SE508338C2 - Method and apparatus for measuring elasticity - Google Patents

Abstract

The invention concerns a device and a method for measuring the resilience in an area (16) of an object (30). The device comprises an oscillation source, a first transmission means (14) for transmission of an oscillation movement from the source of oscillation to the area (16), and a measuring means for measuring the oscillation movement damping caused by said area (16). The method comprises the steps of providing an oscillation movement of the area (16) and by measuring the oscillation movement damping caused by said area (16).

Description

sos 338 W 2 10 15 20 25 30 35 Root caries can be “repaired” by so-called remineralisation of the affected area, whereby minerals that have been removed from the affected area by the caries process are again arranged in and on the tissue. Repaired root caries areas regain essentially the same mechanically elastic values as in healthy root dentin. It is a problem that according to the prior art there is no good objective method for assessing the effect of root caries treatment interventions over time, ie whether remineralization of a root caries infested tooth area has been achieved.

In particular, in order to solve these problems in the field of oral diagnostics, the invention set forth in the appended claims has been developed. However, it has been found that the invention can also be used in elasticity measurement for applications other than for root caries measurements.

A first object of the present invention is therefore to provide an apparatus and a method for measuring elasticity in an area of an object which gives an objective measurement result.

A second object of the present invention is to provide a device and a method for measuring elasticity in an area of an object which gives an objective measurement result even for several measurements performed at different times.

A third object of the present invention is to provide an apparatus and method for measuring elasticity in an area of an object which is substantially non-destructive to the area.

A fourth object of the present invention is to provide an apparatus and method for measuring elasticity in an area of an object which is easy to use, and which can also be used for measurement in relatively small and narrow spaces.

These and other objects are achieved according to the present invention with a device and a method for measuring elasticity in an area of an object according to the appended claims.

In the following, presently advantageous embodiments of the present invention are described in more detail with reference to the accompanying drawings.

V Details that substantially correspond to each other in the various figures have corresponding reference numerals.

Fig. 1 shows a schematic, partly sectioned perspective view of a first embodiment of a device according to the invention.

Fig. 2 shows an area in Fig. 1 on an enlarged scale.

Fig. 3 shows a partially broken away, schematic sectional view from the side of a detail included in the device shown in Fig. 1 on an enlarged scale.

Fig. 4 shows a schematic, partly sectioned second embodiment of a device according to the invention.

Fig. 5 shows a schematic exploded view of parts included in the device shown in Fig. 4.

Fig. 6 shows in a schematic block diagram an embodiment of a drive and measuring device according to the invention.

Fig. 7 shows a schematic view of a tooth used in measurement with the invention in vitro.

The device shown in Fig. 1 has a body with the general reference numeral 1, which has a handle part 2. The body 1 and the handle part 2 are preferably made of a non-conductive material such as plastic.

The device has an oscillation source comprising an oscillation generating element, with the general reference numeral 3, and a drive means, with the general reference numeral 12 (see Fig. 6).

The oscillation generating element 3 in Fig. 1 is The oscillation generating element 3 is also shown in an enlarged manner arranged in a recess in a front part of the body 1. scale in Fig. 3 and in the embodiment shown comprises a membrane part 4, for example in the form of a substantially circulating learn metal plate. sos sas 4 1 4 10 15 20 30 35 The membrane part 4 has on its inner side facing the body 1 a piezoelectric element with the general reference numeral 5. The piezoelectric element 5 comprises a piezoelectric plate 6 with an electrode 7 at the one towards the membrane part 4 facing side, and with an electrode 8 at the side facing the interior of the body 1.

In the embodiment shown, the area of the outer edge of the diaphragm part 4 is fixed in the recess in the front part of the frame 1, for example by gluing. The electrodes 7 and 8 are connected via wires 9 and 10, respectively, which in the embodiment shown extend through a channel in the interior of the body, to the drive means 12 (see Fig. 6), which is included in a drive and measuring device indicated by the general reference numeral 11 ( see Fig. 1). The drive means 12 in the example shown is an alternating current source which during operation causes an oscillation of the piezoelectric element 5, which oscillation is lateral in relation to the diaphragm part 4 in the direction of the arrow 13. According to a preferred embodiment, the AC source has variable amplitude and / or frequency for the voltage.

