DENTAL PROBE

Abstract

A dental probe according to the invention is provided with a tip portion including a water flow path, an air flow path, a multi-lumen tube including a duct formed therein in which an optical fiber is inserted, and the optical fiber inserted in the duct. The optical fiber includes a resin-coated layer provided on an outer circumference of a cladding and a metal-coated layer provided on the outer circumference of the resin-coated layer, and the resin-coated layer is formed of a polymer compound having a refractive index lower than that of the cladding.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a dental probe which is provided in a handpiece for dental treatments and used for guiding laser light transmitted through an optical fiber to a position to be irradiated.

2. Description of the Related Art

Recently, a dental laser treatment device used for dental hard tissue treatments such as the removal of dental caries and dentin and the excision of enamel has been provided.

A laser handpiece used for the dental laser treatment device includes a tip portion guiding laser light emitted from an optical fiber to a treatment site (a position to be irradiated).

It is preferable that the tip portion possess a shape and a structure fit for the treatment site of the teeth and the mode of treatment and can remove evaporated substances by cooling an affected area irradiated with the laser light.

Accordingly, it is known that, in a laser handpiece including a probe guiding the laser light transmitted through the optical fiber to the position to be irradiated, the probe includes a water injection tube injecting water near the exit end of the probe and a gas supply tube injecting gas (air) near the exit end of the probe, and is so formed that the shape of the tip portion of the probe causes the direction of the laser light emitted from the optical fiber to incline with respect to the axis of the laser handpiece (see Patent Japanese Patent No. 3124643, for example).

However, from the probe for dental treatment, a powerful laser light is emitted to remove the dental hard tissue.

On the other hand, there is a problem in that, since the tip portion of the optical fiber bends in the tip portion of the probe, a portion of the laser light leaks out of the optical fiber due to the bending loss of the optical fiber, and the leaking power is converted to heat, whereby the temperature of the probe tip portion rises.

When the temperature of the probe tip portion rises, there is a concern that a patient will experience unpleasant sensations since he or she can feel the intense heat of the probe tip portion.

When the temperature of the probe tip portion rises remarkably, there is a concern that a burn will be caused by contact of the lateral surface of the probe tip portion to the oral cavity, the gums, and the like.

The present invention has been made under the consideration of the above circumstances, and provides a dental probe that can prevent a temperature rise in the tip portion.

SUMMARY

In order to solve the above problems, the present invention provides a dental probe provided in a laser handpiece for guiding laser light transmitted through an optical fiber to a position to be irradiated during dental treatment.

Additionally, a tip portion of the dental probe includes a water flow path, an air flow path, a multi-lumen tube including a duct formed therein into which the optical fiber is to be inserted, and the optical fiber inserted into the duct; the optical fiber includes a resin-coated layer provided on an outer circumference of a cladding and a metal-coated layer provided on an outer circumference of the resin-coated layer; and the resin-coated layer is formed of a polymer compound having a refractive index lower than that of the cladding.

In the dental probe of the invention, it is preferable that the refractive index of the resin-coated layer be 0.04 or more lower than a refractive index of the pure silica.

According to the invention, the resin-coated layer is formed of a polymer compound having a refractive index lower than that of the cladding.

Accordingly, the resin-coated layer can function as a second cladding in the optical fiber to suppress the leakage of the laser light caused by the bending loss.

As a result, it is possible to prevent a temperature rise in the probe.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a front view illustrating an example of a dental probe of the invention.

FIG. 1B is a rear view of a portion taken excluding a tip portion of the dental probe.

FIG. 1C is a view illustrating the tip portion of the dental probe, which is a cross sectional view taken along the line S-S in FIG. 1A.

FIG. 2 is a cross-sectional view taken along the axial direction of the dental probe illustrated in FIGS. 1A to 1C.

FIG. 3 is a schematic view illustrating a configuration example of a laser handpiece including the dental probe illustrated in FIGS. 1A to 1C.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, based on preferable embodiments, the invention will be described with reference to drawings.

FIGS. 2 and 3 illustrate the dental probe by omitting the middle portion of a probe tip portion 11.

As shown in FIGS. 1A to 1C, the tip portion 11 of a dental probe 10 of the embodiment includes a water flow path 31, an air flow path 32, a multi-lumen tube 30 having a duct 33 formed therein in which an optical fiber 20 is inserted, and the optical fiber 20 inserted into the duct 33; the optical fiber 20 includes a core 21, a cladding 22, a resin-coated layer 23 provided on the outer circumference of the cladding 22, a metal-coated layer 24 provided on the outer circumference of the resin-coated layer 23; and the resin-coated layer 23 is formed of a polymer compound having a refraction index lower than that of the cladding 22.

