JPH114839A - Activator acting device and activator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively recover a tissue of a hard tissue such as a bone and a tooth by providing an activator containing a prescribed acting component to be imparted to a living body tissue as its part and an activity control means to control molecular vibration and an active temperature to activity to the acting component and/or an acting part at acting time. SOLUTION: When used to recover and anneal a tooth of a floor type up to partial activity from the whole activity, an activator is prepared by using an aqueous solution containing Ca ions in large quantity as an acting component, and is heated to 40 deg.C by an activity control means. This activator is supplied to a floor 1 covering the tooth through a supply route 1 capable of supplying the activator at any time, or a route 2 capable of the activator at inserting time. After such a floor 1 is inserted into an oral cavity, an electric current is carried to a Peltier element 3 by the activity control means, and respective parts of the tooth are heated to around 40 deg.C by a heat conductor 2. Therefore, recalcification (recovery) is promoted to the tooth delimed by an obstacle such as carious corrosion, acid corrosion and salivary abnormality.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to an agent mainly for enhancing the activity of hard tissue particularly in a living body,
A method that activates, destroys, and reconstructs hard tissues such as bones and teeth, and that assists tissue circulation, such as the effects of hard tissues on surrounding tissues or the effects of non-hard tissues on hard tissues. And a method thereof. This technique is particularly suitable for use on teeth.

[0002]

2. Description of the Related Art There is an apatite-containing toothpaste or a root canal cleaning agent.

[0003]

In conventional apatite tooth restoration agents, tooth defects are caused by Ca ions, P ions,
It is caused by the lack of O4 ion, and in order to repair it, it must be repaired with a single ion or a complex ion thereof. However, it is very difficult to ionize crystalline apatite and the like. There was a problem that the effect on tooth restoration was small. Conventional mouthwashes, dentifrices, root canal cleaning agents, root canal treatment agents, hard tissue repair agents, periodontal tissue treatment agents, etc. do not contain Ca ions or PO4 ions. In this case, ion outflow from hard tissue or the like, that is, a defect occurred. In the case of conventional drugs, the ion concentration in serum or
Ca, PO of hard tissues such as bones of the whole body that maintain the concentration
4 could not be a means, method, or source to maintain the proper composition. It is fully conceivable that Ca ions alone act on teeth and the like, such as ingestion of foods containing Ca ions. At this time, Ca ions alone
The restoration effect on teeth is extremely low. Conversely, the organization,
Since a large amount of a breaking agent such as an acid was used for an acid treatment for bonding an object or the like in a destructive direction such as cutting, the influence on surrounding tissues and surrounding objects was great.
Furthermore, it was not possible to individually control the effects of different directions such as destruction, repair, or improvement of crystallinity, and the effects on the individual treatments were very small or the effects as described above. Did not.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to prevent tissue destruction of hard tissue and the like, to repair tissue such as hard tissue, and to aim at tissue circulation. An object of the present invention is to provide a drug having a function of repairing and destroying tissue such as hard tissue or a method thereof. Also, if the operator is used in a destructive direction, the effect of the acid treatment on the micro-cutting and the adhesive can be achieved with a smaller amount of a processing agent such as a chemical agent than the conventional processing.
Also, the crystallinity can be improved. The magnitude and directionality of the action vector can be freely controlled by the action element, such as switching or synthesizing in the repair direction, the breaking direction, and the crystal improvement by the action of the action element. . Thus, from these points of view, effects that are completely different at first glance, such as restoration and destruction, are disclosed.

[0005]

The information input device of the present invention employs the following technical means. According to a first aspect of the present invention, there is provided an activator action device comprising an activator including at least a part of a predetermined activator to be given to an object or a living tissue, and at least an activator or an action site at least when actuated. Alternatively, it is adopted to provide an activity control means for controlling the molecular vibration or the activation temperature with respect to the activity for both.

[Means of claim 2] The activator of claim 2 comprises:
To control the molecular vibration or the activation temperature with respect to the activity of at least the activator and / or the action site, or both, at least when the activator includes at least the predetermined activator given to the object or the living tissue as a part thereof. Activity control means.

