RU2176491C2 - Stomatologic explorer - Google Patents

Abstract

FIELD: medical equipment used in stomatology for diagnosis of caries. SUBSTANCE: stomatologic explorer has metal rod with point and handle secured with acoustic signal receiver. Receiver output is connected with frequency filter whose pass band frequency is above 1000 Hz. Input of indication unit with indicator is connected to output of frequency filter, and output of explorer serves as output of indication unit. EFFECT: objective estimation of mechanical properties of dentin and higher accuracy of diagnosis results. 13 cl, 6 dwg

Description

 The invention relates to medical equipment and can be used in dentistry in the diagnosis of caries.

 Known dental probe, consisting of a thin rod with a handle (see, for example, US patent N 4886454, publ. 12.12.89 and US patent N 5725373, publ. 10.03.98). Such devices are used in dentistry to determine the condition of gums, periodontal, etc. The main disadvantage of this device is the impossibility of its use in the diagnosis of caries due to the fact that the thin rod is made of soft plastic.

 Known dental probe, consisting of a thin metal rod with a handle (Encyclopedic Dictionary of Medical Terms, edited by Ac. B.V. Petrovsky, Small Soviet Encyclopedia, 1982, v. 1, p. 395). The main disadvantage of this device is the low reliability of determining the degree of carious lesion of dentin. Caries can be diagnosed using such a probe as follows: the doctor, moving the tip of the probe rod along the surface of the so-called pigmented dentin and pressing it with force to the surface, on the basis of subjective analysis of its visual, tactile and auditory sensations, evaluates the dentin hardness, which is directly related with the degree of his carious lesion. As a rule, the darker the color and the lower the hardness of the dentin, the greater the degree of carious lesion. The subjective nature of the diagnosis determines the main disadvantage of known dental probes, namely the high probability of making an incorrect diagnosis of the state of dental tissue.

 Closest to the proposed device and adopted for the prototype is a device for ultrasonic detection of dental caries (UK Application PCT W095 / 04506 publ. 02.16.95) containing a metal rod with a tip, an ultrasound transmitter and receiver, an electric power source, a processor and a display. Diagnosis of caries and other tooth abnormalities occurs according to the parameters of the ultrasound signal reflected from the interface (enamel dentin, dentin pulp) and from defects in the tooth. At the same time, the possibility of close contact of the ultrasound-emitting surface of the device and the tooth surface is provided. This detection method is quite effective. However, this device is very complicated and expensive. In addition, the detection result depends on the sound resistance of the contact layer, which inevitably arises between the ultrasound-emitting surface of the device and the tooth surface, which in turn depends on the relief of the tooth and the force with which the emitting area is pressed against the tooth. Control of the magnitude of these parameters in the device is not provided, which reduces the reliability of detection.

 The problem to which this invention is directed, is to increase the reliability of the result and the speed of diagnosis of dental dentin without a significant increase in the cost of the procedure.

 This problem is solved by achieving a technical result, which consists in an additional objective assessment of the mechanical properties of dentin, manifested in the interaction of the tip of the probe rod with the surface of the tissue under study.

 The indicated technical result is achieved in that in a dental probe containing a thin metal rod with a point and a handle fastened to an acoustic signal receiver, an indication unit including an indicator, the output of the acoustic signal receiver is connected to the input of the frequency filter with a passband of more than 10,000 Hz, while the input of the display unit is connected to the output of the frequency filter, and the output is the output of the probe.

 An electronic key and an electric power source are included in the display unit, the control input of the electronic key being the input of the indicating unit, and the indicator connected to the power source through the output of the electronic key.

 The display unit may include a series-connected electrically coupled amplitude selector, an indicator, as well as an electric power source connected to the input of the amplitude selector, and the indicator is connected to the output of the amplitude selector.

 Additionally, the output of the acoustic signal receiver can be connected to a second frequency filter in series with a passband of 1000 - 6000 Hz, a second amplitude selector and a second indicator of the display unit, while the electric power source is additionally connected to the power input of the second amplitude selector.

 Amplitude selectors can be made in the form of comparators, and their second inputs are electrically connected to an electric power source through voltage regulators.

 The probe handle may have a cavity, while the acoustic signal receiver is located inside this cavity in the place of attachment of the handle and a thin metal rod.

 An acoustic signal receiver may be located on the surface of the dental probe.

 The receiver of acoustic signals can be made in the form of a microphone or a piezoelectric element.

 The indicator can be made in the form of an LED or a liquid crystal display.

 The dental probe may further comprise a sound duct, the input of which is acoustically coupled to the tip of the probe shaft, and the output is connected to the input of the acoustic signal receiver. In addition, the tip of the probe rod may be further provided with a vibrator.