The core 21 and the cladding 22 of the optical fiber 20 can be configured with various optical fibers such as a silica-based optical fiber, a polymer clad optical fiber, a fluoride optical fiber, a chalcogenide glass optical fiber, and the like.

In the embodiment, a large diameter optical fiber in which a core diameter thereof (for example, a core diameter of 400 μm) is higher than that of an ordinary optical fiber for communication is used.

In the invention, not only the large diameter optical fiber, but optical fibers for energy transmission such as an image fiber (a multi-core optical fiber) and a polymer clad fiber can be used, and the types and the structures of the fibers are not particularly limited.

The resin-coated layer 23 is formed of a polymer compound having a refractive index lower than that of the cladding 22.

The material of the polymer compound used for the resin-coated layer 23 is selected according to the refractive index of the cladding 22.

For example, when the cladding 22 is formed of a pure silica glass, examples of the polymer compound having a refractive index lower than that (about 1.463) of the pure silica glass include a silicon resin, a fluoro-acrylic resin, a vinyl acetate resin, and the like.

In comparison, polymethyl methacrylate, polyimide, polycarbonate, and the like have a refractive index higher than that of the pure silica glass.

Even when a resin has a refractive index higher than that of the pure silica glass, if the refractive index of the core and the cladding is higher than that of the resin, the resin can be used for the invention.

It is preferable that the refractive index of the resin-coated layer 23 be 0.04 or more lower than that of the pure silica.

The metal-coated layer 24 can be configured with a metal such as copper (Cu), tin (Sn), or nickel (Ni) or with an alloy such as a Cu alloy, a Sn alloy, or Ni alloy.

When the metal-coated layer 24 is prepared by electrolytic plating, in order to impart conductivity to the surface of the resin-coated layer 23, a base metal layer is formed by a method such as electroless plating, sputtering, vacuum deposition, a chemical vapor deposition method, or the like.

It is preferable that the metal-coated layer 24 have a sufficient thickness that can hold the shape of the optical fiber 20 which is provided while bending in the probe tip portion 11 as shown in FIG. 1A.

Furthermore, it is preferable that the metal-coated layer 24 be provided with such a thickness that the optical fiber 20 has a plasticity (deformability) so that the probe tip portion 11 can be stretched linearly or bent or curved into a desired shape as shown by the two-dot chain line in FIG. 1A.

Generally, the probe includes a metal-coated layer; therefore, the probe is configured so that, even when the leakage of light is assumed to be caused by bending of the probe, the light does not leak out of the probe.

As shown in FIG. 1C, the multi-lumen tube 30 includes the duct 33 in which the water flow path 31, the air flow path 32, and the optical fiber 20 are inserted.

The optical fiber 20 is inserted into the duct 33.

One end of the multi-lumen tube 30 is a tip surface 39.

The other end of the multi-lumen tube 30 is housed within a probe body portion 12, as shown in FIGS. 1A to 1B and FIG. 2.

The shape of the exit end 26 of the optical fiber 20 is not limited to a planar shape perpendicular to the optical axis.

The shape can also be formed (or polished for example) into a bevel or a cone.

In the embodiment, the probe tip portion 11 is formed of the multi-lumen tube 30 and the optical fiber 20.

The multi-lumen tube 30 can be configured with a polymer compound such as urethane, stainless steel, or the like.

It is preferable that the multi-lumen tube 30 be formed of a polymer compound having flexibility, since the probe tip portion 11 can be deformed into a desired shape using one's fingers.

In the probe 10 of the embodiment, the metal-coated layer 24 is provided on the optical fiber 20.

Therefore, even when the probe tip portion 11 is bent, or the bending shape thereof is arbitrarily changed (deformed), it is possible to reduce the stress applied to the optical fiber 20 to suppress the damage or breaking of the optical fiber 20.

As shown in FIGS. 1C and 2, the duct 33 in which the optical fiber 20 is inserted is formed to continue from the tip surface 39 of the multi-lumen tube 30 to an end surface 39a at the other side.

In FIG. 1C, a clearance is shown between the duct 33 and the optical fiber 20; however, the duct 33 and the optical fiber 20 may be close to each other to such a degree that the optical fiber 20 can be inserted into the duct 33 without difficulty.

The water flow path 31 is partitioned from the air flow path 32 by a partition wall 36 throughout the entire length of the tube.

The water flow path 31 and the air flow path 32 are opened in the tip surface 39 of the multi-lumen tube 30.

When laser light is emitted from the exit end 26 of the optical fiber 20, water and air are respectively ejected from openings (outlets) of the flow paths 31 and 32, whereby the evaporated substances can be removed by cooling the position to be irradiated.

The probe body portion 12 can be configured with various materials such as polymer compounds (a resin, rubber, or the like) or metals, and the structure thereof is not particularly limited.