[Claim 3] The activator-operating device or activator according to claim 1 or 2 is provided with surrounding activity control means for performing predetermined molecular vibration control or temperature control on surrounding tissues or surrounding objects. An activator acting device, or an activator, or a method of activating the activator is employed.

[Claim 4] A Ca element according to any one of claims 1 to 3, wherein at least a part of the operator is in an ionic state at least after reaching the action site. Activator acting device or activator, or its activation method.

(5) A PO4 element according to any one of (1) to (3), wherein at least a part of the operator is in an ion state at least after reaching the action site. Activator acting device or activator, or its activation method.

According to a sixth aspect of the present invention, at least a part of the active agent according to any one of the first to third aspects is a buffer or a neutralizing agent for an acid or both of them. An activator or its activation method is employed.

[Claim 7] An activator or an activator, wherein at least a part of the activator according to any one of claims 1 to 3 is an antioxidant.
Adopt the activation method.

[Means of Claim 8] An activator activator or activator characterized in that at least a part of the operator in any one of claims 1 to 3 is an acid, or a method of activating the activator. .

[Means of Claim 9] An activator action device or activator characterized in that at least a part of the operator in any one of claims 1 to 3 is an oxidant, or a method of activating the activator. I do.

[Means of Claim 10] An activator acting apparatus or activator characterized in that vitamin D is contained in any of the activators according to claims 1 to 8, or an activator thereof.

[Means of Claim 11] An activator acting device or activator characterized in that any one of claims 1 to 10 contains fluorine, or a method of activating the activator.

[Claim 12] The activator or activator of any one of claims 1 to 11, or a method thereof, wherein the activator is irradiated with an electromagnetic wave such as a light beam. Alternatively, an activator or its activation method is employed.

[Claim 13] In the activator or activator acting apparatus or method according to any one of claims 1 to 12, it is preferable that a carrier for the activator of each activator is provided. A feature activator or activator or method of activation is employed.

[Claim 14] In the activator or activator according to any one of claims 1 to 13, or the method thereof, the activator or activator or the activity thereof in all combinations thereof. Adopt the method of adopting.

[0019]

Effects of the Invention and Effects of the Invention

[Action and Effect of Claim 1] The activator action device of claim 1 comprises an activator containing at least a predetermined activator to be given to an object or a living tissue as a part thereof, and at least an activator or Employs the provision of activity control means to control the molecular vibration or activity temperature for the activity at the site of action or both, so repair and reconstruction previously difficult or impossible with this activation method , Remineralization, annealing, etc. can be realized.
In addition, this device makes it possible to easily switch the opposite effect, that is, the action vector such as repair and destruction.
The combined effect of the effects can be easily obtained, the control of the active site and the non-active site is surely performed, the concentration of the drug to be applied is extremely low, and the activation treatment can be performed in a short time.

[Action and Effect of Claim 2] The activator according to claim 2 comprises an activator containing at least a part of a predetermined activator to be given to an object or a living tissue, and at least an activator at least when actuated. Or an activity control means for controlling molecular vibration or activity temperature for the activity for the action site or both,
The effect of claim 1 can be more easily enjoyed.

[Function and Effect of Claim 3] In the activator-operating device or activator of claim 1 or 2, the surrounding activity control means for performing predetermined molecular vibration control or temperature control on the surrounding tissue or surrounding object is provided. Since the activator action device or the activator characterized in that it is provided, or the method of activating the activator is adopted, the action of claim 1 is more reliably and
A lower concentration of active agent can effect a more limited site of action in a shorter time.

[Action and Effect of Claim 4] At least a part of the operator according to any one of claims 1 to 3 is in an ion state at least after reaching the action site. Since the activator action device or activator or the method of activating the Ca element is employed, effects such as restoration, remineralization, reconstruction, annealing, and strengthening of bones and teeth, particularly teeth, can be enjoyed.

[Action and Effect of Claim 5] At least a part of the operator according to any one of claims 1 to 3 is in an ionic state at least after reaching the action site. Since the activator activator or activator which is a PO4 element or its activation method is adopted,
Effects such as restoration, remineralization, reconstruction, annealing, and strengthening of bones and teeth, particularly teeth, can be enjoyed. .