At the side of the membrane part 4 facing away from the body 1, a first transfer member 14 is in the embodiment shown, for example by gluing attached to a detail such as a non-conductive plastic part 15, which in turn is attached to the membrane part 4. The first transfer member 14 is made of stainless steel, for example, and is bent 90 ° in the region of the end facing away from the body 1 in this embodiment. The device also has a measuring means comprising a vibration detecting means, a second transmission means 17 and a display unit with the general reference numeral 20. the second transfer means 17 is according to a preferred embodiment made of stainless steel, and in the embodiment shown in the area of the end facing away from the body 1 makes contact with and is preferably for instance by welding fixedly arranged at the first transfer means 14. The second over The guide means 17 is in the embodiment shown in the area of the body but in the opposite end, for example by gluing attached to a part 18 such as a non-conductive plastic part. The part 18 is in turn attached to a vibration detecting member. The vibration detecting means is arranged in a recess at the same end of the body 1 as the above-mentioned piezoelectric element, and in the embodiment shown has a membrane part which is connected to a second piezoelectric element with the general reference numeral 19 which is preferably of the same The second piezoelectric element 19 electrodes are via wires, which in the embodiment shown extend type like the above-mentioned piezoelectric element. through a channel in the interior of the frame, connected to the display unit 20 (see Fig. 6). The display unit 20 is included in the drive and measuring device 11 in the embodiment of an amplifier 21, (see Fig. 1) and comprises in the shown a rectifier 22 and a phase shift detection unit 23.

Fig. 1 schematically shows an object 30, which in this case is a tooth at which the gums in a zone are retracted, whereby a caries attack has occurred in an area 16. The device according to the invention is inserted into the mouth of the patient so that the first the transfer means 14 makes contact with an area to be diagnosed, for example the surface area 16. In operation, the oscillating movement of the piezoelectric element 5 is transmitted to the first transfer means 14 and to the area 16, the first transfer means 14 being arranged so that its oscillating movement is substantially parallel to the surface of the area 16 in the direction of the arrow 13 '(see Figs. 1 and 2, the arrows 13 and 13' are substantially parallel). Since the volume (and thickness) of root caries is relatively small in relation to the thickness of the tooth root, the force which affects the measuring range of the tooth and which is directed substantially parallel to the measuring range should be relatively small, which is easily achieved, for example, by limiting the amplitude of the piezoelectric element. 508 338 e «10 15 20 25 30 35 oscillations and thereby limit the oscillations in the tested measuring range.

If the area 16 is affected by caries, due to demineralization, its elasticity differs from the elasticity of an unaffected area of the tooth. In particular, the elasticity of an area 16 affected by caries is greater than that of an unaffected area of the tooth, and thus provides less attenuation of the oscillating movement of the first transfer member 14 than for an unaffected area of the tooth.

The second transmitting means 17 transmits the attenuated oscillation motion from the first transmitting means 14 to the vibration detecting means, and in the illustrated embodiment, the signal from this means is amplified by the amplifier 21 and the signal is rectified by the rectifier 22 at which the amplitude of the attenuated rectified signal can be suitably read.

The amplitude is smaller for non-caries-affected areas than for caries-affected areas because the oscillation movement of the first transfer means 14 mentioned above is attenuated to a greater extent on contact with a non-caries-affected area than on contact with a caries-affected area. The attenuation in a caries-affected area also results in a phase shift between an input signal, such as an alternating current, from the drive means 12 to the oscillation generating element 3, and an output signal, such as an alternating current, from the vibration detecting means. The differences in amplitude and / or in phase are so large that it can be easily read at the display unit 20. Thanks to this, an objective diagnostic result is achieved for the measured area.

Fig. 4 shows a second embodiment of the invention. In this embodiment only a piezoelectric element with the general reference numeral 24 is used. A first transfer means 14 'is in a similar manner as above to the embodiment shown 10, for example by means of gluing attached to a detail such as a non conductive plastic part 15 'membrane part which is connected to the piezoelectric which in turn is attached to an element 24. In this embodiment the first transmission means 14' also acts as second transmission means 17 ', which means that the means also transmits the attenuated signal from the tested the measuring range. This can be achieved thanks to the design of the piezoelectric element per se, which is schematically shown in Fig. 5. At one of its sides, in the case shown it facing the side of the body 1 ', there is an electrode member, which is indicated by the general reference numeral 25, and which comprises an electrode 26 which together with the electrode 7 'the measuring device 11', which drive means has substantially the same, is connected to the drive means in drive and function as that shown in Fig. 6. The second electrode included in the electrode means 25 27, which is insulated from the electrode 26, is connected to a first pole of the drive and measuring device 11 'display unit. The display unit is connected at a second pole to a pole of the drive means, for example by connection to the electrode 7 'or the electrode 26. In this case, a detection signal is provided to the display unit using only a piezoelectric element. The display unit otherwise has essentially the same function as that shown in Fig. 6.

