with the EMF of the object of study. A change in the magnetic component causes a change in the electric current, which is equivalent to a change in the capacitive component in the complex resistance of the equivalent oscillatory circuit of the inductor, which has a well-defined resonant resistance. Since the inductor is multi-layered, which increases its own capacitance and reduces the quality factor of the inductor, this contributes to the occurrence of free oscillations in the equivalent oscillatory circuit of the inductor even when fixing a weak EMF when interacting with the studied electromagnetic field sources. As a result, the sensitivity of the measuring coil and the information content of the obtained research results, and therefore the reliability, are increased.

In addition, the equivalent circuit of a multilayer inductor in a roughened form is a parallel oscillatory LC circuit, the electric oscillations in which have the form of damped periodic oscillations, which have a polyharmonic spectrum. The presence of a large number of harmonic components makes it possible to record even minor changes in the parameters of the oscillatory circuit of the inductor, which increases both the sensitivity of the device and the information content and reliability of the research results.

The implementation of the rod in the form of a cylinder turning into a truncated cone, as well as the choice of the design parameters of the inductor, in which the EMF has an elongated shape and maximally inside the coil, makes it possible to optimally focus the magnetic component of the field at the point of interest in the object, i.e. allows you to minimize the area of the controlled area around the investigated point. This ensures good distinguishability of the measurement results, confident discretization of the measurement results, and therefore increases the reliability of information about changes in the parameters of the electromagnetic field at the studied point.

The choice of the length of the rod equal to the five maximum diameters of the rod is optimal and provides maximum sensitivity to a change in the magnetic component of the field. This always ensures a constant distance between the controlled surface of the object and the winding of the inductor. The coil also receives an EM signal from the point under investigation. Since the shape of the EMF induced in the coil is elongated, the distance between the controlled surface of the object and the winding of the inductor is constant, and measured by the area of the bar cone, unlike the prototype, the measuring coil receives a signal from a practically point source, which minimizes the area of the controlled zone around the point under investigation.

The execution of the end of the cone-shaped part of the bar straight or bent at an angle ensures access directly to the object of study, even in hard-to-reach points. In this case, the coil is always at the same distance from the surface of the object under study when the pin is inserted in the point under investigation, which increases the reliability of the information received on the change in the EMF parameters at the point under investigation.

Since the tolerance on the deviation of the geometric dimensions of the parts of the device is determined within the error of the measuring device, when measuring with the same device the error is the same, which always allows you to fulfill the condition: the length of the rod is five maximum diameters of the rod, the length of the coil is the maximum diameter of the rod, and the thickness of the winding coils - 0.4 of the maximum diameter of the rod, and therefore, allows you to form the desired shape of the electromagnetic field, which ensures the reliability of the result in research.

Thus, the claimed measuring inductance coil used to implement the method for determining the compliance of the mucous membrane of the prosthetic bed, when implemented, ensures the achievement of the technical result, which consists in increasing the reliability of the information obtained when measuring the electromagnetic field at the point under investigation.

The method for determining the compliance of the mucous membrane of the prosthetic bed is implemented as follows. As a controlled parameter, the bioelectromagnetic reactivity index is used, which is measured at controlled points in the mucous membrane of the prosthetic bed before and during mechanical loading. Then perform the difference in the values of the corresponding measurements. Moreover, if the difference in the measured values is equal to or greater than 1, then the mucous membrane at the controlled point is characterized as loose, and if the difference in the measured values is less than 1, then the mucous membrane is characterized as dense. Then, the value of the mechanical compliance coefficient Km is calculated by the formula: Km = ((X2-X1) / M) × 100 (mm), where X1, X2 are the values of the bioelectromagnetic reactivity indices at the controlled point of the mucous membrane of the prosthetic bed before and after the load, respectively; M - coefficient taking into account the nature of the density of the mucous membrane, which is taken equal to 6.6 for loose mucosa and equal to 6.4 for dense mucosa.

To implement the method for determining the compliance of the mucous membrane of the prosthetic bed, the claimed measuring inductance coil is used.

On figa shows a measuring inductance coil with a straight line, and on figb - with a core bent at an angle (vertical section). Since the coil is actually small in size, for the convenience of describing its design, the coil is shown exaggerated without respecting the proportions according to the claims.

