JP4264128B2 - Optical examination device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is characterized in that it is a device for examining living tissues including teeth.
[0002]
[Prior art]
There is a manual diagnostic instrument.
[0003]
[Problems to be solved by the invention]
Conventional examination devices have a problem that the organization is easily damaged, and there is a difficulty in automatic examination.
[0004]
[Means of Claim 1]
The optical examination device according to claim 1 is:
A tip terminal provided with a light irradiator that emits light to the portion inserted into the periodontal pocket;
A light measuring means for measuring light from the light irradiation unit in a state inserted in a periodontal pocket;
Storage means for storing what has been measured in advance with respect to the relationship between the intensity of light measured by the light measuring means or the light absorption state and the state of the periodontal pocket;
From the light intensity measured by the light measurement means or the light absorption state,
And a control device for specifying a periodontal pocket based on the storage means.

[Means of claim 2]
The optical examination device according to claim 2 is:
The light irradiation part is provided extending from the tip of the tip terminal inserted into the periodontal pocket in the longitudinal direction over the outside of the periodontal pocket,
The light measurement means is provided so as to be able to measure the intensity of light emitted from the light irradiation unit exposed to the outside from a periodontal pocket,
The control device stores data relating the intensity of light irradiated from the light irradiation unit exposed to the outside from the periodontal pocket and the depth of the periodontal pocket,
The depth of the periodontal pocket in which the tip terminal is inserted is quantified based on the intensity of light measured by the light measuring means and the stored data.

[Means of claim 3]
  The optical examination device according to claim 3 is:
The light irradiation part is provided extending from the tip of the tip terminal inserted into the periodontal pocket in the longitudinal direction over the outside of the periodontal pocket,
The light measuring means is provided so as to be able to measure the intensity of light absorbed in the periodontal pocket from the light irradiation unit,
The control device stores data relating the intensity of light absorbed in the periodontal pocket and the depth of the periodontal pocket,
The depth of the periodontal pocket in which the tip terminal is inserted is quantified based on the intensity of light measured by the light measuring means and the stored data.

[Means of claim 4]
The optical examination device according to claim 4 is:
The light irradiation unit is provided in the periodontal pocket so as to be able to irradiate light of one or more specific wavelengths or broad wavelengths,
The light measuring means is provided so as to be able to measure the wavelength absorbed in the periodontal pocket,
The control device stores data associating the wavelength of light absorbed in the periodontal pocket with the properties in the periodontal pocket, the wavelength of light measured by the light measuring means, and the data to be stored. Based on the above, the property of the periodontal pocket in which the tip terminal is inserted is specified.

[0005]
[Operation and effect of claim 1]
The optical examination device according to claim 1 is:
A tip terminal provided with a light irradiator that emits light to the portion inserted into the periodontal pocket;
A light measuring means for measuring light from the light irradiation unit in a state inserted in a periodontal pocket;
Storage means for storing what has been measured in advance with respect to the relationship between the intensity of light measured by the light measuring means or the light absorption state and the state of the periodontal pocket;
From the light intensity measured by the light measurement means or the light absorption state,
Since it comprises a control device that identifies the state of the periodontal pocket based on the storage means,
The state of the periodontal pocket can be specified.

[Operation and effect of claim 2]
The optical examination device according to claim 2 is:
The light irradiation part is provided extending from the tip of the tip terminal inserted into the periodontal pocket in the longitudinal direction over the outside of the periodontal pocket,
The light measurement means is provided so as to be able to measure the intensity of light emitted from the light irradiation unit exposed to the outside from a periodontal pocket,
The control device stores data relating the intensity of light irradiated from the light irradiation unit exposed to the outside from the periodontal pocket and the depth of the periodontal pocket,
Since the depth of the periodontal pocket into which the tip terminal is inserted is quantified based on the intensity of light measured by the light measuring means and the stored data,
Periodontal pocket depth can be measured.

[Operation and effect of claim 3]
The optical examination device according to claim 3 is:
The light irradiation part is provided extending from the tip of the tip terminal inserted into the periodontal pocket in the longitudinal direction over the outside of the periodontal pocket,
The light measuring means is provided so as to be able to measure the intensity of light absorbed in the periodontal pocket from the light irradiation unit,
The control device stores data relating the intensity of light absorbed in the periodontal pocket and the depth of the periodontal pocket,
Since the depth of the periodontal pocket into which the tip terminal is inserted is quantified based on the intensity of light measured by the light measuring means and the stored data,
Periodontal pocket depth can be measured.

[Operation and effect of claim 4]
The optical examination device according to claim 4 is:
The light irradiation unit is provided in the periodontal pocket so as to be able to irradiate light of one or more specific wavelengths or broad wavelengths,
The light measuring means is provided so as to be able to measure the wavelength absorbed in the periodontal pocket,
The control device stores data associating the wavelength of light absorbed in the periodontal pocket with the properties in the periodontal pocket, the wavelength of light measured by the light measuring means, and the data to be stored. Since the feature of the periodontal pocket in which the tip terminal is inserted is specified based on
Properties such as periodontal pocket bleeding, oxygen saturation, and pulse wave can be measured.

[0006]
[Means of claim 2]
The electromagnetic diagnostic apparatus according to claim 2 is a tip terminal for scanning a living body to be examined, an electromagnetic wave supply means for supplying electromagnetic waves to the tip terminal, and absorption and reflection of electromagnetic waves supplied to the living body to be examined from the tip terminal. And having a detecting means for detecting shielding, transmission, excitation or reaction.
[0007]
[Means of claim 3]
The electromagnetic wave diagnostic apparatus according to claim 1 or claim 2
It has the attachment / detachment means which makes the tip terminal attachable / detachable.
[0008]
[Means of claim 4]
The electromagnetic wave diagnostic apparatus according to any one of claims 1 to 3,
It has a predetermined tip terminal.
[0009]
Operation and effect of the invention
[Operation and effect of claim 1]
The electromagnetic wave diagnostic apparatus according to claim 1 is supplied to the tip terminal for scanning the living body to be examined, the electromagnetic wave supply means for supplying the electromagnetic wave to the tip terminal, and the living body to be examined from the tip terminal. It is characterized by detecting the absorption, reflection, shielding, transmission, excitation or reaction of electromagnetic waves, so that the degree of absorption, reflection, shielding, transmission, excitation, and reaction of electromagnetic waves supplied to the object to be examined can be understood. You can see the type of organization and the presence or absence of disease. As an example, it is possible to identify substances such as detection of glucan such as α13, etc. If the electromagnetic wave is a radio wave, the change in moisture etc. You can In addition, the depth of periodontal pockets, the level of pus juice, and the degree of progression of the disease state can be detected. Furthermore, the difference between the pathological state and the healthy state of the organization can be detected.
[0010]
[Operation and effect of claim 2]
The electromagnetic diagnostic apparatus according to claim 2 is a tip terminal for scanning a living body to be examined, an electromagnetic wave supply means for supplying electromagnetic waves to the tip terminal, and absorption and reflection of electromagnetic waves supplied to the living body to be examined from the tip terminal. In addition to the features of the apparatus of claim 1, further automatic detection and more accurate detection can be performed.
[0011]
[Operation and effect of claim 3]
The electromagnetic wave diagnostic apparatus according to claim 1 or claim 2
Since it has the attachment / detachment means which makes the tip terminal attachable / detachable, infection can be prevented or it can be replaced immediately even if the tip terminal deteriorates.