According to a preferred embodiment, the oscillation frequency of the oscillation source is selected so or adjustable to cause a resonant frequency to be generated for the oscillation movement of the first transmission means 14, 14 '. the phase changes sharply, and the phase changes, which among other things increases at resonant frequencies the read amplifiable way can be read at the phase shift detection unit 23. Depending on the design of the device, and in particular to obtain a good measurement result at resonant frequency of the first transmission means 14, 14 ', it is advantageous that the oscillation frequency is in the range from 1 Hz to 100 kHz and in particular is in the range from 1 kHz to 20 kHz.

The invention has been tested in experiments with root caries measurements both in vitro and in vivo. Results from some such measurements are reported below. In the measurements, any suitable measuring unit can be used, which shows the attenuation. For example, the amplitude can be measured, and for example stated in V or A.

Experiment 1: In vitro In vitro experiments, a device according to the embodiment in Figures 1-3 and 6 has been used. The transfer member 14 was made of stainless steel, had a diameter of 1.2 mm, and was bent 90 'at the outer end. The transfer means 14 was attached to a circular metallic membrane part 4 with a cyanacrylate glue via a non-conductive plastic part 15. The outer edge of the membrane part 4 was fastened to the front end of the frame 1 with a cyanacrylate glue. A piezoelectric element 5 was attached to the inner side of the membrane part 4 facing the interior of the body 1.

The second transfer member 17 was made of stainless steel, had a diameter of 0.6 mm, and was welded at one end to the transfer member 14. The second transfer member 17 was with an adhesive in the form of cyanoacrylate at the other end via a non-stainless steel. conductive plastic part 18 attached to a circular metallic membrane part. The outer edge of the membrane part is attached to the front end of the frame 1 with an adhesive in the form of cyanoacrylate. At the inner side of this membrane part facing the interior of the body 1, a second piezoelectric element 19 was attached.

The membrane parts and the piezoelectric elements 5 and 19, respectively, are commercially available as so-called "piezoelectric sound components". The experiments used two such components from Hoechst CeramTec AG Lauf, Germany, of the type "Sonox P51 35424", with a diameter of 12.5 mm 10 15 20 9 508 538 The hollow frame 1 was made of a non-conductive plastic material. The piezoelectric elements 5 and 19, respectively, were connected to a drive and measuring device 11 according to Fig. 6.

The in vitro studies have been performed on extracted human teeth, premolars, removed due to orthodontic reasons. The alternating voltage applied to the piezoelectric elements 5 and 19, respectively, was 9 volts.

By storing the test teeth in 6% carboxymethylcellulose gel mixed with 0.1 mol per liter of phosphoric acid, with a final pH of 5.0, artificial caries can form on various tooth surfaces by continuous demineralization. Round tooth areas protected by round biodiscs (3 mm in diameter) were used as a control, which were glued to the tooth surface and covered with nail polish to resist the acid gel treatment. When removing the biodiscs, tooth surfaces are exposed as round so-called fenestrations. This is shown in Fig. 7, where an acid-treated tooth is schematically shown. The tooth has an acid-treated root surface 50 and an acid-treated enamel surface 51. Biodisks on each surface are indicated by 52 and 53, respectively.

The results of the measurements are shown in Table 1. 508 538 Table 1. Amplitude measurements according to the invention on extracted teeth which have been subjected to continuous demineralization for 3 weeks in 6% CMC gel with pH 5.0.

