DE9208617U1 - Dental dual wavelength laser device - Google Patents

Description

Dental dual wavelength laser device

The innovation relates to a device for the selective removal and cutting of hard (enamel) and soft (dentin) tooth material, for cutting and coagulating soft tooth tissue, for root canal preparation, for enamel conditioning, for fissure closure and for the production of ceramic and plastic-based tooth fillings by means of laser light according to the generic term of the main claim.

When laser light interacts with tissue material, the wavelength of the emitted laser radiation is a decisive factor influencing its reaction. In soft tissue with a water content of more than 60%, for example, characteristic spectral absorption bands are seen that are dominated by the absorption behavior of the water. At wavelengths of around 2 and 3 um, these are particularly pronounced, so that the penetration depth of this laser radiation into the tissue is extremely low. Hard tissue, such as bone and tooth enamel, has a very low water content and therefore shows the absorption behavior of its individual tissue components, so that for certain laser wavelengths, additional artificial absorbers must be used for effective ablation. Only in

25In the ultraviolet and far infrared range of the electromagnetic spectrum, pronounced self-absorption occurs again due to specific atomic or molecular properties of the tissue material.
The individual interaction mechanisms are

30men of laser radiation with tooth enamel, for example, at a wavelength of 10.6 μm it is a purely thermal effect, associated with melting and evaporation of the material, at 2.94 μηη it is a thermo-mechanical effect with evaporation and micro-explosions, at 193 nm it is a decompositional

35Effect combined with a fine atomization of the tooth material.

Depending on the tissue composition, a suitably adjusted laser wavelength will therefore produce optimal ablation results with minimal thermal and acoustic side effects.

Basic findings on laser/tissue interaction and the current technical status of the use of laser radiation in dentistry are presented in the publications ' R. Hibst: Laser use in dentistry - basic principles and current status, MedTech 2(4),1991,18-23 and M. Franetzki: Laser in dentistry, Magazine for Dentistry, Management and Culture, 7,1991,9-14 '.

The innovation is based on the task of creating a solid-state dental two-wavelength laser system that can optionally provide different wavelengths using a modified dental laser handpiece.

which can be optimally adapted to the respective processing mode to be carried out on the tooth and transmitted via the same flexible laser handpiece. This makes it possible for the first time to carry out the following dental procedures with a single laser device:

Selective ablation of caries, preparation of dental cavities, shaping of dental cavities, crown or partial crown preparation, cavity filling and hardening, treatment of sensitive tooth necks, enamel conditioning, processing of ceramic or plastic inlays, fissure closure, root canal preparation, periodontal and surgical work, as well as repairs to ceramic defects.

This problem is solved according to the innovation by the characterizing features of the main claim in conjunction with the features of the generic term.

30The measures specified in the subclaims enable advantageous further developments and improvements.

WO 90/01907 discloses a dental laser arrangement that uses a Nd:YAG laser crystal at a wavelength of 1.06 um 35 for dental treatment. However, this wavelength is hardly absorbed by the tooth enamel itself.

From the published patent application DE 38 41 503 a method and a device for removing tooth tissue is known, whereby

pulsed laser radiation in the wavelength range of 2.5-3.2 μηη is used.

Furthermore, from the published patent application DE 39 11 871, a method for destroying and removing tooth material has become known, which uses a thin layer of a liquid, in particular water, that absorbs the incident laser radiation for the removal.

Furthermore, from the published patent application DE 40 30 734, a method and a device for treating tooth defects, as well as for preparing and filling root canals and tooth cavities is known, which uses an Alexandrite laser with wavelength ranges of 720-860 nm and 360-430 nm.

The innovation is shown in drawing 1 and is explained in more detail in the following description.

Show it:

Fig.l an overall view of the individual components of the new dental two-wavelength laser device,

Fig.2 a detailed view of the wavelength generation device as a swivel unit and

25Fig.3 a detailed view of the wavelength generation device as a plug-in unit.

Fig. 1 shows an overall view of the individual components of the solid-state dental two-wavelength laser device for carrying out various dental treatment procedures on hard and soft tooth material. This consists of a pump laser system 1, external beam control units 8 and 9, an external wavelength generation device 10, a beam coupling device 11 and a dental laser handpiece 18 with an optical fiber transmission unit 13 and separate connections 14 and 15 for incoherent illumination with an external cold light source or for an air/liquid mixture from an external supply unit 16. Furthermore, an additional connection for suctioning the rinsing liquid from the tooth area can be present. All channels are led separately via a common hose section 17 from the laser device to the dental laser handpiece 18.

