SE1001237A1 - Device for quality testing of a dental bracket - Google Patents

Abstract

The invention relates to a method and device for testing the quality of attachment of a dental crown attached to a tooth and / or implant. The method comprises the steps of: detecting at least one resonant frequency for a part when it is in contact with said crown or a part attached to the crown, and interpreting the detected resonant frequency with regard to the degree of attachment between the crown and the tooth (Fig. 2).

Description

25 30 A major risk is attaching crowns to the surrounding teeth. If there is a loose contact between the crown and the teeth, the risk of caries increases. The most common cause of solid bridge replacement is caries, or decay of the underlying tooth structure. When one of the supporting teeth for a bridge develops caries (rot), the entire bridge, which includes at least three kronor, must be replaced. Often the supporting tooth also needs more care, for example a pulp protection, root building, crown extension or root filling treatment.

SUMMARY There is thus a need to discover if there is a problem in the bracket between the crown (s), especially dental bridge crowns and a tooth and / or an implant.

There is thus a need for a procedure to clinically observe the quality of the bracket between the crown and the tooth surface. A non-destructive test would help reduce errors of this type, and also allow for recurring tests to be performed on bridge supports, which are used to ensure that they are still satisfactory.

It is therefore the object of the present invention to provide a non-destructive test which can give a reliable indication of the quality and / or extent of the bracket between a crown and the tooth to which it is attached.

Therefore, a method is provided for testing the attachment quality of a dental crown connected to a tooth and / or implant. The method consists of: detecting at least one resonant frequency of a part when it is in contact with said crown or a part attached to the crown, and interpreting the detected resonant frequency with regard to the degree of attachment of the crown to a tooth. The method may comprise the step of releasably attaching the part to the crown, or a part attached to it. The part may consist of a support pin. The pin is attached to the said crown or partially connected to the crown via a threaded hole. The pin can also be attached to the said crown or partially connected to the crown by means of fasteners. The pin can be incorporated in the said crown or a part connected to it.

The method may comprise the step of comparing the detected resonant frequency with one or more values of resonant frequencies caused by the same or similar part from a previous measurement. The method may include the steps of exciting the part with an AC signal, detecting the response from the part to the AC signal, and varying the frequency of the AC signal until the detected responses from the part are maximum. The method may comprise driving an output signal which is the ratio of the voltage of the response signal to the excitation signal. The method can also involve performing a pulse excitation of the part and detecting the response and making a frequency analysis of the response signal. Preferably, the measurement is non-contact.

The invention also relates to a device for quality testing of a dental crown bracket. The device comprises a detector for detecting at least one resonant frequency for a part when it is attached to the dental crown. The detector for detecting at least one resonant frequency in the part may comprise means for exciting the part with an AC signal, and a sensor for detecting the response from the part to the AC signal, the device is such that the frequency of the AC signal is variable, and the sensor senses when the response from the part is highest. The excitation means and / or the detector may comprise a piezoelectric element, which is driven by a variable frequency oscillator. The part consists of a detectable part and the detector part consists of a detector for contactless detection of said detectable part.

According to one embodiment, the part may consist of a magnetic part and the detector may consist of a coil.

According to one embodiment, the part may consist of a marker and the detector may consist of a light detector.

According to one embodiment, the part may consist of a ferromagnetic material and the detector may consist of a coil for detecting interference in an external magnetic field.

The device may further comprise an amplifier, a processor and a data memory. The processor is further configured to vary a frequency output signal in an oscillator, and store the results in said data memory. At least one coil can be configured to transmit magnetic pulses to a part attached to this part and detect response corresponding to the magnetic pulse from the part.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail, by way of example only, with reference to the accompanying drawings, in which: Fig. 1 shows a schematic view of a dental bridge; Fig. 2 shows a schematic view of a second embodiment of a device, according to the invention; Fig. 3 shows a schematic view of a second embodiment of a device, according to the invention; Fig. 4 shows a schematic view of a third embodiment of a device, according to the invention; Fig. 5 shows a schematic view of a dental bridge according to an embodiment of the invention; Fig. 6 shows a diagram of a coarse sweep used to obtain resonant frequencies; Fig. 7 shows a schematic view illustrating the variation of the resonant frequency over time for a particular bridge. and Fig. 8 shows a diagram illustrating data from a sweep used to obtain the resonant frequency of the device according to Fig. 3.