 Numerous experimental studies of the authors revealed differences in the spectral composition of sound signals that arise when the tip of the probe shaft moves along the dentin surface with pressing force, depending on the degree of its carious lesion. So in the spectrum of the acoustic signal that occurs when the probe tip moves along the intact dentin, there are mainly vibrations with a frequency in the range of 500-2000 Hz with a maximum in the region of 1000 Hz. In the spectrum of the signal received from carious dentin, along with vibrations at frequencies of 1000 Hz and 6000 Hz with an amplitude of 3-4 times the amplitude of vibrations for intact dentin, there is a higher frequency up to 17 kHz with a maximum in the region of 13 kHz. In the study of intact dentin, acoustic signals with a frequency of more than 10 kHz are practically absent.

 The invention is illustrated by diagrams of electrical signals and circuits shown in FIG. 1-6.

 The Fourier spectra of the acoustic signals obtained in the cases described above are shown in FIG. 1.

 In FIG. 2 is a schematic diagram of a dental probe.

 In FIG. 3 is a functional diagram of a dental probe with an indication unit including an indicator, an electronic key and an electric power source.

 In FIG. 4 is a functional diagram of a probe with an indication unit including an indicator, an amplitude selector, and an electric power source.

 In FIG. 5 is a functional diagram of a dental probe, further comprising a second frequency filter with a passband of 1000-6000 Hz, a second amplitude selector and a second indicator of the display unit.

 In FIG. 6 shows a design drawing of a dental probe containing an acoustic vibration receiver located inside the handle cavity in the place of its attachment to a thin metal rod, sound duct and vibrator.

 The essence of the invention consists in the implementation of a technical solution that allows the registration and analysis of the amplitude and frequency spectrum of the acoustic signal that occurs when moving with pressing force the tip of the dental probe along the investigated surface of the dentin of a human tooth. In the physical phenomenon discovered and investigated by the inventors, the dependence of the above characteristics of the acoustic signal on the degree of carious damage of dentin, namely, the presence of high-frequency (over 10 kHz) components of the acoustic signal that occurs during the diagnosis of dentine affected by caries, and in the absence of such components in the sound signal spectrum from intact dentin is the physical essence of the invention. As a result of numerous laboratory studies, the authors confirmed the effect of increasing the reliability of the diagnosis of dentin caries using the inventive device. Experimentally proved is also an increase in the reliability of the diagnosis of dentin caries in the early stages of its development when analyzing the amplitude of the sound signal that occurs when the tip of the dental probe moves with the clamping force along the studied surface of the human tooth dentin in the frequency range from 1 to 6 kHz. In particular, the authors showed that the amplitude of the acoustic signal in this range of the spectrum for carious dentin is several times higher than the amplitude of the sound signal in the same range for intact dentin. The spectral composition of the signal from intact dentin is shown in FIG. 1 a, and from carious in FIG. 1 b

 The inventive device (Fig. 2) consists of a metal rod 1 with a point and a handle 2 fastened to an acoustic signal receiver 3, made in the form of a microphone or a piezoelectric element and located near the tip of the probe. The output of the receiver 3 is electrically connected to the input of the frequency filter 4, transmitting electrical signals with a frequency of more than 10000 Hz. The output of the filter 4 is electrically connected to the input of the display unit 5, which includes an indicator 6, made, for example, in the form of an LED or a liquid crystal display. Display unit 5, in addition to indicator 6, may contain an electronic key 7 (Fig. 3), made, for example, in the form of a transistor, and an electric power supply 8. In this case, the output of the frequency filter 4 is connected to the input of the electronic key 7, which can serve as the base of the transistor , and indicator 6 is included in its emitter-collector circuit. The electric power source 8 can be connected through a switch to the power input of the amplitude selector 9 (Fig. 4). In this case, the output of the frequency filter 4 is connected to the input of the amplitude selector 9, and the indicator 6 is connected to the output of the amplitude selector 9. The amplitude selector 9 is made, for example, in the form of a comparator, to the input of which the output of the filter 4 is connected, and as the power input of the amplitude selector 9 serves as a second input of the comparator, electrically connected to a power source 8, for example, through a voltage regulator.

 In FIG. 5 shows a diagram of the proposed dental probe, which allows for increased reliability in determining the degree of carious lesion of dentin. To this end, an additional signal path from carious dentin is connected to the output of the acoustic receiver 3, consisting of a second frequency filter 10 with a passband of 1000 - 6000 Hz, a second amplitude selector 11 and a second indicator 12. In contrast to the amplitude selector 9, the amplitude selector 11 must be set to select a signal with a high amplitude value.