[0012]
[Operation and effect of claim 4]
The electromagnetic wave diagnostic apparatus according to any one of claims 1 to 3,
Since it has a predetermined tip, it can be used for various examinations and has a good feeling of use.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Next, the electromagnetic wave diagnostic apparatus of this invention is demonstrated based on the Example or modification shown in FIGS.
[Configuration of Example]
[0014]
First Embodiment A first embodiment discloses an examination apparatus that examines an object by supplying an electromagnetic wave to a tip terminal and detecting absorption, reflection, excitation, and reaction of the examination object with respect to the sensor means.
Here, FIG. 1, FIG. 2, FIG. 3, and FIG. 4 are examples of explanatory diagrams of the electromagnetic wave examination apparatus, and FIG. 5 and FIG. 6 are examples of the tip terminal.
[0015]
In FIG. 1, the electromagnetic wave from the electromagnetic wave irradiation means 2 is reflected from the internal reflection optical path 3 by the electric power supplied from the input means 1, passes through the sensor means 4, is reflected by the reflection means 5, and again passes through the sensor means 4. The electromagnetic wave is detected by the detection means 7 after passing through and reflecting inside the internal reflection optical path 3. The signal converted by the detection means 7 is amplified by the amplification means 8 and output as an external output. At this time, the amplifying means 8 may be a buffer or rarely an attenuator. Here, the holding means 6 holds the electromagnetic wave irradiation means 2 and the detection means 7. In this embodiment, the holding means 6 is shielded so that the detection means 7 does not receive the direct irradiation wave of the electromagnetic wave irradiation means. 1, 2, and 3, the tip terminal means the sensor means 4 and the reflection means 5. In FIG. 4, only the sensor means 4 is referred to as a leading terminal.
[0016]
When this apparatus is used, the gripping means 9 is held by hand, and the sensor means 4 at the tip is inserted into a measured object such as a periodontal pocket or an aqueous solution. After use, the tip is removed by the holding means 10 to prevent infection, and the autoclave is disinfected or discarded.
[0017]
Here, the optical circuit may use the optical path changing means 12 as shown in FIG. 2, FIG. 3, and FIG. 4, so that there is no stray light, or the electromagnetic wave irradiation means 2 with the input means 1 as the waveguide 13 path. Or an optical element such as a lens may be used at the position of the electromagnetic wave irradiation means 2.
Here, the electromagnetic wave emitted from the electromagnetic wave irradiation means 2 reflects inside the internal reflection light path 3 and passes through the sensor means 4, is reflected by the reflection means 5, passes again through the sensor means 4, and passes through the internal reflection light path 3. Is reflected to reach the detection means 7. At this time, there are electromagnetic waves that pass through the sensor means 4 and electromagnetic waves that are emitted. The ratio between the passing electromagnetic wave and the electromagnetic wave emitted to the outside depends on the material of the sensor means 4 and the material of the measured object in contact with the sensor means. This means that the detection means detects changes in physical quantities such as electromagnetic wave intensity, wavelength, and phase that are absorbed (released) from the tip to the outside such as a tissue. In other words, the sensor means 4 This suggests that the quantity and quality of an object in contact with can be observed by changing the current of the external output.
[0018]
In the probe disclosed in this embodiment, the cross-section of the tip portion is mainly circular or elliptical (it is not necessary to stick to this shape and may be an n-gonal shape (n> = 3)), and the tip portion of FIG. The tip of FIG. 5 is a probe with a dome shape or sphere formed on a cylinder, or a probe with a dome or sphere tip processed on a truncated cone. Here, the tip may have any shape such as a plane, a concave, a convex, a sphere, and an elliptical sphere as long as there is even a slight reflection. 4 is particularly suitable for teeth and the like, and FIG. 5 is suitable for examination of periodontal pockets and the like. For tip terminals used for periodontal pockets, etc., as shown in Fig. 5, the tip of the tip terminal is applied with a reflective coating as shown in Fig. 5, and when using the side, only the tip part is not used and only the tip part is used. There are cases where both the tip portion and the side portion of the tip terminal are used. Here, the black portion is a total reflection coat, the partial reflection coat, or the like, and the white portion is an uncoated portion. At this time, the thickness and material of the coat may be any as long as they meet the gist of the present invention. In other words, any structure may be used as long as electromagnetic waves propagate inside the gripping part or the like, and internal electromagnetic waves can reduce or eliminate interference and leakage with the outside. For example, a metal film or metal color paint may be applied or plated, white, red or black paint may be used, or a resin or other material with a different refractive index may be covered. good.
[0019]
As an example, since the h-terminal of FIG. 5 can examine absorption over the entire circumference, the sensitivity is high, and a in FIG. 5 can be measured linearly with respect to a certain place such as along the inner epithelium or the side of the pocket. B in FIG. 5 has an inflection point (line) or threshold value in the insertion position (velocity) vs. the measured value, such as the output changing when a certain range is exceeded, so the distance is calibrated and confirmed on the inflection point (line), etc. Can do. C, d, e, and f in FIG. 5 are those in which the output increases and decreases nonlinearly. In particular, c and e have inflection points (lines) or threshold values in the conversion function. In Fig. 5c, there is an inflection point near the tip, so if this distance is about 2mm ± 1mm, the periodontal pockets of healthy and sick people can be quickly identified and the pocket length can be measured. . Further, e in FIG. 5 has an inflection point in the direction of the gripping part, so that measurement overflow or the like can be detected.
[0020]
In FIG. 5f, a large output can be secured even in a shallow pocket. 5d of FIG. 5 can measure a deep pocket with high accuracy. Since g in FIG. 5 is sensitive only to the tip, diagnostic information can be obtained regardless of the pocket depth. This probe can be used for safe probing that does not puncture the test tissue, especially if a specific wavelength is used for the epithelial tissue at the pocket bottom. In FIG. 5, h can be detected all around the front terminal and has high sensitivity. In this case, since the sensitivity of the tip portion of the tip terminal tends to be high, it is suitable for diagnosis. 5, a, b, c, d, and e in FIG. 5 are used to measure the depth of an object to be measured such as a pocket, and g and h in FIG. 5 are diagnosed. Suitable for property inspections. The tip terminals in Fig. 1, Fig. 2, Fig. 3, etc. have an intermediate character and are suitable for both depth and examination, but the operator decides which tip terminal is to be used for which purpose. It ’s good. Further, the area, shape, etc., of the reflective coating of the tip terminal may be any shape, area in accordance with the spirit of the present invention.
[0021]
Here, in FIG. 1, FIG. 2, FIG. 3 or FIG. 4, the electromagnetic wave irradiation means 2 is composed of a light emitter made of visible light, LED, LD or the like that outputs at least one wavelength.
[0022]
Then, the electromagnetic wave irradiated from the electromagnetic wave irradiation means 2 is repeatedly reflected in the internally reflected light path 3 made of a transparent resin having a metal coating on the surface, and the electromagnetic wave is guided to the sensor means 4. Of course, the internal reflection optical path 3 is not necessarily required, and an optical path that propagates without reflection may be used as the internal reflection optical path. These are electromagnetic wave supply means. The tip sensor means 4 also repeats internal reflection due to the difference between the refractive index of air and the refractive index of the resin, and finally returns to the detecting means 7. The detecting means 7 can detect the return electromagnetic wave (light) from the tip.