[Amplitude in suitable unit of measurement] 5 Tooth no. W Fresh dentin "Karierad" dentin BPBP 1 163 166 188 215 2 152 140 500 200 3 170 165 400 120 4 225 175 520 600 5 150 74 400 300 6 168 200 650 640 7 '80 200 200 170 8 140 220 300 230 9 220 113 450 520 10 165 220 680 720 11 143 170 700 550 12 145 168 600 520 13 170 150 500 500 14 188 182 490 534 15 128 134 510 420 Amplitude average value 2 160235 165239 4732157 4162193 Standard deviation B: Buckal P: Proximal 10 Conclusion Measured average amplitude according to the invention gives for healthy dentin 160235 units of measure for buccal surface and l65i39 units of measure for proximal surface in this example. For artificially carious dentin, significantly higher amplitudes were measured according to the invention. On buccal surfaces, units of measurement were measured, and on proximal surfaces, 416,113 units of measurement were measured in this example.

Experiment 2: In vivo In the in vivo experiments a device according to the embodiment in Figs. 4-6 has been used. The transfer member 14 'was made of stainless steel, had a diameter of 1 mm, and was bent with a radius of 10 mm. The transfer means 14 'was with a glue in the form of cyanoacrylate via a non-conductive plastic part 15' 4 '. A piezoelectric element 24 was attached to the inner side of the membrane part 4 'facing the body 1' attached to a circular metallic membrane portion.

The diaphragm part 4 'is commercially available as a so-called "piezo- and the piezoelectric element 24 electrical sound component". The experiments used such a component from Hoechst CeramTec AG Lauf, Germany, of the type "Sonox P51 35424 / selfdrive", with a diameter of 12.5 mm. The front end of the membrane part 4 '1' with an adhesive in the form of cyanoacrylate. outer edge attached to the front end of the hollow body 1 ', the inner diameters of which were 11.5 mm, and its handle part 2', were both made of a non-conductive plastic material. The piezoelectric element 24 was connected to a drive and measuring device 11 ', with the same function as that shown in Fig. 6.

The methodology of the invention has been tested on patients with clinically diagnosed root caries.

Reproducibility measurements have, for example, been performed on a 25-year-old patient who showed the following status.

Tooth 24 and 13: Root caries with "leathery" surface structure.

As a reference surface, the tempted enamel on the same teeth was also measured. The result is shown in Table 2. 508 338 12 Table 2. [Amplitude in suitable measuring unit] Tooth 24 Tooth 24 Tooth 13 Tooth 13 Chromed Healthy Charred Healthy root surface enamel root surface enamel 180 150 180 100 180 120 190 100 180 120 170 100 170 120 180 120 190 100 200 150 180 120 200 120 190 120 190 100 190 120 190 100 190 120 190 100 170 120 190 120 Amplitude mean standard 183: 8 121111 188: 10 110: 17 deviation An amplitude study has also been performed on four additional 5 patients comprising 20 teeth with root-carious surfaces and with fresh enamel as a positive reference structure on each tooth. The results of the measurements are shown in Table 3. 10 15 20 25 13 508 338 Table 3. [Amplitude in suitable measuring unit, N = number of teeth] Root- Root- Enamel-carious surface healthy surface healthy surface N = 7 N = 13 N = 20 Amplitude mean: 146: 6 105: 8 115210 Standard deviation Conclusion From the in vivo study, it can be stated that carious root surfaces show about 40% higher average appliance level and that the amplitude level for healthy root dentin and healthy enamel does not differ significantly. This means that the healthy enamel as well as healthy dentin can also be used as a reference object for measurements on root surfaces that show clinical caries. The ratio between carious root and enamel is about 1.4.

Other embodiments of the invention According to an embodiment of the invention, the second transfer means 17 does not make contact with the first transfer means 14, but instead makes contact with the measuring area in the vicinity of the contact area of the first transfer means 14 with the measuring object. According to this embodiment, the oscillation movement is transmitted from the first transmission means via the measuring area of the object to the second transmission means.

The display unit design can be varied within wide limits. For example, it does not need to show a rectified voltage amplitude, but can show any signal that indicates the magnitude of the attenuation. 508 558 14 10 15 20 25 30 35 The vibration detecting means need not have a piezoelectric element for providing a signal corresponding to the attenuation. Instead, other vibration-sensitive detectors such as capacitive, magnetic, electromagnetic or acoustic detectors can be used. The oscillation movement can for instance also be effected by a magnetically driven or an electromagnetically driven element. It is also possible to produce an oscillating movement in the form of "shock waves" instead of, as in the example described above, where a sinusoidal shape of the alternating current source causes continuous oscillating movements of the first transmission means 14, 14 '.