[Action and Effect of Claim 6] At least a part of the activator according to any one of claims 1 to 3, is a buffer for acid and / or a neutralizer, or both. Since the device or the activator or the method of activating the device is employed, destruction by acid can be reduced or neutralized. When the present invention is used in a correct direction such as repair, the control of acid is important.

[Action and Effect of Claim 7] At least a part of the activator according to any one of claims 1 to 3 is an antioxidant, or an activator activator or activator, or an activity thereof. By employing the method, the harmful effects of the oxidizing agent can be localized, and the action of oxides harmful to the living body can be suppressed.

[Action and Effect of Claim 8] An activator action device or activator characterized in that at least a part of the activator according to any one of claims 1 to 3 is an acid, or a method of activating the activator. Since it is adopted, various acid treatments can be performed at a lower concentration than before, and the site of action is limited to reduce the influence on the surroundings. Further, since the constructive action and the destructive action can be alternately enjoyed by the same mechanism, it is possible to easily and efficiently improve the physical properties such as the crystal.

[Action and Effect of Claim 9] An activator action device or activator characterized in that at least a part of the operator in any one of claims 1 to 3 is an oxidizing agent, or a method of activating the activator. The antibacterial action against bacteria that inhibit the activity of the substance
Can be more effective.

[Function and Effect of Claim 10] Claim 1
In the case where the activator action device or activator characterized in that vitamin D is contained in any of the activators according to any one of to 8 or the activator thereof is employed, the device, the drug and the method act on hard tissue. More effectively, hard tissue repair,
Construction and annealing can be performed, and the continuous effects of their actions can be enjoyed.

[Function and Effect of Claim 11] Claim 1
Activator activator or activator characterized in that fluorine is contained in any of the activators in to 10, or the method of activating the activator. Thus, effects such as higher antibacterial action can be enjoyed.

[Function and Effect of Claim 12] Claim 1
The activator or activator of any one of claims 11 to 11, or the method thereof, wherein the activator or activator is characterized by irradiating electromagnetic waves such as light rays, or
Since this activation method is employed, in the case of ultraviolet rays, the production of vitamin D can be helped, and in the case of infrared rays, effects such as annealing of teeth, prevention of dental caries, or control of molecular vibration can be enjoyed.

[Function and Effect of Claim 13] Claim 1
The activator or activator or the activator according to any one of claims 12 to 12, characterized in that the activator or activator or the activator is provided with a carrier for the activator or the activator of each activator. Because we adopt activation method,
Greater activity can be enjoyed.

[Function and Effect of Claim 14] Claim 1
In the activator or activator acting device or method according to any one of claims 13 to 13, the activator acting device or activator in all combinations thereof is employed, or the method of activating the activator is adopted. Than if
It is more effective and, in some cases, can provide not only a single effect but also a synergistic effect.

[0033]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an activator and an activator according to the present invention will be described with reference to the embodiment shown in FIGS.

As shown in FIG. 1, the molecular vibration of the active substance is controlled by the activity control means. In general, the activity control means acts excitatively at the action site, and acts more toward the stop state at the non-action site. Also, the active means controls the molecular oscillations (between and inside) for the operator and / or the site of action.

FIG. 1 is a diagram of the activator action device in the embodiment and the modified example, and FIG. 2 is a diagram of the action vector.
The activator action device here comprises an activity control means by heat exchange and an activator at least a part of which is composed of an element composed of a tooth component, a reinforcement or a broken object. In this activity control, molecular vibration is controlled by heat.

[Construction of Embodiment] The first embodiment proposes the use of the floor type from FIG. 3 to full restoration to partial activation as tooth restoration and annealing in FIG. Here, an aqueous solution containing a large amount of Ca ions is used as an activator and used as an activator. Then, it is heated to 40 ° C. by the activity control means. Supply means (not shown) supplies the active agent to the working site to the floor 1 covering the teeth by the supply supply route 1 where the active agent can be supplied at any time or the route 2 where the active agent can be supplied at the time of insertion. At this time, PO4 ions may be used in combination.

The floor 1 is inserted into the oral cavity. Then, power is supplied to the Peltier element 3 from the activating means. Then, each part of the tooth is heated by the heat conductor 2 to about 40 ° C. Here, the control is performed in an open loop, but a temperature detection sensor such as a thermocouple may be inserted at an appropriate position of the action site to improve the accuracy. At this time, the accuracy may be improved by arranging the heat conductors 2 in parallel, or assembling the heat capacity into parts. At this time, if there is no problem in the structure, it is better to raise the temperature as much as possible.