[0023]
Here, the detector uses a photodiode, a phototransistor, a photomultiplier tube, or the like. The detecting means 7 uses an amplifying means 8 (gain | G |> 0) in accordance with an input level of a display device in the subsequent stage, an A / D converter, or the like. If level adjustment is unnecessary, the amplifying means 8 is not necessary. This output level indicates the degree of absorption of an object that has contacted the tip terminal.
[0024]
Here, pocket measurement is disclosed as a first usage example. This tip is inserted into the periodontal pocket. Periodontal pockets become deeper as periodontal disease progresses. In addition, when the disease progresses, such as acute, secretions such as bleeding and drainage occur.
[0025]
First, an example of using the present invention to measure the depth of the former pocket will be disclosed. Here, the tip terminal may have a normal so-called probe shape, but it is better to adopt a round probe shape whose tip does not damage the pocket. When the tip terminal having the above-described mechanism is inserted into the periodontal pocket, the absorption is increased by the degree of insertion. The degree of absorption is defined as the pocket depth. Specifically, a calibration curve or function equation of depth versus absorption is obtained in advance with an aqueous solution or the like, and an inspection is performed based on the calibration curve or function equation. More specifically, the conversion means consisting of a calibration curve or a functional equation is stored in the computer, and the depth with respect to the degree of absorption is displayed on a display device or the like. Here, the pocket depth error due to the difference in the substance in the pocket may be corrected based on the next in-pocket component inspection function. In this case, the electromagnetic wave used may be any wavelength such as ultraviolet, visible, and infrared.
[0026]
Also especially H₂O near 3300 cm −1 or 1600 cm −1 may be used. When electromagnetic waves are in the infrared region, CO₂Lasers, semiconductor lasers or Glover light sources may be used, but lasers are convenient. Here, when a multi-wavelength light source such as a lamp is used as an electromagnetic wave source, when two or more specific wavelengths are used, or when a specific single wavelength is used, coherent light is further used, and non-coherent light is used. -There are cases where rent light is used or combinations thereof. As an example, when the detection intensity difference between two adjacent wavelengths is used as the absorption intensity, pocket measurement that is resistant to disturbance can be performed. Specifically, the electromagnetic wave light source in the above-described embodiment or modification is a two-wavelength or multi-wavelength light source LD or LED. Similarly, the detecting means uses two or more wavelengths. And the output of this detector is compared with a comparison means, and the change of the value is made into the absorption change of the sensor part 4 in a front terminal. If a multi-wavelength light source such as a lamp is used as the electromagnetic wave source, errors due to absorption intensity at each wavelength can be easily averaged, and disturbances can be averaged to measure the pocket depth. When at least one specific wavelength is used, it is suitable for the examination described later. In the case of coherent light, a single wavelength can be easily formed, an optical circuit can be easily formed, and there are cases where it is suitable for examination, and the light intensity distribution inside the tip terminal can be easily calculated. Non-coherent light is suitable for pocket measurement because the tip-end light distribution is easily averaged, and can also be used for examination as described later. Further, the inflection point may be provided by making the tip light distribution uniform by a plurality of wavelengths to reduce the pocket measurement error, or conversely, by increasing or decreasing the electromagnetic wave intensity only at a specific part.
[0027]
Next, the component inspection function in the pocket is disclosed. Periodontal disease causes bleeding and drainage when the disease progresses, and the inside of the periodontal pocket when it is healed depends on the problem of detection sensitivity. good. (Of course, it may be stricter, or the absorption intensity may be corrected when measuring along the gingiva.) In short, it is only necessary to distinguish between a pathological state and a relatively healthy state. It is only necessary to find out the difference from the components, bacterial components and inflammatory substances (enzymes, etc.).
[0028]
As an example, H₂Adopting 2 wavelengths of either 660 nm or 870 nm of hemoglobin, or both of them in the electromagnetic wave irradiation means, in the vicinity of 3300 cm-1 or 1600 cm-1 of O, and the difference is defined as the degree of bleeding . Here, any index may be selected and used for any diagnosis according to the gist of the present invention, such as blood, plasma component, bacterial component, inflammatory substance (enzyme, etc.) may be used as an index. . As an example, a wavelength in the range of 850 nm to 900 nm, or a wavelength per 1 μm is used as an index of blood.
Furthermore, here, when two wavelengths of 660 nm and 870 nm are used, the oxygen saturation may be measured based on the ratio of the two wavelengths. Specifically, if a known oxygen saturation measurement function is installed in a conversion circuit such as a computer, and the detection outputs at two wavelengths of 660 nm and 870 nm of the present invention are converted by the conversion circuit and displayed on a display device or the like, the oxygen saturation is obtained. The degree can be detected. Further, the background correction of the detection output may be performed. This improves accuracy when done in the same way in any example. Moreover, it is good also as a pulse wave with the change of either or both of 2 wavelengths.
[0029]
As another example, a dental caries examination is disclosed. Here, when the tip terminal is applied to the object to be measured (here, a tooth) as shown in FIG. 4, electromagnetic waves are absorbed by the object at the interface between the object and the probe, and the internal reflection component is reduced. Specifically, the absorbency when a probe is applied to a healthy tooth and the absorbency when applied to an object such as a carious tooth are different.
[0030]
Healthy teeth do not stick. That is, since the contact area is small and only a hard tissue such as an apatite crystal is used, electromagnetic waves are not absorbed easily from the tip. (If a specific wavelength is further selected, the absorption is further reduced.)
[0031]
The pathological tooth sticking tooth, that is, the tooth having a stick fisher, has a large contact area, and organic components other than apatite due to tissue destruction, that is, H₂O, C-H, C-O, etc. are increasing. Therefore, the absorption from the tip terminal shows different absorption in the morbid state and the healthy state. Here, if a wavelength other than the apatite absorption wavelength is selected, absorption at a pathological site increases. The electromagnetic wave source used visible light, but H is infrared light.₂Wavelengths near 3300 cm-1 or 1600 cm-1 of O, or less than 3000 cm-1 such as CH, or near 1400 cm-1 may be used, and sensitivity using thousands of centimeters of CO-1 is also used. May be raised.
[0032]
Furthermore, a wavelength in the vicinity of 1038 cm −1 and 1034 cm −1 unique to α13 bonding may be used. In this case, the caries risk at the examination site is revealed. At this time, the moisture of the plaque may be measured at the wavelength, and the measurement wavelength may be corrected by the correction means, thereby reducing the absorption wavelength measurement error of C-O. Of course, the vicinity of 1015 cm-1 of α16 glucan and the vicinity of 1055 cm-1 of fructan may be used similarly. Where H₂Caries risk by comparing peak intensities of glucan and fructan using O as the internal standard around 3300cm-1 and 1600cm-1 of the peak or perhaps 1080cm-1 of the phosphate group in the polysaccharide peak group May be displayed. As an example, an absorption near 1080 cm-1 is compared with an absorption near 1038 cm-1, and the value is 1.0 (when the former is A and the latter is B / A, that is, the intensity near 1080 cm-1 If the intensity near 1038 cm −1 is greater.), The risk of caries is increased.
[0033]
Here, if the wavelength of the supplied electromagnetic wave, for example, 8.8 μm to 10.4 μm or 100 nm to less than 300 nm is set as the apatite absorption wavelength, the absorption at the pathological site is reduced compared to the healthy site. In this way, any wavelength can be used as long as the wavelength that changes before destruction (healthy part) and after destruction (pathological part) of the index tissue is selected, and pathological organization such as abscess and tumor is healthy. You may probe with the difference in the electromagnetic wave absorption characteristics with the knowledge. When using infrared light such as these, the electromagnetic wave source is CO₂Use laser or Glover light source.