Enamel caries sometimes leads to caries in the crown dentin inside the enamel. It will be appreciated that the invention may also be used for measurements on this type of dentinal caries.

This type of tooth damage can be treated, for example, by drilling up the damage in the enamel and dentin, and by then applying a temporary filling to plug the hole in the enamel and dentin. The pulp then withdraws from the injured area during healing, and the dentin is hopefully formed up towards the affected area. The filling can be removed after a while to examine how the treatment worked. The invention can be used here to measure the elasticity of the affected crown dentin before and after treatment, to give an objective measure of whether the treatment has been effective. It has been found that the invention can also be used to advantage in elasticity measurements for objects in other areas of use than for root and dentin caries measurements on a tooth in a human or animal's mouth, or on an elongated tooth. For example, the invention can preferably be used in the medical field to measure softening of dentin, skeleton and nails, to measure a wound healing process where the healing process causes increased or altered elasticity of the wound area, and for measurements of horny skin formations. The invention can also be used, for example, for measuring the elasticity of capsules of materials such as cellulose, etc., which capsules can be used, for example, for encapsulation of pharmacological products and drugs.

The invention can also be used for elasticity measurements on other types of paper and cellulose products.

Another area of use for the invention is measurement of the drying process, such as, for example, measurement of the drying process of paint, which obtains reduced elasticity during said process.

Other examples of areas of use for the invention and in It will be appreciated that the method according to the invention and it are measurements for coagulation of, for example, blood, formation of gel in, for example, the food industry. According to the invention, the device can also be used for measuring elasticity in a number of other application areas, such as for measurements on wood material, for example to check rot, for rubber, for example to measure the elasticity of rubber gaskets which decrease with increasing life, on cadaver, on plastics, on hides / leather in the processing industry, etc. In most of these applications it is preferable to perform measurements of the elasticity in the surface area of the object, but it is realized that it is also possible to measure the elasticity for coagulation and gel applications, for example. in, for example, the center of the measuring object (ie in the middle of, for example, the gel) by inserting at least one first transfer member into the measuring object.

The invention also relates to a method for measuring elasticity in an area of an object, comprising the measures of effecting an oscillation movement of the area, and of measuring the attenuation of the oscillation movement caused by the area.

The invention provides a device and a method for measuring elasticity in an area of an object which gives an objective measurement result, for example in the form of a rectified amplitude for the attenuated oscillation 338 4 M 10 15 20 movement. By means of the invention, an objective measurement result can thus be achieved also for several measurements which are performed at different times, such as for instance when measuring a remineralization process for a caries-infested area of a tooth. According to a preferred embodiment, the oscillation movement in the tested area is substantially parallel to the surface of the tested area, and a relatively small amplitude of the oscillation movement is used, which means that measurement with the device according to the invention and utilization of the method according to the invention are substantially non-destructive to the object area. Thanks to the design of the device, it is easy to use, and can advantageously also be used for measurement in relatively narrow spaces, such as, for example, for root caries diagnosis in the oral cavity.

It will be appreciated that it is possible to make certain deviations from the described embodiments. All variants and modifications included in the underlying inventive concept shall, however, be covered by the appended claims.

Claims (20)