[Effects of the Examples] Remineralization (repair) of teeth demineralized due to disorders such as dental caries, acid erosion, and abnormal saliva
To promote. In this case, Ca ions, PO at meals, etc.
4 It is very effective as compared with ion intake, and if performed after a meal, demineralization due to a decrease in pH on the tooth surface caused as a result of the meal can be prevented, and a restorative and annealing effect can be enjoyed. In other words, the activity control means and the activator improve the crystallinity of the hydroxyapatite crystal of the tooth by the action of the added molecular vibration and the operator, or the molecular vibration acts as the sublimation of impurities or the carrier, or the combined action of the two Ca, PO4, etc. are carried into the Ca, PO4 deficient site and repair is performed, thereby improving the caries resistance.

[Second Embodiment] A second embodiment proposes the use of partial activity for tooth restoration and annealing.

FIGS. 4 to 9 show a method of partially repairing and annealing. FIG. 4 is a peripheral view of a probe that is advantageous for performing a gentle curved surface such as a buccal side, a lingual side, a mesial side, and a distal side. FIG. 5 is a cross section thereof. FIGS. 6 and 9 show a probe that is convenient to be inserted and carried out, such as an occlusion. 7 and 8 show a shell type probe. FIG. 9 shows a curved surface compatible probe for mounting an occlusal surface.

[Curved Surface Type] FIG. 4 will now be described. Molecular vibration such as heat is applied via the probe 6 having a shape along the teeth. The probe is provided between the teeth and the like via a stopper, and a gap 7 is provided between the main body 6 and the active site such as the teeth, into which the active agent is inserted. At this time, the probe 6 and the heat conductor 5 are made of a metal mesh, a metal rod, a pipe, or the like, and the molecular vibration control means such as the heat conductor and the activator supply means may be integrated. An independent structure may be used.

At this time, the probe 6 is connected to the aforementioned metal mesh,
If there is a hole or the like from which the activator seeps out of the pipe, if such a probe is used, the gap 7 is unnecessary. In this case, more effective and more direct activity control at the site of action can be performed. In other words, the supply of the operator may be performed while controlling the temperature of the operator by using a flexible structure such as a flexible pipe or a metal cloth in which fine metal wires are woven.

In the state shown in FIGS. 4 and 5, the action probe 6 on the Peltier element controlled by the activity control means is brought into contact with the action site. Here, a bar-shaped metal that is smoothly bent and aligned with the tooth surface was used, and a solution containing an operator was held between the metal and the tooth by utilizing surface tension or capillary action. The structure which can use the surface tension or the capillary action together enhances the action only on the action site.

[Occlusion type] A heat conductor may be formed of a soft metal or resin, and an activator supply means may be added to or inside the heat conductor. In this case, as shown in FIG. 6, it can be used by being occluded, and since it is soft, the active site can be activated in a shape adapted to the occlusal surface. Alternatively, this may be replaced with a fibrous material such as gauze, and may be temporarily fixed to the tooth by, for example, occlusalizing by including an active agent therein. At this time, an activity control means may be used in combination, or a time-sharing activation means such as an active ingredient, an activator containing it, or an activity site may be controlled in advance. . Further, other types of functional structures may be used.

[Shell type] If necessary, the periphery of the action site is appropriately cooled by a Peltier element driven by the activity control means. As a result, even if the operator leaks to the surroundings, the effect is significantly reduced. As an example, 8 in FIG.
As shown in FIG. 9, that is, an activator inlet or / and an active effect probe containing a first agonist and an activator inlet or an active effect probe containing an actor other than 8 may be used as the reverse active effect probe. For example, other types of functional structures may be used.

[Occlusal Surface Corresponding Probe] FIG. 9 shows a type that can be held on an occlusal surface, and is manufactured mainly by a metal, resin, porcelain, or the like based on the CAD / CAM method, the conventional indirect method, or the direct method. There are many ranges from one tooth to several teeth. The concave system of the occlusal surface is described in the circular part of this inner surface by the above-mentioned method, and it is used by occlusal use by upper and lower teeth, or it is installed on one jaw tooth or only one tooth occlusal surface Used. At this time, the functional structure may be the same as the above-described functional structure, or may be integral with the holding structure and may be a combined type.