[0034]
Although a continuous wave is used, a pulse wave may be used. In this case, the re-radiation wave may be observed, or the fluorescence of the tissue may be observed during the rest period of the pulse. Specifically, a known electromagnetic wave source that can irradiate a pulse waveform may be used. A plurality of diagnoses may be performed simultaneously using a combination of the various wavelengths described above. H as an example₂O, CH and PO₄For example, an effect determination after cleaning is performed on a tooth cleft for which determination of sealant or restoration is divided. Specifically, the tooth cleft is cleaned with a Robinson brush and dried with air. After that, H₂O, CH and PO₄Inspect using the wavelength of. At this time H₂A large amount of O or CH, PO₄If there is only a small amount, it is not a sealant but a repair.
[0035]
[Effects of Example] The periodontal pocket depth, which has been conventionally measured with a gauge or the like, can be measured, and the progress state of a medical condition can be determined. In addition, it is possible to diagnose early occlusal caries and smooth caries that are difficult to understand by visual recognition or X-ray images. It can be used to diagnose components of body fluids such as saliva, blood, or gingival crevice. In addition, the amount of oxygen supply such as periodontal tissue can be known, and the risk of periodontal disease can be determined. Diagnosis of lesions including abscesses and tumors becomes possible.
[0036]
[Second Embodiment]
The second embodiment discloses an example using storage means. The external output of the apparatus disclosed in the first embodiment is connected to the storage means. As an example, external output is A / D converted and stored in a memory inside a general-purpose computer. Here, the use wavelength of the electromagnetic wave irradiation means is set to 850 nm (or 800 nm to 900 nm or the like). And the value before inserting a sensor part in a periodontal pocket is memorize | stored in a memory | storage means. Thereafter, the values taken out from the periodontal pocket are held in the storage means, and both of them are displayed on the display means, or compared on the comparison means, and the values are displayed on the display means. At this time, if blood is attached to the sensor means 4, the value changes. This change is used as an index of bleeding.
[0037]
Here, you may use this apparatus with respect to deposits other than blood. As an example, if the wavelength of glucose CO synthesis peak top value is 1026 cm −1 (there is a shift depending on the water content, water correction may be performed. In this case, the blood glucose level is about 1034 cm −1 to 1000 cm −1). Can be diagnosed.
[0038]
[Effect of Example] The property of the object to be measured can be diagnosed.
[0039]
[Third embodiment]
The third embodiment discloses an electromagnetic wave diagnostic device as a depth detection device such as a pocket probe.
[0040]
In FIG. 6, an electromagnetic wave having a wavelength of at least one wavelength is emitted from the tip terminal, and this is visually observed or detected by a detection means or the like to measure the depth. Here, in FIG. 6a, electromagnetic waves having respective wavelengths of λ1, λ2, and λ3 are emitted from the tip terminal from a circular-like window that is not provided with a reflective coating. The tip terminal (probe) in FIG. 6b has a light emission band in a band shape. Here, these windows are coated to pass a specific wavelength. Specifically, red paint is applied to λ1, green paint is applied to λ2, and blue paint is applied to λ3. Similar effects may be obtained by using an optical process such as a dielectric multilayer film, or other bandpass filters, highpass filters, and lowpass filters may be employed. Then, an electromagnetic wave is irradiated or enters from the direction of the arrow, passes through the window here, and only the electromagnetic wave of each wavelength is emitted from the window.
[0041]
6c and 6d show a tip terminal (probe) having a dispersive element. The tip terminal disperses the wavelength component of the incident electromagnetic wave and projects various wavelengths onto the tip terminal. Specifically, an electromagnetic wave is irradiated from the direction of the arrow, and the electromagnetic wave is transmitted through a hologram element or a prism as a dispersion element, dispersed for each wavelength, and supplied to the tip terminal. Thereby, the spectrum-decomposed electromagnetic wave is projected on the surface of the tip. If white light is used, a light element such as rainbow is projected onto the tip.
[0042]
These tip terminals may be provided at the tip of FIGS. 1, 2, 3, and 4 or may be used with only a gripping portion installed on the tip terminal. Then, the tip terminal of this examination device is inserted into the periodontal pocket and used. Specifically, since the visible wavelength window is different depending on the depth of the periodontal pocket by visual observation or the like, the depth of the periodontal pocket can be easily measured even in a dark oral cavity. On the contrary, the transmission of the inserted part may be observed. These are examples of shielding and transmission.
[0043]
As another example, as shown in FIG. 7, the detection means may use an image sensor such as a CCD camera. Here, the tip terminal of FIG. 5 or FIG. 6 is provided at the tip (4, 5 in FIG. 7), and this is measured by the imaging means 7 such as a CCD camera. Specifically, the front terminal is imaged by the imaging means, the video signal is A / D converted, and the video data is transmitted to the computer. The transmitted video signal is detected by known light spot recognition and light spot tracking means. The light spot that is not detected at this time represents the depth of the periodontal pocket. More specifically, the measured value is the depth (length) of the wavelength that can be confirmed at present, and the pocket depth can be easily measured. More specifically, in FIG. 6a or b, as an example, λ1 is not visible, and if λ2 is visible, the length of λ1 becomes the pocket depth. Of course, you may look at the middle length of (lambda) 1. Here, 3, 4, and 5 in FIG. 7 may be made flexible by using an elastic body such as an optical fiber, or may be formed of a rigid resin, glass, optical crystal, or the like.
[0044]
Here, λ1, λ2, and λ3 may be changed in wavelength, wavelength band, number, shape, and the like according to the purpose. It may be λn. (N> 0)
[0045]
[Effect of Example] Specifically, since the visible wavelength window differs depending on the depth of the periodontal pocket, the depth of the periodontal pocket and the like can be easily measured even in a dark oral cavity.