10 15 20 25 30 35 17 508 338 PATENT REQUIREMENTS 1. A device for measuring elasticity in an area (16) of an object (30), the device having an oscillation source, a first characterized in that guide means (14: 14 ') for transmitting an oscillation motion from the oscillation source to the area (16), (16) caused the attenuation of the oscillation movement, and a measuring means for measuring the area of the oscillation movement of the first transmission means (14; 14 ') (16). in the area is essentially parallel to Device according to claim 1, characterized in that the object (30) that the measuring area is a substantially fixed one (16) and that the first surface, such as a tooth, is a surface area of the object (30), the guide means (14) ; l4 ') causes non-destructive contact structure, with the surface area. Device according to any one of the preceding claims, characterized in that the measuring means has a vibration detecting means for detecting it by (16) Device according to claim 3, the area causing the attenuation of the oscillating motion. characterized in that the measuring means has a second transmitting means (17; 17 ') the movement from the area and / or from the first transmitting (14; 14') for transmitting the damped oscillating transmitting means to the vibration detecting means. Device according to one of Claims 3 to 4, characterized in that the measuring means has a display unit (20), which is connected to the vibration detecting means, and which, directly or after treatment, such as amplification, rectification, etc., shows one from the vibration detecting means. attenuation indicating signal emitted, for example in the form of the amplitude of a rectified alternating voltage from the vibration detecting means, or in the form of the phase shift 508 338 2 w l0 15 20 25 30 35 between an input signal to the oscillation source and an output signal from the vibration detecting the means, said signals being, for example, alternating currents. Device according to one of Claims 3 to 5, characterized in that the vibration detecting means has a piezoelectric element (19; 24) for detecting the attenuation of the oscillating movement caused by the area (16). Device according to one of the preceding claims, characterized in that the oscillation source has an oscillation-generating element (3) with a piezoelectric element (5; 24) for generating the oscillation movement. Device according to claim 6, characterized in that the oscillation source has an oscillation-generating element (3) with a piezoelectric element (24) for generating the oscillation movement, and that this piezoelectric element (24) is used for both the oscillation source and the vibration detecting means. Device according to any one of claims 1 - 6, characterized in that the oscillation source has an oscillation generating element with a magnetically driven element for generating the oscillation movement. Device according to one of Claims 7 to 9, characterized in that the oscillation source has a drive means (12), preferably in the form of an alternating current source, which is connected to the element (5, 24) which generates the oscillation movement. 11. ll. Device according to one of the preceding claims, characterized in that the oscillation frequency of the oscillation source is adapted and / or that the oscillation frequency of the oscillation source is adjustable for generating resonant frequency of the first transmission means (14: 14 '). Device according to any one of the preceding claims, in that the oscillation frequency oscillation motion. k ä n n e t e c k n a d 10 15 20 25 30 35 19 508 338 is in the range from 1 Hz to 100 kHz and in particular is in the range from 1 kHz to 20 kHz. Device according to one of the preceding claims, characterized in that the device has a body (1), which has a handle part (2), the oscillation-generating element (3) included in the clay source, that an oscillator is arranged at the body, that the first transmission (14; 14 ') is connected to the oscillation generating element vibration detecting means is arranged at the body and that a second transmission means (17; 17') conducts the attenuated oscillation movement from the first transmission means (14: 14 ') to the the vibration detecting means is connected to the first (14: 14 ') means (3), to a (1) included in the measuring means, for the transmission means and the vibration detecting means. A method of measuring elasticity in an area (16) of an object (30), of the measures of causing an oscillating movement of the area (16), (16) causing the attenuation of the oscillating movement, the oscillating movement being substantially parallel to the area (16) . A method according to claim 14, of the step of causing an oscillation source characterized by an oscillation source and measuring it characterized by the area - to cause an oscillation movement of a first transmission means (14: 14 '), to effect non-destructive contact between the transmission means (14: 14 ') (16), and to measure with a measuring device the attenuation of the oscillation movement caused by the area. wherein the object and the area (16) A method according to claim 15, is a substantially fixed structure, characterized by the measures of performing the measurement in a (30) drawn surface area of the object (30), and of effecting an oscillating movement of the first transfer means (14: 14 '). the surface area. which in the surface area is substantially parallel to 508 338 20 10 15 20 25 Method according to one of Claims 15 to 16, characterized by the measures of measuring the attenuated oscillation movement in the area (16) with the measuring means and / or directly or via a second transmission means (17) measuring the attenuated oscillation movement of the first transmission means. (14: 14 '). Method according to one of Claims 14 to 17, characterized by the step of showing in a display unit (20) directly or after treatment, strengthening, rectification, etc., the attenuated oscillation movement, for example in the form of the amplitude of a rectified alternating voltage from the measuring means, or in the form of the phase shift between an input signal to the oscillation source and an output signal from the vibration detecting means, said signals being, for example, alternating currents. Method according to any one of claims 15 - 18, characterized by the measure of adjusting the oscillation frequency of the oscillation movement and / or adjusting the oscillation frequency of the oscillation movement so that resonant frequency is generated for the first transmission means (14; 14 '). A method according to any one of claims 14 to 19, of the step of generating an oscillating motion. know the oscillation frequency in the range from 1 Hz to 100 kHz and in particular in the range from 1 kHz to 20 kHz.