DESCRIPTION With reference to Figure 2, the device consists of a part in the form of a projecting pin 20 fastened by means of e.g. a threaded section or glue to a fixture in a suitable place on the bridge 10 (in this case false tooth). The bridge can be any of a number of known types. Two sensors, e.g. piezoelectric elements or strain gauges 21 and 22 are attached, e.g. bonded, to different sides of the pin 20, the sensor 21 being an exciter and 22 being a receiver.

The exciter 21 can be driven by a variable frequency oscillator, signals from which, for example in the form of a sinusoidal voltage excitation, are supplied to the exciter 21 via an amplifier. The oscillator and amplifier may be included in a frequency response analyzer 28.

The signals detected by the receiver 22 are amplified by a charge amplifier 27 and provided as an input to the analyzer 28. The output of the analyzer representing the relationship between the response voltage and the excitation voltage is fed to a processor, such as a microprocessor 26, which is used to vary the frequency output of the oscillator. the analyzer 28, and store the result in a data memory 29. The results may be printed, and / or displayed on an oscilloscope 25, and / or an AC voltage meter or the like.

In use, the pin 20 is secured, i.e. screwed to the bridge 10. Constant amplitude, e.g. 1 volt, AC excitation signals are then applied to the pin 20 via unit 21. The frequency of the AC excitation signals is varied until the amplitude of the signal displayed on the oscilloscope 25 is maximum. The resonant frequency is the frequency where the amplitude of the ratio between the response voltage to the excitation voltage is max.

Fig. 6 shows data from a coarse sweep used to obtain an approximate resonant frequency. A finer sweep around this region is then used to identify this frequency, usually the first or fundamental frequency more accurately. This frequency is noted and compared, for example with data for other bridges / crowns at a similar stage of fortification.

It is expected that for a particular bridge bracket, the resonant frequency will vary with the time depicted in Fig. 7. Thus, by comparing the detected resonant frequencies with previously compiled data for similar previous measurements, an indication of the degree of attachment of the crown to the tooth can be obtained. .

The technique, which is based on the detection and comparison of resonant frequency shifts, rather than amplitude changes, is effective in determining the quality of the bracket between the crown (s) and the tooth (s) as a function of its stiffness.

The pin 20 shown in Fig. 2 may advantageously be of metal, e.g. aluminum, stainless steel or titanium, is dimensioned to provide a resonant frequency range for the system in the order of 1 to 20 kHz, more specifically 5-15 kHz, and preferably in the region of about 10 kHz.

It is obvious that various changes may be made without departing from the scope of the present invention as defined in the appended claims.

For example, additional pairs of excitation / detector sensors or meters may be mounted on the sides of the pin at 111 ° to the sensors or meters 21 and 22 so as to provide readings at right angles to these sensors, without necessarily reorienting the pin on the bridge. In addition or alternatively, the pin and / or sensor system could be adapted to rotate relative to the dental bridge or crown.

The sensor or meter and possibly also the pin can be coated, for example with an air-dry acrylic material, to protect the sensors during the sterilization of the device. The electrical connections or cables connected to the sensors are mounted or adapted to minimize their damping effect on the resonant structure. The part can take a different shape than a support pin and / or piezoelectric sensors can be replaced with other transmitter / receiver parts, for example sound resonance can be used. The pin, instead of being basically straight, could be substantially U-shaped, and connected to the bridge or crown at its base. The sensors or equivalent can be mounted on the same or opposite leg.

According to another aspect of the invention, the measurements are performed contactless.

According to Fig. 3, the system comprises a part 30 in the form of a projecting pin attached to bridge 10. The part 30 is provided with a magnetic element 31. The magnetic element 31 can be arranged at one end of the pin 30, e.g. the free end or integrated inside the pin.

The second part of the system consists of the test equipment 35, including a probe 351 and a response analyzer unit 352. The probe 351 consists of a coil 353 for detecting oscillations of the magnetic element 31.