[0046]
[Modification] The material of the tip terminal, that is, sensor means 4, reflection means 5, internal reflection optical path 3, etc. is PMMA, polyolefin, polyamide, polyester, polyether, polyimide, polyamideimide, flame resistant elastomer, silicone, fluorine resin, nitrogen Phosphorous resin, thermosetting polymer, phenol resin, epoxy resin, polyene, polydiacetylene, polyazomethine, main chain network polymer, polytriazine, polyparabanic acid, polyhydantoin, polydistyrylpyrazine, polycarbonate, polyurethane, sulfone polymer, vinyl , Vinyl polymer, PEEK, polyetheretherketone, cellulose resin, urethane, xylene resin, melamine formaldehyde, polyethylene ethylene copolymer, acrylic nitrile, cellulose, flammable resin, Neoprene, furan resin, ABS resin, ACS resin, AES resin, ASA resin, ABS / PVC resin, PC / ABS alloy, PC / AES alloy, EVA resin, FRP, SAN, polytetrafluoroethylene, polyvinylidene chloride, polychloro Trifluoroethylene, polyfucavinylidene, liquid crystal polymer, mica, alkyd, amino, polysulfone, polyethersulfone, polyfucavinyl, polyacetal, polyphenylene oxide, polyethylene oxide, polyethylene phthalate, polyethylene terephthalate, carbon fiber, glass fiber, Glass, silica, cotton, hemp, ramie, wool, silk, styrene graft, polystyrene, rayon, polynosic, cupra, acetate, triacetate, promix, nylon, vinylon, vinyl Redene, polyvinyl chloride, polyester, acrylic, polyethylene, polypropylene, polyclar, benzoate, polyoxymethylene, polybismaleimide, bismaleimide triazine, EVA saponified product, chlorinated polyether, chlorinated polyethylene, diallyl phthalate, ethylene-α- Olefin copolymer, ethylene-vinyl acetate-vinyl chloride copolymer, ethylene-vinyl chloride copolymer, polyarylate, polyallylsulfone, polybutadiene, polybutylene, polybenzimitazole, ionomer, olefin vinyl alcohol copolymer, aroma Polyester, methacryl-styrene copolymer, nitrile resin, liquid crystal resin, petroleum resin, polybutylene terephthalate, polyetherimide, polyetherketone, polyethernitrile, polythioe -Tersulfone, polyethylene naphthalate, polyethylene terephthalate, thermoplastic polyimide, polyamino bismaleimide, polyketone, polymethylpentene, norbornene, porolefin, polyphenylene ether, polyphenylene sulfide, unsaturated polyester, vinyl ester epoxy, polyvinyl acetate, styrene copolymer Coalesced, butadiene-styrene, polyvinyl acetal, polyvinyl alcohol, acrylic modified polyvinyl chloride, thermoplastic elastomer, phthalic alkyd, modified alkyd, amino alkyd, urea melamine, melamine, alcohol-soluble phenolic resin Does not damage the measured object compared to the terminal. )
[0047]
Rubber, beech N, styrene butadiene rubber, butadiene rubber, acrylonitrile butadiene rubber, ethylene propylene rubber, butyl rubber, acrylic rubber, chlorosulfonated polyethylene rubber, silicone rubber, fluorine rubber, polysulfide rubber, natural rubber, isoprene rubber, styrene rubber Olfin rubber, ester rubber, urethane rubber, vinyl chloride rubber, butadiene rubber, amide rubber, (the above does not damage the object to be measured compared to metallic tip), quartz, Silica, glass, BK7, BaF₂, CaF₂, Various optical crystals, various optical glasses, optical propagators, electromagnetic wave propagators, ATR crystals, germanium, zinc selenium, ZnSe, CdTe, CsBr, Csl, SiO₂, H₂O, Si, LiF, MgF₂, KBr, KCl, NaCl, KRS-5, ZnS, alumina, zirconia, titania, various ceramics (they are functional because they easily transmit specific electromagnetic waves).
Or any combination thereof may be employed. Of course, you may use as a material of another part. Here, these materials may be solid, gas, or liquid. At this time, when a gas or liquid is used, the periphery thereof may be covered with a solid, or a fluid may be used as a leading terminal. Specifically, electromagnetic waves (light rays) are conveyed to a gas component generated by an air blower, or a liquid such as water is ejected by an ejecting means, and the electromagnetic waves are conveyed in the flow for use. In this case, since the operation of cleaning and drying the periodontal pocket and the propagation of electromagnetic waves can be performed, the electromagnetic waves (light rays) permeate deeply. These functions may be used for a known water pick or a three-way syringe. Moreover, you may use for parts other than a front terminal.
[0048]
Here, in the case of polymers such as resins, high performance by adding functional groups, copolymerization, bridge polymerization, block polymerization, graft polymerization, polymer blend, intermolecular crosslinking, single crystallization, polymer alloy, glass Higher performance materials may be adopted by fiber reinforcement, filler addition, and compounding at all levels from the atomic level to the material level. Examples include calcium carbonate, talc, glass beads, aluminum hydroxide, magnesium hydroxide, diatomaceous earth, silica, clay, clay, kaolin, barium sulfate, titanium oxide, carbon black, metal powder, graphite, shirasu balloon, potassium titanate, wax Fillers or auxiliary materials such as lastite, carbon fiber, mica, glass and asbestos may be added.
[0049]
In some cases, the tip terminal may be made of porcelain, ceramics, ferrite, magnetic material, metal, organic compound, or the like. Furthermore, the material of the tip may be a hybrid structure starting from the above materials, a polymer alloy, or a single structure with a single composition.
[0050]
In the above embodiment, the exchange means 10 is made by a fitting force, but any means such as a screw, a screw, a groove, a key and key way, various chuck structures, and a one-touch lock may be used. Moreover, you may employ | adopt attachment / detachment auxiliary tools, such as chuck removal. For example, as a means for attaching the intermeshing force, a simple column or a double taper structure as shown in FIG. 7 may be used.
The gripping part may be in the shape of a grip, or it may have any shape and characteristics according to the fingers of the present invention, such as providing anti-slip or the like with an elastic body, or providing grooves or ledges for appropriately fixing the fingers. But it ’s okay. When passing electromagnetic waves, a material suitable for the wavelength may be selected. As an example, a metal cavity or a cavity in which a gas, liquid, or solid is inserted may be used. This may be adopted for the tip terminal or the waveguide. More specifically, a metal pipe such as iron or stainless steel is used for the gripping part, and a waveguide is connected to one end of the pipe, and an electromagnetic wave (light beam) is propagated through the end to supply the electromagnetic wave to the tip terminal. is there. Here, a liquid such as water or oil may be put in this. Here, similarly, the tip terminal may be formed of liquid or gas.
[0051]
Further, the tip part may be directly attached to the grip part, omitting the grip part tip part connecting means, or may be directly or indirectly attached to any part of the grip part. Furthermore, the tip part may be attached to both sides of the grip part, and the number of tip parts and the number of grip parts may be plural.
[0052]
The tip shape may be a mono-angle or a bi-bending shape that is more than a bi-angle. The angle may be any angle such as 0 to 360 degrees. Moreover, you may employ | adopt the structure which changed the angle continuously with the screw | thread etc. FIG. The cross section of the gripping portion and the tip portion may be any shape such as a circle, an ellipse, or a polygon.
The material of the tip portion, the tip terminal attaching means, the gripping means 9 and the like may be any material such as metal, resin, porcelain.
[0053]
Tip, tip, root planing tip, tooth cleaning tip, crown polishing tip, pocket probe, various filling tips, various burners, various carvers, various mirrors, various spatula, various brushes, various water picks, various air Dental treatment such as a blower, an electric dental pulp examination chip, an electromagnetic wave supply chip, and an applicator, and a preventive instrument (tip terminal) may be employed.
[0054]
In the above embodiment, a tip terminal such as a sharp needle as shown in FIG. 4, a cylinder with a dome shape or a sphere shape as shown in FIG. 5, or a probe with a dome or a spherical tip processed on a truncated cone is used. Although disclosed, it may have any shape. Here, depending on the shape of the tip or the properties of the waveguide, the electromagnetic wave density may increase in a specific portion. Therefore, the shape may be set so as to correct this or use it in reverse. As an example, if a laser is used as a light source, a polarization-maintaining fiber is used as a waveguide, and a concave mirror curve is used as a tip, the reflected beam density can be increased in a specific portion. If this part is a part without a reflective coat, a favorable examination can be performed. Conversely, such a portion may be masked with a reflective coat, or uniform absorption may be obtained as a dispersed electromagnetic wave path. Here, depending on the object to be measured and the use terminal, the degree of reflection from the organization may be detected by the detecting means. As a specific example, the detection level when held in the air is used as a reference value and compared with the insertion level as needed. At this time, when held in the air, electromagnetic waves are emitted from the tip terminal and there are no reflected electromagnetic waves from the surroundings. Next, if inserted into a tissue having a highly reflective metal crown or implant, reflected electromagnetic waves from the tissue may be generated. The shape and properties of the probe are not limited to those shown in FIGS. 5 and 6, and any probe may be used. An optical element is attached to the probe's electromagnetic aperture to diffuse, converge, collimate, etc. It may be given to the organization. Furthermore, the applied electromagnetic wave may be used for tissue reaction, excitation, internal observation, and the like.