When removing and cutting hard (enamel) or soft (dentin) tooth material, when cutting and coagulating soft tooth tissue, when conditioning enamel, when closing fissures and when making fillings in tooth cavities, the dental laser handpiece 18 is equipped as a handpiece with a focusing head part 19; when preparing and filling root canals, the head part 19 contains a thin, flexible single glass fiber. Both head part variants can be connected to the laser handpiece 18 using quick-release fasteners.

The pump laser system 1 includes a laser medium 4 that is optically pumped by a pulsed light source 5, in particular a xenon flash lamp, and is enclosed in a resonator cavity by the two mirrors 2 and 3. The laser material 4 is a laser crystal that can be tuned in the wavelength range of 650-1100 nm and is made of chromium-doped materials such as Cr:GSGG, Cr:LiCAF, Cr:LiSAF, preferably CrIBeAl ₂ O ₄ (alexandrite), or titanium-doped sapphire (TItAl ₂ O ₄ ). The laser mirror 2 is totally reflective for the wavelength range of 650-1100 nm, the mirror 3 is partially reflective for the same range, with a typical reflection factor of 50-70%. In particular, the resonator cavity is constructed as an unstable resonator, with a special shape of the two resonator mirrors 2 and 3. The totally reflecting mirror 2 is

for example, designed as a convex mirror, the output mirror 3 is in particular a concave-convex mirror with a gradient laser mirror layer on the component side facing the laser crystal 4. The reflectivity of this mirror layer decreases, for example, according to an exponential law towards the edge of the mirror, with the central reflectance on the optical axis of the pump laser system 1 being 70%. This creates an almost homogeneous, step-like intensity distribution in the laser beam cross-section after the laser radiation exits the output mirror 3. This is advantageous for frequency doubling.

Furthermore, the pump laser system 1 has an optical Q-switch 6 for generating individual laser pulses of high peak power with pulse widths of 10-300 nanoseconds.

Furthermore, the pump laser system 1 has an internal optical adjustment unit 7, preferably a birefringent filter system, which enables the continuous tuning and/or selection of a specific wavelength from the broadband emission range of the tunable laser medium 4. In the case of alexandrite, for example, this is the wavelength range of 720-860 nm. The optical adjustment unit 7 is particularly important in connection with the wavelength generation device 10, which contains special optical crystals 26 for wavelength doubling or shifting. For example, the birefringent filter system is automatically set to a wavelength of 785 +/- 2 nm when optically pumping a Tm:YAG crystal in the wavelength generation device 10. Furthermore, the pump laser system 1 is designed such that it allows an increased operating temperature of the optical pump chamber, in particular in the temperature range of 15-250 ^° C. This leads to a higher laser efficiency, in particular when using alexandrite as the laser medium 4.

Behind the output mirror 3, a first beam attenuator 8, preferably a polarization filter, is arranged so as to be rotatable in the beam path in order to regulate the output power of the pump laser system 1. Together with a second beam attenuator 9, also preferably a polarization filter, the ratio of the radiation outputs of the pump laser system 1 and the wavelength generation device 10 can be individually adjusted.

The wavelength generating device 10 is described in more detail in Figs. 2 and 3.

A beam coupling device 11 in the form of a surface mirror, preferably an off-axis paraboloid, focuses the different wavelengths of the pump laser system 1 and the wavelength generation device 10 simultaneously onto the entrance surface of a common optical waveguide 12 so that all laser beams coincide at the same coupling location.

An optical fiber transmission unit 13 enables, in addition to the optical fiber 12, preferably a quartz glass optical fiber with a core diameter of 400-800 µm, the connection of an external incoherent illumination in the form of a cold light source and the feeding of an air/liquid mixture, preferably an air/water aerosol under pressure, from an external supply unit 16. The air/liquid mixture is used either for additional cooling of the tooth surface, for rinsing the tooth cavity during treatment or for increasing the absorption of the laser radiation of different wavelengths transmitted through the optical fiber 12. For example, a tetracycline is added to the air/water aerosol.

added in a low concentration to further increase the absorption capacity of the frequency-doubled alexandrite pump laser in the wavelength range of 360-430 nm on a healthy enamel surface and to further reduce the threshold energy density for ablation.

In Fig. 2 and 3, a detailed view of the wavelength generation device 10 is shown as a swivel or slide-in unit. In both representations, the same numbering corresponds to the same functional units.

With the aid of the wavelength generation device 10, any optical crystals 26 for wavelength doubling or shifting can be optionally and independently pivoted or inserted into the optical beam path of the pump laser system 1. These are accommodated in through-holes 20-22 arranged separately from one another. The surgeon then determines the desired wavelength range from the outside depending on the type of therapy and the corresponding optical crystal is pivoted or inserted into the beam path.