The measuring inductor contains a core 1 of a magnetic material with high magnetic permeability and an inductor 2 with leads 3 and 4, which is wound on the core 1 and made multilayer. The core 1 is a cylindrical rod turning into a truncated cone, while the coil 5 of the inductor 2 is placed on the cylindrical end of the rod, and the end 6 of the cone-shaped part of the rod is made straight (Fig. 1a) or bent at an angle (Fig. 1b). At the same time, in the range of the error of the measuring device, the bar length is five maximum bar diameters, the coil length is equal to the maximum bar diameter, and the coil winding thickness is 0.4 of the maximum bar diameter.

To implement the method for determining the compliance of the mucous membrane of the prosthetic bed, a measuring inductance coil was made with geometric dimensions: maximum rod diameter 5 mm, rod length 25, coil length 5 mm, and coil winding thickness 2 mm. The bending angle of the end of the cone-shaped part of the bar 30 °. The diameter of the working surface of the end of the cone-shaped part of the bar is 2 mm, which, as experience has shown, is optimal. The diameter of the winding wire is determined by the electrical parameters of the device with which the sensor works. In our case, the diameter of the winding wire was 0.18 mm.

The method for determining the compliance of the mucous membrane of the prosthetic bed can be implemented by means of a device for determining the bioelectromagnetic reactivity of living organ tissues, a block diagram of which is described in the literature: V.I. and others. "Low-frequency pulsed complex-modulated fields in medicine and biology", Ekaterinburg: Ural University Press, 1992, p. 39, Fig. 8.

The device contains a sensor that is applied to the surface of the tissue under study, a balanced demodulator, a pulsed complex modulated electromagnetic field generator (ISM EMF), a corrector, a detector, an amplifier, an analog-to-digital converter, and an indicating device. As a sensor in the device, the claimed measuring inductance coil can be used.,

The sensor is part of a measuring open oscillatory circuit tuned to a pulsed complex-modulated mode of operation. In addition to the sensor, the measuring oscillatory circuit includes an ISM EMF generator, a balanced demodulator, a detector, and a corrector. The vibrational circuit is excited at the moment the sensor touches the surface of living tissue.

Currently, the device is implemented in the expert diagnostic tool “Lira-100”, developed and manufactured in the Department of Medical Cybernetics of the Central Scientific Research Laboratory and the Department of Normal Physiology of the Ural State Academy. The device has been regularly demonstrated since 1997 at the All-Russian Exhibition of Manufacturers of Medical Equipment and Medical Devices and has been repeatedly awarded with Diplomas of the Ministry of Health and Social Development of the Region and the Russian Federation. The device is protected by patents of the Russian Federation: patent No. 2107964, priority 28.04.95 .; No. 96121429/07 (028062), priority 04/28/95 .; patent No. 2080820, priority 01.08.94.

The device contains an EMF sensor, a converter, an amplifier filter, a microprocessor, an analog-to-digital converter, and a recorder-indicator. As the EMF sensor, the claimed measuring inductance coil can be used. The sensor provides registration of EMF of living tissues in the form of relative values of the BEMR indices, which are displayed on the indicator screen.

To implement the method, the patient is seated in a chair and invited to open his mouth. Outlined on the mucous membrane of the future prosthetic bed controlled points to determine the compliance of the mucous membrane. The end 6 of the cone-shaped part of the core rod 1 of the measuring inductance coil 2 is applied at a controlled point on the surface of the mucous membrane without pressing (close to touch), so as not to spontaneously increase local microcirculation. The contact of the core 1 of the coil 2 with the surface of living tissue leads to a change in the magnetic component formed by the magnetic field of the core. In this case, capacitive resistance is introduced into the equivalent oscillatory circuit of the inductor 2, which has a well-defined resonant resistance, which leads to the excitation of electrical vibrations in the equivalent circuit of the coil that are adequate to the fixed electromagnetic field formed by the mucous membrane at a controlled point. The electrical vibrations generated in the coil 2 are recorded by the measuring device.