[0055]
1, 2, 3, 4, 5, etc., with a replaceable tip, a root planing tip, tooth cleaning tip, crown polishing tip, pocket probe, and various fillings instead of a probe Chips, various burners, various carvers, various mirrors, various spatula, various brushes, various water picks, various air blowers, electric dental pulp examination chips, electromagnetic wave supply chips, any one of dental treatment and preventive instruments such as applicators, or Whether the combination is used as the front terminal is not particularly limited by the freedom of the operator or manufacturer. Further, in this case, the attachment of the tip terminals has a shape according to the modified example of the embodiment of the present invention, and is attached to the tip terminal attaching means by the same operation. If these tip terminals are attached, various diagnosis, treatment, and prevention can be performed. In addition, since the tip terminal can be easily discarded, it is very clean such as preventing hospital infection. Further, if the gripping part and the gripping part tip part connecting means are made of a material that can be autoclaved such as stainless steel and engineering plastic, it is further clean.
[0056]
Alternatively, a blade may be attached to the tip to provide a bladed probe.
[0057]
Irradiation or supplied electromagnetic waves may be polarized with linearly polarized light, circularly polarized light, elliptically polarized light, or the like. Moreover, you may employ | adopt as a detector. By these, the nature and depth of the examination organization can be controlled, and the influence of stray light can be suppressed. Further, a polarizing beam splitter or a wavelength plate may be used together with it. In this case, the return electromagnetic wave can be efficiently captured by the detection means, absorbed at the tip terminal efficiently, or the change in polarization of the object to be measured can be captured. Further, as shown in the optical circuit example of FIG. 2, a sensitivity may be increased by providing a lens or the like in front of the detector. In this case, the surface to be observed may be set anywhere from the surface (end surface) through which the electromagnetic wave enters from the electromagnetic wave source, such as a waveguide or a front terminal, to the front end of the front terminal. It can be set anywhere between. At this time, stray light may be reduced by using the incident surface of the electromagnetic wave as a slope. As another example of a highly sensitive optical path, the electromagnetic wave source is linearly polarized and a polarizing beam splitter is used as the beam splitter. In this case, stray light from a surface (end surface) where an electromagnetic wave such as a waveguide to the detector or a leading terminal enters from the electromagnetic wave source is reduced, and the sensitivity and stability can be improved. As another circuit, a phase conjugate wave is generated from the electromagnetic wave irradiation means and injected into the tip terminal, and if the detector is set at an optical distance equivalent to the point of origin, stable and sensitive measurement without disturbance (with the tip terminal) Absorption intensity measurement). As another circuit, only the center of the beam splitter may be transmitted, and the periphery thereof may be reflected to reduce stray light. Further, the tip terminal may be treated as a principal wave generating crystal such as a harmonic wave crystal, and the injection wavelength and the reflection wavelength may be processed at different wavelengths. In this case, propagation of stray light to the detection system is reduced.
[0058]
In the above embodiment, the metal coating (reflective coating) is applied to the grip portion. However, this range may be anything, and the coating material and its electromagnetic properties may be changed as appropriate. Examples are aluminum, gold, silver, chromium, MgF₂For example, a dielectric multilayer film or the like is coated or plated. Although loss is large, enamel, lacquer paint, etc. may be coated as an inexpensive coat. In that case, a color having a high reflectance may be used according to the wavelength used. Further, the reflective coating and the non-coated portion of the tip terminal as shown in FIGS.
[0059]
Frequency modulation, amplitude modulation, phase modulation, 1 / f fluctuation, etc. may be used.
[0060]
The wavelength of the electromagnetic wave emitted by the electromagnetic wave emitting means may be any wavelength such as visible, ultraviolet, infrared, radio wave, etc. The wavelength used corresponds to the disease and any wavelength is used according to the gist of the present invention. You may do it. Further, the irradiation port may be provided anywhere, and any introduction path may be used as long as it is within the spirit of the present invention. Here, the waveguide 13 may be a fiber-like object or a mirror-like object. Moreover, what is necessary is just to use according to the wavelength of an electromagnetic wave source, when using a waveguide. For example, the infrared band uses silver halide or the like, and the visible or ultraviolet band uses a fiber such as plastic or quartz. The waveguide may be either a wavefront storage type or a non-conservation type, and may be selected in consideration of the purpose of use, price, sensitivity, and the like. Similarly, a phase conjugate type may be adopted. The coupling means to the waveguide, the coupler to the gripping part, etc. may be anything as long as electromagnetic waves propagate. Here, the end face may be any object such as parallel, concave, convex, oblique, or the like. Further, a light propagation medium such as a gel may be used as a coupler or coupling means for coupling. In this embodiment, the waveguide is used as the electromagnetic wave source. However, the electromagnetic wave source may be built in the holding part without using the waveguide. Conversely, the structure of the waveguide 13 may be employed for the gripping means 9 or the tip terminal (tip portion). That is, the holding part 9 and the tip terminal (tip part) may be a waveguide structure such as an optical fiber, and a structure in which only the reflective coating is applied to the tip part. In this case, the grip portion is less likely to be errored if it is painted, coated, or coated.
[0061]
The power source may be a battery or a capacitor, a commercial power source, a built-in gripper, or an external power source. At this time, the battery may be a primary battery or a secondary battery. In the case of a secondary battery, an inductive charging mechanism may be employed. Further, a fluorescent material may be used as a light source. At this time, the fluorescent material may be excited and this light emission may be used.
[0062]
The switch can be any switch. As an example, a slide switch or a push switch may be employed for the grip portion, a foot switch, a switch using a sign language input, or the like.
[0063]
The tooth type (part) is displayed on the computer screen, and the examination part and the tooth type (part) on the screen are associated with each other to examine the pocket depth, caries (C1 to C4), bleeding, or drainage. Also good. As an example, an electromagnetic wave source or detection means is built in the gripping part. At this time, the waveguide may or may not be used. Further, the sensitivity of the detector can be easily increased without using a lens or the like.
[0064]
As a means for irradiating a tissue such as a tooth with electromagnetic waves, a laser beam generator may be used as an example, or other means may be used as long as the electromagnetic waves can be irradiated. Specifically, laser light, natural light, medium waves such as radio waves, microwaves, X-rays, and sound waves, and any waves such as ultraviolet rays, infrared rays, and visible rays may be used. Moreover, a coherent wave may be sufficient and it does not need to be a coherent wave. Here, the laser is NdYg, CO₂Any of the oscillation modes such as He—Ne, various Yag lasers, various xenon lasers, various argon lasers, excimer lasers, dye lasers, and semiconductor lasers may be used. Of course, a wavelength tunable laser such as a grating or a harmonic crystal may be used. Of course, the line width may be used for various light sources or may not be used.
[0065]
When the electromagnetic wave is a radio wave, an antenna, a waveguide, an electromagnetic field lens, or the like may be used. Infrared light may be received by an antenna. As the light source, any electromagnetic wave source such as a global light source, a lamp, or an LED may be used as long as it is suitable for the present invention. For example, for ultraviolet rays, an ultraviolet lamp, a KrCl laser, a KrF laser, or the like may be used.