In this case, one of the crowns 11 is attached to an implant 17 instead of a tooth. The implant is anchored in a leg by means of a screw part 18.

To generate oscillations in the pin, it must be excited. This can be done manually or with the help of an electric sensor, by applying a force F to the pin.

Signals detected by the probe 350 are amplified by an amplifier 354 and provided as an input to the analyzer. The output of the analyzer, which represents the relationship between the response voltage and the excitation, is fed to a processor, such as a microprocessor 355, which is used to vary the output frequency of the oscillator by the analyzer, and the results are stored in the memory 356. The results can be printed, and / or displayed on a display or the like.

Referring now to Fig. 4, a third embodiment of the invention is illustrated, in which the first part of the arrangement according to the invention consists of a part in the form of a projecting pin 31, as in previous embodiments, attached to the tooth bridge 10. The pin 31 in this the case is provided with a mark 42, such as lines, arranged at one end of the pin 21.

The second part of the embodiment comprises the test equipment 450, including a probe 451 and a response analyzer unit 452. The probe 450 consists of a light source 453a, preferably but not limited to a laser, and a light detector 453b for detecting reflections from the pin and thus the oscillations of the pin. The light source is preferably a laser diode. The pen is equipped with one or more markers, such as darker (or lighter) sections that affect light reflection. The path is excited manually or, for example, by an electric exciter, by applying a force F to the pin.

The light source on the tip of the probe illuminates the pin and the light detector 453b detects the reflected light. The detected light signal is converted into an electrical signal from the detector and the signals detected by the probe 451 are amplified by an amplifier 454 and provided as an input signal to the analyzer. The output of the analyzer, which represents the relationship between the response voltage and the excitation, is fed to a processor, such as a microprocessor 455, which is used to vary the output frequency of the oscillator by the analyzer, and store results in a memory 456. The results can be printed, and / or displayed on a display or the like.

In use, the pin 31 is fixed in the dental bridge 10. Preferably, but not necessarily, the pin according to the invention is a disposable article, which means that it can be removed and discarded, which provides a hygienic test arrangement.

F ig. Fig. 8 shows data from a coarse sweep, which is used to obtain the resonant frequency roughly in the device according to Fig. 3. A finer sweep around this region is then used to identify this frequency, usually the first or fundamental frequency, more accurately. This frequency is noted and compared, for example with the data for a previous measurement, e.g. when the bridge was installed.

It is expected that for a given bridge, the resonant frequency will vary with the degree of attachment of the crowns to the teeth. Thus, the detected resonant frequency is compared with previously compiled data for the same bridge, which can give an indication of the degree of attachment of the bridge obtained.

The technique, which is based on detecting and comparing resonant frequency shifts, rather than amplitude changes, is effective in determining the quality of the mount.

The pin which can advantageously be made of metal, e.g. titanium or aluminum, is dimensioned to provide a resonant frequency range for the system (bridge bracket and pin) in the order of 1 to 20 kHz, more specifically 1-10 kHz, and preferably in the region of about 8 kHz. For example, in the embodiment according to Figs. 2 and 3, the pin can be about 1 cm high.

In yet another embodiment, the pin may be comprised of a ferromagnetic material and may be excited by an external magnetic field generated by a field generator. The field generator may be a permanent magnet to generate a DC field or a coil to create an AC field. The probe can be arranged externally.

The magnet connected to a smart stick (pin) can be excited with magnetic pulses. After each pulse, alternating magnetic fields are obtained which are the result of the self-oscillating pin of the coil in the measuring probe. The magnetic pulses can be generated by another coil in the same probe (or an additional probe).

Metallic sticks have a simplified mechanical construction compared to the sensors, and do not require individual calibration. It is not possible to store any calibration parameters in them because they are not electrically connected to the instrument. Instead, individual differences between the pins are reduced to a minimum through a carefully controlled manufacturing process.

The pins also have a simpler mechanical behavior when they vibrate at their resonant frequency. They are more sensitive and have a predictable behavior down to very low attachment stability.