[Effects of the Embodiments] The activator action device and method of the present embodiment promotes remineralization (repair) of teeth that have been demineralized due to disorders such as caries, erosion and abnormal saliva. In this case, it is very effective compared to the intake of Ca ions and PO4 ions at meals and the like, and if performed after meals, prevents demineralization due to a decrease in pH on the tooth surface as a result of eating,
Further, the effects of repair and annealing can be enjoyed. In other words, the activity control means and the activator improve the crystallinity of the hydroxyapatite crystal of the tooth by the action of the added molecular vibration and the operator, or the molecular vibration acts as the sublimation of impurities or the carrier, or the combined action of the two Ca,
Ca, PO4, and the like are carried into the PO4 deficient site to be repaired, thereby improving cariogenicity. It is possible to limit the functional action according to various forms, and to make the action more effective. In other words, it is possible to more quickly and more efficiently act on the amount of active agent used depending on the risk site. These various topical types can suppress the swallowing of various drugs appearing in the present invention.

[Third Embodiment] The third embodiment is shown in FIGS.
However, since the third embodiment is an example in which an operator having a different action vector in FIG. 2 is applied, redundant description is omitted. [Construction of Embodiment] The third embodiment shows an example of use as an acid treatment or an oxidation treatment before the restoration of adhesion to a tooth. FIG.
Shows an etching diagram in the third embodiment. ,

[Acid treatment] The probe is adjusted along the etched portion of the formed tooth.

A liquid heated to the tooth to be restored after formation,
The probe 6 is set at the action site using a small amount of acid formed of a solid or a fluid as an operator, and the probe 6 is applied to the gap 7. The acid used at this time may be any acid such as phosphoric acid or maleic acid as long as the desired effect can be obtained.

Here, acid is placed on the 8 side of the mechanism 8 and 9 in FIG.
A neutralizer, a buffering agent, or the like for an acid may be employed as the operator on the ninth side. The buffering agent used at this time may be any of a phosphoric acid type and a carbonic acid type as long as the desired effect can be obtained. The same applies to the neutralizing agent.

[Oxidation treatment] H2O2 is used as an activator as an antibacterial treatment on the plaque attachment site before or after plaque cleaning.
An oxidizing agent such as is used as an activator. Use Figure 3
Although any of the probes 9 to 9 may be used, the type employing the mechanisms 8 and 9 in FIG. The method of implementation is in accordance with the second embodiment. At this time, a shell may be prepared for the caries risk site, and the shell may be provided and oxidized. Here, this operation may be a bleaching operation.

Here, antioxidants such as vitamins A, C, E, β-carotene, glutathione peroxidase, catalase, SOD, etc., for acids are employed on the 8 side of the 8 and 9 mechanisms in FIG. May be.

[Effects of the Embodiment] Since etching can be performed with a smaller amount of acid (destroyer) than the conventional amount, the influence on the surrounding structure is small. Further, by adopting the functional structures shown in FIGS. 8 and 9, there is no further influence on surrounding tissues. Further, by performing the activity control in this manner, the action by the action vector of the operator, forward, reverse, or a combined vector thereof can be exerted.

[Modification]

In the above-described embodiment, the tooth is targeted.
It can be used for various materials.
The present embodiment is not particularly limited by the operator's freedom.

In the first and second embodiments, in the direction of restoration, such as restoration, annealing, etc., and structural reinforcement, a phosphate buffer solution,
A carbonate buffer, an alkaline preparation or a combination thereof may be used as a part of the agonist. In this case, it is possible to alleviate the influence of the acid attached to the plaque on the tooth surface or from the outside.

In the directions of the restoration and the structure reinforcement such as the restoration and annealing in the first and second embodiments, vitamin D and light rays may be irradiated before and after this point.
In this case, the added vitamin D or vitamin D generated by light rays (ultraviolet rays) promotes the absorption of Ca ions and consequently maintains or increases the Ca ion concentration in saliva.

If the shape of the probe can be achieved,
Anything is fine.