[0066]
Here, an example using radio waves will be disclosed. As an example, a probe portion (tip terminal portion) is disclosed in FIG. That is, radio waves may be used to measure the pocket depth. In this case, the mechanism is different from the light wavelength band. Specifically, in this case, either one or both of the tip terminal and the gripping part is made of an electromagnetic wave propagating material (for example, ferrite or metal is a probe material), and this is connected to an electromagnetic wave coupling means such as a coil. Then, the waveguide 9 is formed with a copper wire or the like. As a more specific example, a coil having a diameter of about 10 mm and having one or two turns is manufactured and installed so as to be wound around the gripping portion. This high frequency circuit is defined as one side of the high frequency bridge. By detecting an energy change such as a current or frequency change of the bridge circuit, the degree of absorption of the electromagnetic wave into the organization is obtained. Of course, the degree of electromagnetic wave absorption may be determined by measuring re-radiation waves without using a bridge circuit, or by capturing energy fluctuations in a circuit for supplying electromagnetic waves. In those cases, the output stage may be a floating amplifier, and the propagation of high-frequency energy to the tip terminal may be directly coupled from a high-frequency generating means (electromagnetic wave source) and supplied. Something like that may be used. Furthermore, although about 200 MHz was used as the driving frequency, this frequency may be any value as long as it falls within the spirit of the present invention. As another method of using radio waves, the carrier wave may be an optical band and the modulated wave may be a radio wave. In this case, for example, a known optical modulation element may be inserted after the electromagnetic wave source. At this time, detection using a reference wave at the detector or detection not using it may be performed. When a reference wave is used, either heterodyne detection or homodyne detection may be used. In these cases, the probe periphery is covered with a shield material as shown in FIG. 8, and if a shield probe is used, it can be used as a handpiece.
[0067]
As a result, the depth of the pocket becomes large or small in the extent of electromagnetic wave absorption from the tip to the tissue. (If the energy absorption is large, the depth of the pocket is large.) Again, measure the conversion function of water and absorption intensity in advance, create a conversion means with a computer, etc., and input and display the output of the present invention. It becomes a pocket depth measuring instrument. In this case, the tip terminal may not have to touch the measurement organization.
[0068]
An optical element such as a lens or a mirror may be used to adjust the energy and range of the excitation site due to the irradiated electromagnetic wave.
[0069]
The teeth may be irradiated with at least one pulsed electromagnetic wave at an appropriate interval or may be a continuous wave. Further, reflected or transmitted electromagnetic waves from the first pulse or the second pulse may be observed, and the phase matching may be adjusted by changing the interval between the first pulse and the second pulse. Further, the re-radiation may be observed with one pulse, or the re-radiation with each pulse may be compared. Further, the maximum re-radiation wave condition may be set in the irradiation means.
[0070]
The wavelength of the irradiated electromagnetic wave may be a single wavelength or a plurality of wavelengths. Further, the electromagnetic wave used for the interference may be a plurality of interferences from many directions, a multiple interference in which a plurality of interference waves are superimposed, or a combination thereof. In this case, even a complex tissue can be finely irradiated by region. Further, the wavelength before the wavelength change may be used for excitation. Those waves may be subjected to Fourier synthesis. Further, linearly polarized light, circularly polarized light or random polarized light may be changed by a polarizer in accordance with the irradiation purpose, depth, and the like.
[0071]
Detection means are HgCdTe, CCD, InA₂, Pb₂nTe, Pb₂, Cd₂, Cd₂e, PzT, LiTaO_Three You can use a thermopile, bolometer, etc. and remove stray light by using imaging means, bandpass filter, polarizing filter, high cut filter, low cut filter, etc. Electromagnetic waves may be extracted. Further, a similar effect may be obtained by applying an antenna or the like. In addition, the detection sensitivity may be adjusted by adjusting and feeding back the signal intensity and wavelength of the electromagnetic wave to the optimum state, or the diagnostic accuracy of the organization may be increased. Here, a circuit for removing background light such as an indoor lamp may be employed. Moreover, you may insert the optical element 14 like FIG. Examples thereof include a concave lens, a convex lens, and an optical element having the same refractive index as the inside of the internal reflection optical path.
[0072]
In addition, as the crystal matching of the tooth apatite progresses, the resonance wavelength often shifts. In this case, the excitation wavelength may be shifted and followed by the electromagnetic wave control means in accordance with the shift of the resonance wavelength. A pulse pair or group may be pulsed twice, or a pair or group excited three or more times may be used. In the case of a pulse, the electromagnetic wave control means may be scanned so as to obtain a pulse interval or a pulse wavelength that maximizes the re-radiation wave.
[0073]
Further, here, an infrared light source (Glover light source, CO₂A laser light source or the like may be provided, and the light of the light source may be passed through a filter or diffraction grating to obtain a predetermined wavelength such as 9.6 μm, which may be guided to the waveguide 9 for irradiation.
Moreover, you may make it irradiate with the following wavelengths. These can be used for excitation, reaction, examination, etc. as an example.
As an example,
8.8 μm to 10.0 μm of enamel (especially 9.1 μm, 9.4 μm, 9.5 μm, 9.6 μm, 9.7 μm, 9.6 ± 0.8 μm)
Dentin in the vicinity of 9 μm to 10 μm (especially in the vicinity of 9.6 μm ± δ) Collagen in the range of 5.8 μm to 10.0 μm (especially 5.8 μm to 6.2 μm, 6.0 μm to 6.8 μm, 7.3 to 8. 0 μm),
Chondroitin 7.5 μm to 10 μm,
7.6 μm to 10.1 μm of PO, (especially 9.6 to 10.1 μm, 8.1 to 8.4 μm),
PO₄(3-) Ion, HPO₄(2-) Ion, H₂PO₄(−) 9.0 μm to 10.0 μm such as ions,
HPO₄11.6 μm,
4.1 μm to 4.4 μm of P-H,
Ca (OH)₂O 5.5 μm to 10.0 μm, 2.6 μm to 3.3 μm (especially 2.85 μm)
Around 2.7μm of CaO
H₂2.9 μm ± δ of O, 6.1 μm ± δ,
CO₂Of 4.25 μm ± δ,
OH—2.7 μm to 2.8 μm, 15.7 μm,
NH, 2.8 μm to 3.3 μm, 3.4 μm to 4.3 μm, 6.9 μm to 7.2 μm
SOx 10 μm to 11 μm, 14 μm to 16 μm, 8.6 μm to 9.5 μm, 15 μm to 17 μm
Near apatite of 200 to 300 nm (may be excited by KrCl or KrF laser)
Is just an example. These may be used alone or in combination. Moreover, a reference vibration may be used, and a harmonic may be used. Furthermore, cutting and organization guidance (including use as a reactor etc.) may be performed using these wavelengths. For example, teeth are cut by irradiation with electromagnetic waves of 9.6 μm. In this case, compared with other wavelengths such as a wavelength of 10.6 μm, the heat effect on the pulp is less and the cutting surface is good. As an example, the tip terminal may be a scaler or curette type tip terminal, and an electromagnetic wave of 9.6 μm or the like may be emitted from the blade tip to perform tooth cutting, calculus removal, or curettage.
