RU2212185C1 - Method for measuring galvanic processes in oral cavity - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves measuring DC value flowing via metal structures available in oral cavity. Electric current intensity is measured in direct and reversed connection polarity with respect to power supply source of galvanic system under study. System impedance is calculated as circuit resistance mean value in two measurements. The value is interpreted in terms of galvanic processes intensity in oral cavity. The oral cavity area under study is preliminarily dried. EFFECT: high accuracy and reliability of measurements. 3 dwg

Description

 The invention relates to problems in the diagnosis of galvanic processes in the oral cavity, in particular the measurement of pathologies due to the presence of metallic inclusions in the oral cavity.

 In dentistry, various materials are used for the manufacture of dental crowns and bridges, the presence of which in the electrolytic environment (in particular, saliva) of the oral cavity leads to the occurrence of galvanic processes. As a result of the interaction of metal dentures and fillings, some patients develop pathological "intolerance to metal inclusions in the oral cavity." There are three main types of such pathological effects on the human body: toxic-chemical, electro-galvanic and allergic.

 The clinical picture is characterized by the following symptoms: a change in taste (a taste of metal, salt, bitterness), paresthesia, glossalgia, hypo- or hypersalivation, a feeling of "passing current" when metal objects are introduced into the oral cavity. The following reactive manifestations are possible: rhinitis, urticaria, dermatitis, eczema.

 The most objective characteristic for galvanic processes is the magnitude of the current flowing in a galvanic system. In the oral cavity, such a system is formed from metal inclusions connected by a conductor, which are the tissues of the oral cavity, direct contact of structures or a metal tool between them.

An equivalent circuit of such a system is shown in FIG. The magnitude of the current for such a circuit is determined by the equation
I = E / (R _TK + R _BH ),
where I is the current in the system,
E - EMF of a galvanic cell,
R _TK is the resistance of the tissues of the oral cavity,
R _BH is the internal resistance of a galvanic cell formed by metallic inclusions in the oral cavity.

A known method for detecting electrochemical processes in the oral cavity, in which measure the potential difference (RP) between metal structures or between them and the mucous membrane of the oral cavity. For this, a voltage measuring device is connected in parallel with R _TK (I. Rubezhova, “Phenomena of galvanosis in the oral cavity and their treatment. Methodical manual for doctors” L., 1972). However, the severity of pathological changes is not always proportional to the value of RP. It was believed that with RP not exceeding 100 mV, pathological manifestations are insignificant, however, there are cases when patients suffered from severe galvanism and with a lower value of RP.

In the same work, I. Rubezhova Another method for assessing electrochemical processes is described, which consists in directly measuring the currents of a galvanic system using a low-resistance microammeter connected in parallel with R _TK .

 This method also has significant disadvantages. Connecting a low-resistance device shunts the resistance of the tissues of the oral cavity and leads to a distortion of the measurement results.

 In the patent of the Russian Federation 2151546, A 61 B 5/05, dated 11.10. In 99, a method for the diagnosis of galvanosis was described, which, according to the authors, improves the information content and reliability of measurements. The essence of the invention lies in the fact that the controlled parameter is measured in the studied area of the oral mucosa, the measurement result is compared with the control value, and galvanosis is diagnosed by the results of the comparison. As a controlled parameter in this invention, the selected index of biomagnetic reactivity due to the electrical component of electromagnetic waves induced in the tissue by electromagnetic fields as a result of its biomagnetic activity. As a control value take the readings of the measuring device in saline. Galvanosis is diagnosed when the controlled parameter is 30% higher than the control value.

 However, in practice, this method turned out to be quite complicated and not reliable enough.

 The closest solution to the proposed can be considered the method described in the above work I. Rubezhova and consisting in measuring the current included in the galvanic system of the oral cavity.

 The objective of the proposed solution is to increase the reliability of the results of measuring galvanic processes in the oral cavity.

 To solve this problem, some improvements have been made to the method for measuring galvanic processes in the oral cavity, based on measuring the magnitude of the direct current flowing through metal structures in the oral cavity. Measurements are made with direct and reverse polarity of the connection of the investigated galvanic system to the voltage source. Next, calculate the total internal resistance (impedance) of the galvanic circuit at constant current as the average value of the circuit resistance in two measurements.