The activator may be applied to the site of action with a brush or the like.

Objects that can be used as an occlusal type (FIG. 3,
6, 9) may be used as a night guard or as a bite lift.

The activator may be in any form, such as a liquid, gas, solid, powder, fluid, sol, gel, and the like. The powder may be dissolved in CaCO, CaCl2, or the like at the action site and used as Ca ions to be ionized after reaching the action site. Further, the activator or the activator may be encapsulated to control the onset time of action such as ionization, or the activation means may control the action time such as ionization.

The activity control means may be heat generated by an object or tissue. Heat may be absorbed.

The activity control means may be shared with other purposes such as heat generated by a medical device such as a light.

In the case of improving the crystallinity, the destructive direction is given to the impurity and the repair direction (action vector) is greatly given to the constituent, and in some cases, the breakdown and repair of the constituent are repeated. The first, second, and third embodiments may be combined in terms of time and space so that the structure such as crystallinity can be strengthened. In the case of repeatedly using and strengthening the construction and the direction of destruction, or in the case of using only for construction, it is important to control the acid securely or not to include it at all, or to buffer and neutralize it.

Fluorine may be used in combination. In this case, a greater effect than that of fluorine alone, such as enhancement of tooth quality and antibacterial action, can be obtained.

In the above description, molecular vibration such as heat is used as a carrier. However, chemical carrier such as Ca carrier such as xylitol can be used.
Physical carriers may be used.

As an example, the action time may be defined by monitoring the consumption or elution of the activator, such as by attaching a Ca or PO4 sensor to the action site side of the probe 6 or the like. Similarly, a pH sensor may be attached to the probe 6 for monitoring the acid. On the other hand, a feedback loop may be similarly provided in the activation control circuit. In the case of thermal control, a thermocouple may be attached to at least one or more locations and monitored and fed back.

These results may be fed back to control the control factors such as the supply amount of the operator of the circuit and the control amount of the activity.

In the above-mentioned embodiment, the activity is controlled by controlling the molecular vibration by heat, but other elements may be used as long as the molecular vibration can be controlled. Chemicals such as acids and bases may be used. At this time, if an exothermic agent or an exothermic agent is put in the capsule or the like as the activity control means, time control, selection of an action site, and the like can be controlled, and an operator with such an activity control means may be given to the action site.

In the molecular vibration control, an action detection sensor may be further provided at the probe 6 to perform closed control to further increase the accuracy.

In the above embodiment, molecular vibrations such as intermolecular and intramolecular are caused to act by means of heat. However, other transmitting means such as medium waves such as electromagnetic waves and sound waves may be used as means for controlling the activity. If the purpose is achievable, such as good, other transmission means may be used to obtain the same effect.

The heat may be transmitted in a contact or non-contact manner, and may take any form of heating or heat absorption as long as molecular vibration can be controlled. Further, the activity may be increased by increasing or decreasing the temperature.

The irradiation of electromagnetic waves may be used in combination. This has effects such as controlling molecular vibration and generating heat. Vitamin D is produced by appropriately irradiating ultraviolet rays. At this time, it is more preferable to use a vitamin D precursor in combination. Irradiation with an infrared lamp may be used. In that case, it is more effective to tune to the absorption peak of the tooth including the phosphoric acid group, and it is effective to tune to the absorption peak even at other wavelengths. In addition, St. It may be tuned to the Mutans suppression wavelength.

An electromagnetic wave such as light may be applied. In this case, the crystallinity of the hydroxyapatite crystal of the tooth is improved by the molecular vibration due to the applied light, and thereby the anti-caries property is improved. In particular, avoiding the phosphate group peak of hydroxyapatite in tooth enamel and dentin to a wavelength of 9.6 μm, and if possible, shifting to a lower wavelength is more effective from the viewpoint of acid resistance. Conceivable. 8.8 μm for a more complete crystal structure
The closer to, the better.

The molecular vibration may be strengthened by applying an electromagnetic wave of a specific wavelength to the phosphoric acid group, or may be used in combination with the present method. At this time, an electromagnetic wave may be supplied to the action portion via a waveguide or a fiber.