[0074]
And since irradiation of these electromagnetic waves performs caries protozoa suppression including suppression of a caries protozoan substance, the cleaning and prevention effect becomes large. In addition, it can reliably irradiate the cleaning area, and exhibits a synergistic effect with cleaning. In particular, since glucan is suppressed, glucan removal, that is, plaque removal can be performed very easily. This electromagnetic wave may irradiate an electromagnetic wave band near 9.8 μm from near 9.4 μm, or may have a single wavelength such as 9.4 μm, 9.6 μm, 9.8 μm, plaque collected from a living body, You may synchronize with the absorption wavelength of bacteria.
Ca, PO₄When using ions and the like, improvement, restoration, and coating of the tooth can be expected with the electromagnetic wave having the above wavelength. That is, CaO, OH, or PO₄For example, the reference vibration or overtone vibration is used. As an example, 350cm of CaO^-1For example, in the vicinity or by irradiating its overtones.
[0075]
Further, a carbonate buffer or a phosphate buffer may be used as a pH adjuster or an acid neutralizer, and conversely, a drug for periodontal treatment may be used. If effective, various minerals such as V ion, Mg ion and Cu ion, various vitamins such as vitamins C, B and E, antibiotics, antibacterial agents, bacterial flora control agents such as photosynthetic bacteria, lactic acid bacteria, anti The agent to be used, such as an oxidizing agent or an oxidizing agent may be used or used in combination, and any material can be used at the operator's discretion.
[0076]
Here, as an example of the drug, as at least one component thereof, fluorine ion, calcium ion, phosphorus ion, Ca₃(PO₄)₂, Hydroxyapatite, fluoroapatite, predetermined elemental apatite, non-stoichiometric apatite, hydroxyapatite lattice defect, hydroxyapatite atom defect, Ca deficient apatite, phosphate deficient apatite, OH deficient apatite, OH substitution Apatite, Ca_10-x(HPO₄)_x(PO₄)_6-x(OH)_2-x(N · H₂O) where x is 0 to 1, n is 0 to 2, or any combination thereof, Ca_Four(PO₄)₂O, Ca₅(PO₄)_ThreeOH or Ca_n(PO₄)_m・ X, Ca_nH_z(PO₄)_mX (n> 0, m> 0, z> 0, X is a predetermined substance or none),
(These become tooth quality improvement drugs)
[0077]
Carbonate buffer, phosphate buffer, cyclodextrin, glucose aminoglucan, polyphenol, antibacterial agent, antibiotic agent, fluorine
(These become agents for improving caries prevention) Here, in particular, cyclodextrin may be used by inclusion of fluorine. In this case, cyclodextrin adheres to Mutans Streptococci, releases fluorine over a long period of time, suppresses the activity of Mutans Streptococci, and strengthens the tooth structure.
[0078]
Collagen, chondroitin, chondroitin sulfate, hyaluronic acid,
(These will be gingival, skin, mucous membrane, dentine, pulp, bone improving drug)
[0079]
Alkaline phosphatase, osteopontin, osteocalcin, cytokine, vitamin D, prothrombin, bikunin, neflocalcin, heparan sulfate, phosphate, phosphate, hydrochloric acid, bone morphogenetic protein, calcium binding protein, hydroxylase,
(These become hard tissue improving drugs such as bone, dentin, and enamel)
[0080]
A drug having any one of a substance constituting a living body such as a substance or a substance assisting the living body or a combination thereof as one component is used.
[0081]
When a toothbrush-like or electrode-like thing is attached to the tip, hair (wire) with a conductor in the insulator is implanted into a toothbrush or multiple electrodes on the cleaning element, and positive and negative electrodes are alternately placed on the bristles. A local current may be supplied by providing a wiring. This local current may be adjusted according to the purpose from direct current to high frequency. In this case, glucan in dental plaque may be removed more efficiently, apatite may be strengthened, or used as a dental pulp examination device. In the case of dental pulp examination, any form may be adopted as long as a local circuit is established even with a unipolar tip terminal such as a probe. You may use this as an electric dental pulp examination chip.
At this time, an apatite precursor may be disposed between the cleaning element and the hairs (lines) of the electrodes to facilitate clustering and excitation. At this time, the vibration may be transmitted to the cleaning element to promote clustering. Furthermore, clustering may be promoted by a local current.
[0082]
The above embodiments or modifications may be implemented alone or in combination. Moreover, you may use for another use.
[0083]
[Brief description of the drawings]
FIG. 1 is an example of an electromagnetic wave examination apparatus.
FIG. 2 is an example of an electromagnetic wave diagnostic apparatus.
FIG. 3 is an example of an electromagnetic wave diagnostic apparatus.
FIG. 4 is an example of an electromagnetic wave diagnostic apparatus.
FIG. 5 shows an example of a terminal for examination such as periodontal tissue.
FIG. 6 shows an example of a tip terminal for examination such as periodontal tissue.
FIG. 7 is an example of an electromagnetic wave diagnostic apparatus.
FIG. 8 is an example of an electromagnetic wave diagnostic apparatus.
[Explanation of symbols]
1 An example of input means.
2 An example of electromagnetic wave irradiation means.
3 An example of an internally reflected light path.
4 An example of sensor means.
5 An example of reflection means.
6 An example of holding means.
7 An example of detection means.
8 An example of amplification means. (Including buffer and attenuation means)
9 An example of gripping means.
10 An example of exchange means.
11 An example of external output means.
12 An example of optical path changing means.
13 An example of a waveguide.
14 An example of an optical element.

Claims (4)

A tip terminal provided with a light irradiator that emits light to the portion inserted into the periodontal pocket;
A light measuring means for measuring light from the light irradiation unit in a state inserted in a periodontal pocket;
Storage means for storing what is measured in advance with respect to the relationship between the intensity of light measured by the light measurement means or the light absorption state and the state of the periodontal pocket;
From the light intensity or light absorption state measured by the light measurement means,
A photodiagnosis device comprising: a control device for specifying a periodontal pocket based on the storage means. The optical examination device according to claim 1,
The light irradiation part is provided extending from the tip of the tip terminal inserted into the periodontal pocket in the longitudinal direction over the outside of the periodontal pocket,
The light measurement means is provided so as to be able to measure the intensity of light emitted from the light irradiation unit exposed to the outside from a periodontal pocket,
The control device stores data relating the intensity of light irradiated from the light irradiation unit exposed to the outside from the periodontal pocket and the depth of the periodontal pocket,
  An optical examination apparatus characterized in that the depth of a periodontal pocket into which the tip terminal is inserted is quantified based on the intensity of light measured by the light measuring means and the stored data. The optical examination device according to claim 1,
The light irradiation part is provided extending from the tip of the tip terminal inserted into the periodontal pocket in the longitudinal direction over the outside of the periodontal pocket,
The light measurement means is provided so as to be able to measure the intensity of light absorbed in the periodontal pocket from the light irradiation unit,
The control device stores data relating the intensity of light absorbed in the periodontal pocket and the depth of the periodontal pocket,
  An optical examination apparatus characterized in that the depth of a periodontal pocket into which the tip terminal is inserted is quantified based on the intensity of light measured by the light measuring means and the stored data. In the optical examination apparatus in any one of Claims 1-3,
The light irradiation unit is provided in the periodontal pocket so as to be able to irradiate light of one or more specific wavelengths or broad wavelengths,
The light measuring means is provided so as to be able to measure the wavelength absorbed in the periodontal pocket,
The control device stores data relating the wavelength of light absorbed in the periodontal pocket and the properties in the periodontal pocket, the wavelength of light measured by the light measuring means, and the data to be stored Based on the above, the characteristics of the periodontal pocket in which the tip terminal is inserted are specified.

Images