 This eliminates the influence of the internal EMF of the galvanic cell on the final result, which improves the reliability of the measurements.

The impedance Z contains a reactive component, which occurs in a real circuit due to the presence of double electric layers at the interface between the electrode and electrolyte, interelectrode capacitance, dielectric capacitance on the electrodes, etc. Since the measurements are made with direct current, only the active components of the resistances included in the equivalent circuit are taken into account (Fig. 2). Thus, the impedance Z contains only R _TK and R _BH , which determine the current in the system.

 An important difference of the proposed method from the prototype is a significant reduction in distortion introduced by the measuring circuit into the investigated galvanic system.

To eliminate the influence of the internal EMF of the galvanic cell on the result in two stages, the measurements of the ratio of the voltage drop across the measuring resistance are performed. To calculate the impedance, the voltage source current U flowing through the system is measured. This current is equal to R _un to the value of this resistance. First, the current flowing through the galvanic system is measured when a voltage source U is connected to it. This current I 'is equal to the ratio of the voltage drop U at the measuring resistance R _TK . At the second stage, the current I 'from the voltage source U is determined with the reverse polarity of its connection.

The impedance value is determined as the average value of the measurement results with opposite polarity and is calculated by the formula
Z = 2U / (I '+ I ").

 Such a sequence of measurements eliminates the influence of the intrinsic EMF of the measured object on the measurement result.

 Figure 3 shows a block diagram of a device for implementing the proposed method.

 The device comprises a voltage source 1, a voltage control sensor 2 connected in parallel to the source 1, a polarity switch 3 connected in parallel with other outputs of the source 1, an ammeter 4 connected to the output of the switch. Electrodes 5 and 6 are connected to the output of the ammeter in the form of probes, which are connected to the dental structures.

 Measurements are made as follows.

 Turn on the power of 1 measuring device. Using the sensor 2 measure the magnitude of the voltage. If the voltage value corresponds to the nominal, proceed to the measurements.

 Set the selected voltage polarity using switch 3.

 Touch the ends of the probes 5 and 6 to the specified points of the studied dental structures. In this case, contact of the probes with moistened areas of the oral cavity should be avoided, as this can short circuit and distort the measurement results. To exclude such contact, the oral cavity in the study area is pre-dried.

 After contact is established, the value of the current flowing in the circuit is measured.

 Next, with the help of switch 3, the polarity of the voltage supplied to the probes 5 and 6 is changed, and the current in the circuit is re-measured with a new polarity.

The resistance of the measured section of the circuit is calculated as the average value of the resistance Z, measured at two different polarities
Z = 2U / (I '+ I "),
where U is the voltage of the power source,
I 'is the magnitude of the current in the measuring circuit at the first polarity of the voltage across the probes,
I "- the magnitude of the current in the measuring circuit with a second voltage polarity on the probes.

The resulting ratio allows us to draw the following practical conclusions:
- an increase in the impedance of the system leads to a decrease in the galvanic currents flowing in it; this reduction can be achieved with equal efficiency by increasing R _TK or R _BH ;
- reducing the magnitude of the current can also be achieved by reducing the potential difference between the metal elements of the system.

 It is possible to achieve a reduction in the potential difference by selecting materials of metal structures in the oral cavity, as well as by changing various factors affecting the emf (the hydrogen index of the oral medium, the conditions for aeration of the electrodes, etc.). Obviously, this way is ineffective in practical terms.

More promising is an increase in the internal resistance of the system, i.e., impedance. This can be achieved by applying a dielectric layer to the metal surface of the metal elements of the dentures. Due to the isolation of the surface of metal structures from the electrolyte (saliva), both the internal resistance of the galvanic cell R _BH and the resistance of the circuit through which this current is closed, i.e. oral tissue resistance R _TK .

 The proposed method is simple to implement and can be implemented on standard equipment.

Claims (1)

 A method for measuring galvanic processes in the oral cavity, which consists in measuring the magnitude of the direct current flowing through metal structures in the oral cavity, characterized in that the current measurements are carried out with direct reverse polarity of the test system to the voltage and power source, and the system impedance is calculated as the average value circuit resistance in two measurements, the value of which characterizes the level of galvanic processes in the oral cavity, while the oral cavity in the studied area is pre itelno osushivayut.

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