Without removing the end 6 of the cone-shaped part of the bar from the studied point, the result of measuring the BEMR index is recorded. After that, the end 6 of the cone-shaped part of the rod is pressed tightly against the surface of the mucous membrane, simulating the pressure of the future prosthesis. At the same time, the functional and morphological state of the tissues of the mucous membrane change at the point under study, and therefore, as shown above, the parameters of the formed EMF change. After the BEMR index is measured a second time, the measurement result is fixed. The difference in the values of the respective measurements is performed. If the difference in the measured values is equal to or greater than 1, then the mucous membrane at a controlled point is characterized as loose. If the difference in the measured values is less than 1, then the mucous membrane is characterized as dense.

Then determine the degree of compliance of the mucous membrane in terms of length. For this, the value of the mechanical compliance coefficient Km is calculated by the formula: Km = ((X2-X1) / M) × 100 (mm), where X1, X2 are the values of the bioelectromagnetic reactivity indices at the controlled point of the mucous membrane of the prosthetic bed before and after the load, respectively; M - coefficient taking into account the nature of the density of the mucous membrane, which is taken equal to 6.6 for loose mucosa and equal to 6.4 for dense mucosa.

Gradually examining the oral mucosa, determine the compliance zones, which are taken into account in the manufacture of the future prosthesis.

Example. 1. The patient Sosnovsky V.I. He turned about the manufacture of a complete removable denture on the upper jaw.

Determinations of the nature and measurement of compliance of the oral mucosa in the upper jaw at seven points were made: 1 - in the region of the right pterygo-maxillary notch; 2 - along the line "A" in the middle of the distance between the wing-maxillary notch and the middle line of the upper jaw on the right; 3 - along the line "A" in the middle of the distance between the wing-maxillary notch and the median line of the upper jaw on the left; 4 - on top of the alveolar process in the region of the 25 tooth; 5 - in the middle of the sagittal suture; 6 - at the place of transition of the alveolar ridge to the hard palate (buffer zone) in the projection of 16 teeth; on top of the alveolar bone in the region of the 15 tooth.

Measurements of the BEMR indices at controlled points were carried out before and during mechanical loading by adjusting the force of pressing the end of the cone-shaped part of the measuring coil rod to the surface of the mucous membrane. The nature of the mucous membrane was determined by the difference in the measured values: with a difference equal to or greater than 1, loose; with a difference less than 1 - dense.

Compliance was calculated by the formula: Km = ((X2-X1) / M) × 100 (mm), where Km is the value of compliance in mm; X1, X2 - values of the bioelectromagnetic reactivity indices at the controlled point of the mucous membrane of the prosthetic bed before and after the load, respectively; M - coefficient taking into account the nature of the density of the mucous membrane, which is taken equal to 6.6 for loose mucosa and equal to 6.4 for dense mucosa.

The measurement results of the BEMR indices and determination of compliance of the oral mucosa are summarized in table.

Point number BEMP index without pressure BEMP index with pressure The nature of the mucosa Compliance
(mm) one 1,506 1,600 loose 1,42424 2 2,141 2,376 loose 3,5606 3 2,306 2,400 loose 1,42424 four 1,812 1,835 loose 0.34848 5 1,835 1,859 loose 0.36363 6 2,259 2,471 loose 3,21212 7 2,353 2,376 loose 0.34848

The patient was made a full removable denture on the upper jaw. The result of fitting the prosthesis is satisfactory.

Claims (1)

A method for determining the compliance of the mucous membrane of the prosthetic bed, characterized in that the bioelectromagnetic reactivity index is used as a controlled parameter, which is measured at the controlled points of the mucous membrane of the prosthetic bed before and during mechanical loading, after which the difference in the values of the corresponding measurements is performed, if the difference the measured values is equal to or greater than 1, then the mucous membrane at the controlled point is characterized as loose, and if the difference in the measured values is less than 1, then the mucous membrane is characterized as dense, then the value of the mechanical compliance coefficient Km is calculated by the formula Km = ((X2-X1) / M) · 100 (mm), where X1, X2 are the values of the bioelectromagnetic reactivity indices at the controlled point of the mucous membrane of the prosthetic bed up to and after loading, respectively; M - coefficient taking into account the nature of the density of the mucous membrane, which is taken equal to 6.6 for loose mucosa and equal to 6.4 for dense mucosa.