In the embodiment, the probe body portion 12 is made of a polymer compound and is formed integrally with the multi-lumen tube 30 made of a polymer compound.

Notches 14 and 15 are provided on the lateral surface of the probe body portion 12.

The multi-lumen tube 30 is exposed through each of the notches 14 and 15, and thin portions 34 and 35 of the multi-lumen tube 30 are cut and opened to form an inlet 37 of the water flow path 31 and an inlet 38 of the air flow path 32.

In the end surface 39a at the opposite to the tip surface 39 of the multi-lumen tube 30, the water flow path 31 and the air flow path 32 are closed in the probe body portion 12.

An incident end 25 of the optical fiber 20 extends backwardly (the right side of FIG. 2) from the end surface 39a of the multi-lumen tube 30, passes through an optical fiber path 16 that is in the probe body portion 12, and protrudes from a rear end surface 12a of the probe body portion 12.

When the probe body portion 12 is manufactured by insert molding, the flow paths 31 and 32 are filled with a detachable reinforcement material, the multi-lumen tube 30 including the duct 33 in which the optical fiber 20 is inserted is prepared, and a molten resin is supplied to the circumference of the optical fiber 20 and the multi-lumen tube 30 and solidified, whereby the optical fiber path 16 can be formed by using the shape of the exterior surface of the optical fiber 20 as a mold.

At this time, the notches 14 and 15 leading to the inlets 37 and 38 do not need to be opened in post-processing of the probe body portion 12.

The notches can also be formed by, for example, providing fins closing the inlets 37 and 38 to the interior surface of a mold so that the molten resin is not provided to the portions of the inlets 14 and 15.

In a laser handpiece for dental treatments, the dental probe 10 of the embodiment can be used for guiding laser light transmitted through the optical fiber 20 to a position to be irradiated.

FIG. 3 illustrates a configuration example of a laser handpiece.

A handpiece 40 herein is configured so that for example, an operator (particularly, a dentist) can operate the handpiece by gripping it with his or her hand, and the dental probe 10 is detachably mounted on a receptacle 42 provided at the tip side of a handpiece body 41.

The receptacle 42 presses the outer circumferential surface of the probe body portion 12 in the direction facing the central axis thereof with an O-ring 43, for example, and stabilizes the position of the optical axis.

Furthermore, by engaging the fastener 49 with a flange portion 13 which is formed to protrude from the exterior surface of the probe body portion 12, it is possible to prevent the dental probe 10 from coming off accidentally in use.

When the dental probe 10 is detached from the handpiece body 41, the fastener 49 is lifted up, an ejector 48 is moved to the tip side (the left side in FIG. 3) of the handpiece body 41 by using operation means (not shown), therefore the dental probe 10 is pushed out of the receptacle 42.

The handpiece body 41 is provided with a water supply tube 44 and an air supply tube 45.

The water supply tube 44 and the air supply tube 45 are connected to water and air supply devices (not shown).

The water supply tube 44 is connected to a water inlet 37 (see FIG. 1A) provided in the notch 14 of the probe body portion 12.

The air supply tube 45 is connected to an air inlet 38 (see FIG. 1B) provided in the notch 15.

At the rear end side of the handpiece body 41, an optical fiber 46 connected to a laser light source for supplying laser light is held.

The optical fiber 46 at the light source side and the optical fiber 20 of the probe 10 are optically coupled with each other in a non-contact manner through a collimator lens 47.

Consequently, compared to a case where the end surfaces of the optical fibers 20 and 46 are connected by being brought into contact with each other, an external force is not applied to the end surfaces of the optical fibers 20 and 46 in mounting or detaching the probe 10, so it is possible to prevent the end surfaces of the optical fibers 20 and 46 from being damaged.

During the dental treatment, the operator configures the handpiece 40 by mounting the probe 10 having an appropriate tip shape on the handpiece body 41, and emits laser light to a lesion while supplying water and air.

In this manner, the operator can perform the dental tissue treatment.

Even when the probe tip portion 11 is bent into a desired shape, a temperature rise of the probe tip portion 11 caused by the leakage of light from the optical fiber 20 is suppressed.

Therefore, there is no concern that a patient will experience an unpleasant sensation since he or she can feel the intense heat of the probe tip portion 11 or that the patient will be burned.

EXAMPLES

The present invention will be described in more detail based on examples.

The invention is not based only on the shape and dimensions of the examples, and is not particularly limited to the shape and dimensions including the core diameter, cladding diameter, fiber length, bending angle, coating diameter, metal coating diameter, tube structure as well as the material thereof.