For application to medial features such as the root canal, a straight or bent rod or pipe probe having at least one or more bending points may be used.
Used as a probe for activity control means. At this time, the activator supply means may be hollowed out, the activator may be guided into the root canal by another route, or a time-division supply means such as supplying the activator in advance may be used. In the case of a hollow structure, an optical fiber or the like may be incorporated in the hollow structure to irradiate electromagnetic waves, or a medium wave may be induced.

The above embodiments or modifications may be implemented alone or in combination.

[0080]

[Brief description of the drawings]

FIG. 1 is a diagram of an activator acting device and an activator acting as an activator.

FIG. 2 is a conceptual diagram of an action vector of an operator.

FIG. 3 is a part of the activity control means at the action site, which is a floor-type object that covers teeth. This can be a full floor or a partial floor.

FIG. 4 is an example of partial activity, and is an example of a curved surface corresponding probe.

FIG. 5 is a sectional view of FIG. 4;

FIG. 6 is an example of a partial activity, and is an example of a probe used by being occluded.

FIG. 7 is an example of partial activity, in which the probe is an example of a shell type.

FIG. 8 is an example of partial activity, in which the probe is a cone type probe and a sectional view of a cone.

FIG. 9 is an example of partial activity, and is an example of a molar occlusal surface holding type. One jaw or upper and lower jaws may be used.

[Explanation of symbols]

One example of a floor. 2 An example of a transmission path mainly for controlling molecular vibration with a heat conductor or the like. 3. An example of a thermal control element for controlling molecular vibration. 4 Teeth occlusion position (concave). 5 An example of a transmission path to the activity control means. An example that may be a transmission path for the activator in some cases. 6 An example of a probe to the site of action. 7 An example of a gap for holding the activator. 8 An example of an activator input port and / or an active effect probe containing a first agonist. 9 An example of an activator input port containing an agent other than 8 or / and an activity effect probe different from 8. 10 Jacket.

Claims (14)

[Claims] The present invention relates to an active agent containing at least a predetermined agent to be given to an object or a living tissue as a part thereof, and a molecular vibration or activity at least at the time of action to at least the agent and / or the site of action. An activator with an activity control means for controlling the temperature. 2. An active agent containing at least a predetermined agent given to an object or a living tissue as a part thereof, and a molecular vibration or activity with respect to the activity of at least the agent and / or the action site or both at the time of action. An activator having activity control means for controlling temperature. 3. An activity device according to claim 1 or 2, wherein said activity device or said active agent is provided with surrounding activity control means for performing predetermined molecular vibration control or temperature control on surrounding tissues or surrounding objects. Agent activator, or activator, or method of activating it. 4. The activator activator as a Ca element, wherein at least a part of the activator according to any one of claims 1 to 3 is in an ionic state at least after reaching the action site. Device or activator or method of activation. 5. The PO4 according to claim 1, wherein at least a part of the operator is in an ionic state at least after reaching the action site.
An activator acting device or activator which is an element or a method of activating it. 6. An activator or an activator characterized in that at least a part of the activator according to any one of claims 1 to 3 is a buffer or a neutralizing agent for an acid or both. Activation method. 7. An activator or an activator, or a method of activating the activator, wherein at least a part of the activator according to claim 1 is an antioxidant. 8. The activator activator or activator of claim 1, wherein at least a part of the activator in any one of claims 1 to 3 is an acid, or a method of activating the activator. 9. An activator activator or activator, or a method of activating the activator, wherein at least a part of the operator in any one of claims 1 to 3 is an oxidizing agent. 10. An activator, an activator, or a method for activating the activator, wherein the activator according to claim 1 contains vitamin D. 11. An activator-actuating device or activator according to claim 1, wherein at least a part of any one of the activator and the activator according to claim 1 is fluorine or a fluorine compound. 12. The activator or activator according to any one of claims 1 to 11, or a method thereof, wherein the activator or activator is characterized by irradiating electromagnetic waves such as light rays, or How to activate it. 13. An activator or activator acting device or method according to any one of claims 1 to 12, characterized in that the activator is provided with a carrier for the activator tissue or the activator of each activator. Action device or activator or method of activating it. 14. The activator or activator of any one of claims 1 to 13 or the method thereof, the activator or activator of all combinations thereof or the method of activation thereof.