A measurement can consist of a number of pulses, e.g. 4 or 30 pulses. In the case of 30 pulses, these pulses cover the frequency spectrum 1 to 10 kHz. Because the pulses are more narrowband, the 30 pulses contain more energy. This makes the response signals stronger and the signal-to-noise ratio is better, which makes the measuring device of the device less sensitive to ambient electromagnetic disturbances. It is well known to a person skilled in the art that the number of pulses is not limited to 4 or 30.

An embodiment of a dental bridge 10 is shown in Fig. 5. The embodiment includes detectable parts such as magnetic or optical parts 16 in the crowns 11 or the false tooth 13. This design enables the use of the same measuring points.

It will be understood that various changes may be made without departing from the scope of the present invention as defined in the appended claims.

Sensors or gauges and possibly also the pin may be coated, for example with an air-dry acrylic material, to protect the sensors during sterilization of the device. The part can take a different shape than support pins. The pin, instead of being straight, can be substantially U-shaped, and connected to the bridge via its base. In addition, alternative detectors, such as UV, sound and the like, can also be used.

The invention is not limited to bridges and can be applied to crowns or other arrangements to be attached to a tooth.

Claims (1)

A method for testing the quality of attachment of a dental crown (11) attached to a tooth (14), the method comprising the steps of: detecting at least one resonant frequency of a part (16, 20, 21, 31) when it is in contact with said crown (11) or a part attached to the crown, and interprets the detected resonant frequency about the degree of attachment between the crown and said tooth. A method according to claim 1, comprising the step of releasably attaching the part to the crown, or a part connected to it. Method according to claim 1 or 2, wherein the part consists of a support pin. Method according to claim 3, wherein the pin is attached to said crown or a part connected to the crown via a threaded hole. Method according to claim 3, wherein the pin is attached to said crown or a part connected to the crown by means of fastening means. The method according to claim 3, wherein the pin is incorporated in said crown or a part connected to the crown. . A method according to any one of claims 1 to 6, comprising the step of comparing the detected resonant frequency with similar one or fl values of the resonant frequency for the same or similar part from a previous measurement. A method according to any one of claims 1 to 7, comprising the step of exciting the part with an AC signal, detecting the response from the part to the AC signal, and varying the frequency of the AC signal until the detected response from the part is maximum. A method according to claim 8, comprising driving an output signal which is the ratio between the voltage of the response signal and the excitation signal. A method according to any one of the preceding claims, wherein said measurement is non-contact. . A method according to any one of the preceding claims, comprising a pulse excitation of the part and detecting the response and performing a frequency analysis of the response signal. Dental crown mounting quality testing device, characterized in that the device comprises a detector (27, 351, 451) for detecting at least one resonant frequency of a part (16, 20, 21, 31) when the part is attached to a dental crown (11). A device according to claim 12, wherein the detector for detecting at least one resonant frequency of the part comprises means for exciting the part with an AC signal, and a sensor for detecting the response from the part to the AC signal, which device is arranged to The AC signal is varied, and the sensor detects when the response from the part is maximum. Device according to claim 12 or 13, wherein the excitation means and / or the detector consists of a piezoelectric element, which piezoelectric element comprising the excitation means is driven by a variable frequency oscillator. Device according to claim 12 or 13, wherein said part consists of a detectable piece and said detectable piece consists of a detector for contactless detection of said detectable part. The device of claim 15, wherein said part comprises a magnetic part. The device of claim 15, wherein said detector consists of a coil. Device according to claim 12 or 13, wherein said part comprises a marker. The device of claim 18, wherein said detector consists of a light detector. Device according to claim 12 or 13, wherein said part consists of a ferromagnetic material. The device of claim 17, wherein said detector comprises a coil for detecting interference in an external magnetic field. The device of any of claims 12-21, further comprising an amplifier, a processor and a data memory. The apparatus of claim 22, wherein said processor is further configured to vary an output frequency in an oscillator, and store the results in said data memory. The device of claim 22, comprising at least one coil configured to output magnetic pulses to a portion attached to a crown or portion connected thereto and detecting the response corresponding to said magnetic pulses from said portion.