 The movements necessary for the operation of the dental probe can be carried out not only by the hand of a doctor, but also by means of a vibrator 13 (Fig. 6), which is equipped with the tip of the probe. This is especially useful if it is necessary to diagnose areas of dentin surface of small area, as well as hard-to-reach areas of dental tissue. For this purpose, it is possible to locate the acoustic signal receiver 3 inside the cavity 14 of the handle 2 in the place of its attachment to the thin metal rod 1. In this case, the probe can be provided with a sound pipe 5 from the rod 1 to the acoustic signal receiver 3.

 The device operates as follows. The electrical signal from the output of the acoustic signal receiver 3, resulting from the movement with the pressing force of the tip of the metal rod 1 of the dental probe along the studied surface of the dentin, is fed to the input of the frequency filter 4, mainly transmitting electrical signals with a frequency of more than 10000 Hz. The presence of a signal at the output of the frequency filter 4 clearly indicates the presence of high-frequency components in the spectrum of the acoustic signal, which means that the probe tip moves along the surface of the carious dentin. In this case, the signal from the output of the frequency filter 4 is fed to the input of the display unit 5, and then to the indicator 6. As the input of the display unit 5, the base of the transistor or the input of the comparator can serve. The presence of a signal based on the transistor ensures the flow of current in the emitter-collector circuit of the transistor and displays the output signal on indicator 6. The absence of an output signal on indicator 6 will mean the absence of pathological changes in the dentin. If there is an amplitude selector 9 in the display unit 5 in the form of a comparator, the signal arrives from the output of the frequency filter 4 to the first input of the comparator 9 if the amplitude of this signal exceeds the voltage applied to the second input of the comparator 9 from the electric power source 8, for example, through the voltage regulator, leads to the appearance of a signal at the output of the display unit 5. The presence in the spectrum of the acoustic signal from carious dentin oscillations with a frequency in the range from 1 kHz to 6 kHz with an amplitude greater than the amplitude of oscillation in the same range from the intact dentin can further diagnose the condition of dentin. In particular, when connecting the output of the receiver of acoustic signals 3 to the input of the second frequency filter 10, which transmits electrical vibrations in the frequency range from 1 kHz to 6 kHz and the electrical connection of the output of this filter to the input of the second amplitude selector 11, made, for example, also in the form of a comparator , the presence of a high level signal at the output of the second frequency filter 10 provides the appearance of a signal on the second indicator 12. Obviously, this can only happen if the second The first amplitude voltage selector 11 corresponds to the amplitude of oscillations from carious dentin.

Claims (13)

 1. A dental probe containing a metal rod with a point and a handle fastened to an acoustic signal receiver, and an indication unit, including an indicator, characterized in that the output of the acoustic signal receiver is connected to the input of the frequency filter with a transmission frequency of more than 10,000 Hz, while the input of the block Indication connected to the output of the frequency filter, and the output is the output of the probe.  2. The dental probe according to claim 1, characterized in that the display unit includes an electronic key and an electric power source, the control input of the electronic key being the input of the indicating unit, and the indicator connected to the power source through the output of the electronic key.  3. The dental probe according to claim 1, characterized in that the display unit includes an amplitude selector and an electric power source connected to an input of the amplitude selector, the input of the amplitude selector being the input of the display unit, and the indicator connected to the output of the amplitude selector.  4. The dental probe according to claim 3, characterized in that the second frequency filter with a passband of 1000-6000 Hz, a second amplitude selector and a second indicator of the display unit are additionally connected to the output of the acoustic signal receiver, while the electric power supply is additionally connected to power input of the second amplitude selector.  5. The dental probe according to claims 3 and 4, characterized in that the amplitude selectors are made in the form of comparators so that their second inputs are electrically connected to the electric power source through voltage regulators.  6. The dental probe according to claim 1, characterized in that the handle has a cavity, and the acoustic signal receiver is located inside this cavity at the attachment point of the handle and a thin metal rod.  7. The dental probe according to claim 1, characterized in that the acoustic signal receiver is located on the surface of the dental probe.  8. The dental probe according to claim 1, characterized in that the receiver of acoustic signals is made in the form of a microphone.  9. The dental probe according to claim 1, characterized in that the acoustic signal receiver is made in the form of a piezoelectric element.  10. The dental probe according to claim 1, characterized in that the indicator is made in the form of an LED.  11. The dental probe according to claim 1, characterized in that the indicator is made in the form of a liquid crystal display.  12. The dental probe according to claim 1, characterized in that it is additionally equipped with a sound duct, the input of which is acoustically coupled to the tip of the probe shaft, and the output is connected to the input of the acoustic signal receiver.  13. The dental probe according to claim 1, characterized in that the tip of its rod is additionally equipped with a vibrator.

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