Example 1

As shown in FIG. 1C, a metal-coated optical fiber was used which was obtained by coating copper having a thickness of 50 μm on the outside of a resin layer which was formed of a silicon resin (refractive index; 1.35) having a thickness of 50 μm on the outside of a large diameter fiber (core diameter; φ700 μm, cladding diameter; φ500 μm).

The metal-coated optical fiber had a structure in which a length thereof was 40 mm, and a bending angle at the central portion thereof was 30°.

This fiber was inserted into a tube made of urethane having a multi-lumen structure, followed by integral molding by using a mold, therefore preparing a probe.

Example 2

A probe was prepared in the same manner as in Example 1, except that a fluoro-acrylic resin (refractive index; 1.42) was used instead of the silicon resin.

Example 3

A probe was prepared in the same manner as in Example 1, except that a vinyl acetate resin (refractive index; 1.46) was used instead of the silicon resin.

Comparative Example 1

A probe was prepared in the same manner as in Example 1, except that polymethyl methacrylate (refractive index; 1.49) was used instead of the silicon resin.

Comparative Example 2

A probe was prepared in the same manner as in Example 1, except that a polyimide resin (refractive index; 1.52) was used instead of the silicon resin.

Comparative Example 3

A probe was prepared in the same manner as in Example 1, except that a polycarbonate resin (refractive index; 1.59) was used instead of the silicon resin.

Test Example

The samples (n=10) of the examples and comparative examples were continuously irradiated for 10 seconds by an erbium YAG laser with an output of 350 mJ and at a repetition speed of 10 pps.

Thereafter, the temperature immediately after (10 seconds after) the continuous irradiation at the central portion of the probe bending at 30° was measured by using a commercially available contact-type thermometer.

The test was performed at room temperature (23° C.)

<Test result> The test result is shown in Table 1.

The measured temperature in the table is an average value of n=10.

	TABLE 1
	Material name	Refractive	Temperature
	of resin layer	index	(° C.)
Example 1	Silicon resin	1.35	23.3
Example 2	Fluoro-acrylic resin	1.42	23.3
Example 3	Vinyl acetate resin	1,46	23.7
Comparative example 1	Polymethyl	1.49	26.8
	methacrylate
Comparative example 2	Polyimide resin	1.52	41.9
Comparative example 3	Polycarbonate resin	1.59	47.7

>Discussion<

As shown in the test result in Table 1, it is considered that, in the probes (Comparative examples 1 to 3) having a refractive index of the resin-coated layer higher than that of the cladding (pure silica glass), the laser light leaks at the site that has been subjected to the bending process and is diffused to the metal-coated layer side.

Conversely, it is considered that, in the probes (Examples 1 to 3) having the refractive index of the resin-coated layer lower than that of the cladding, the laser light does not leak at the side that has been subjected to the bending process, and the diffusion of the laser light to the metal-coated layer is limited.

It is known that the refractive index of the pure silica layer is about 1.463.

Since the refractive index of Comparative example 1 was slightly higher than that of the pure silica, the temperature was confirmed to rise by several ° C., which is clearly not preferable.

Example 3 was at the same level as the pure silica in terms of the refractive index.

Therefore, a large degree of temperature rise was not confirmed.

However, on the assumption that the bending angle may be 30° or more and that the laser irradiation of higher power may be performed for a long time, it is considered that the margin of the temperature rise may be small.

From the result above, it was determined that the refractive index of the resin-coated layer used in the dental probe of the invention is preferably lower than that of the pure silica layer, and more preferably by 0.04 or more lower than that of the pure silica layer.

Additionally, the presence or absence of the light leakage depends on the difference in the refractive index between the cladding of the optical fiber and the resin-coated layer outside thereof.

Consequently, even when the material of the cladding is not a pure silica layer, the temperature rise can be suppressed in the same manner by setting the refractive index of the resin-coated layer to be lower than that of the cladding.

According to the present invention, since the resin-coated layer is formed of a polymer compound having a refractive index lower than that of the cladding, the resin-coated layer can suppress the leakage of the laser light caused by bending loss, by functioning as the second cladding in the optical fiber.

As a result, it is possible to prevent a temperature rise in the probe.

Claims

1. A dental probe provided in a laser handpiece for guiding laser light transmitted through an optical fiber to a position to be irradiated during dental treatment, wherein a tip portion of the dental probe comprises a water flow path, an air flow path, a multi-lumen tube including a duct formed therein into which the optical fiber is to be inserted, and the optical fiber inserted into the duct;wherein the optical fiber comprises a resin-coated layer provided on an outer circumference of a cladding, and a metal-coated layer provided on an outer circumference of the resin-coated layer, andwherein the resin-coated layer is formed of a polymer compound having a refractive index lower than that of the cladding.

2. The dental probe according to claim 1, wherein the refractive index of the resin-coated layer is 0.04 or more lower than a refractive index of pure silica.