The correct position is monitored by sensors 23 and 24, for example inductive proximity switches, and with the help of coding elements 25.
Nonlinear optical crystals, such as beta-barium borate (BBO) or lithium triborate (LBO), are used to double the wavelength. Tunable wavelengths in the range of 325-550 nm can be achieved from the tunable wavelength range of 650-1100 nm of the pump laser system 1. Optical laser crystals, such as a thulium-doped yttrium aluminum garnet (Tm:YAG) or an erbium-doped yttrium aluminum garnet (Er:YAG) laser crystal, are used to shift the wavelength. Tunable wavelengths in the range of 1850-2160 nm and 2740-2940 nm can be generated from the tunable wavelength range of the pump laser system 1.

The entire dental laser device is controlled and safety monitored via a central computer system.

Claims (1)

Expectations Dental two-wavelength laser device for the selective removal and cutting of hard (enamel) and soft (dentin) tooth material, for cutting and coagulating soft tooth tissue, for root canal preparation, for enamel conditioning, for fissure closure and for the production of plastic- or ceramic-based tooth fillings, characterized in that the entire device consists of a pump laser system (1) with an internal wavelength selection device (7) and an internal optical switch (6), external beam control units (8) and (9), an external wavelength er- 15generation device (10), a beam coupling device (11) and a dental laser handpiece (18) with an optical fiber transmission unit (13) and separate connections (14) and (15) for an incoherent illumination or an air/liquid mixture from a supply unit (16). 20 and is controlled by a central computer system.
2. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) is a pulsed chromium 25-doped beryllium aluminate (CrIBeAl ₂ C^) laser, a chromium-doped gadolinium gallium garnet (Cr:GSGG) laser, a chromium-doped lithium strontium aluminum fluoride (Cr:LiSrAlFg) laser, a chromium-doped lithium strontium gallium aluminum (Cr:LiSrGaAlFg) laser or a titanium-doped sapphire (Ti: 3OAI2O4) laser with a tunable wavelength range of 650-1100 nm.
3. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has pulse widths of 35100-750 iisec .
4. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has a temporal course of the overall pulse shape, the individual oscillator relaxation oscillations ('spikes') with a half-width of 300-1000 nsec. Dental dual-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has repetition rates of 1-100 Hz.
6. Dental dual-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has an internal optical Q-switch (6) made of a non-linear optical crystal.
7. Dental dual wavelength laser device according to claim 6, characterized in that the internal optical quality switch is electro- I5optical or acousto-optical.
8th. Dental two-wavelength laser device according to claim 6, characterized in that the optical Q-switch (6) enables laser pulse widths of 10-300 nsec. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has an internal birefringent filter system (7) for continuously adjusting the pump laser radiation in the wavelength range of 650-1100 nm. 25sits.
10. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has an optical pump chamber which enables laser operation at elevated temperature 30enabled.
11. Dental dual-wavelength laser device according to claim 10, characterized in that the temperature range of the pumping chamber is from 15 to ^{250 °} C. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) is constructed as an unstable resonator.
13. Dental two-wavelength laser device according to claim 1, characterized in that the pump laser system (1) has a partially reflecting gradient laser mirror as an output mirror (3).
14. Dental two-wavelength laser device according to claim 13, characterized in that the partially reflecting gradient laser mirror layer follows a reflection law R(r), for which the following applies: R(r)=R ₀ x exp(-(r/w)^) with Rq=O.7 and w=1.8 mm. Dental two-wavelength laser device according to claim 1, characterized in that the two laser mirrors (2) and (3) of the pump laser system (1) produce a homogeneous, step-like intensity distribution in the laser beam cross-section after the laser beam exits. 15super radiation is generated from the output mirror (3). 16. Dental two-wavelength laser device according to claim 1, characterized in that the output power of the pump laser system (1) can be continuously varied by a first polarization filter (8).
17. Dental two-wavelength laser device according to claim 1, characterized in that optical crystals for wavelength doubling or wavelength shifting can be pivoted or inserted into the beam path of the pump laser system (1) selectively and independently of one another. 18. Dental two-wavelength laser device according to claim 17, characterized in that the pivoting or insertion unit (10) 30can accommodate any number of optical crystals in separate through holes (20-22). 19. Dental dual wavelength laser device according to claim 17, characterized in that the optical crystals for wavelength 35Doubling nonlinear optical crystals made of beta-barium borate (BBO), lithium triborate (LBO), potassium titanyl phosphate (KTP) or bismuth titanate (BTO). 20.
Dental dual wavelength laser device according to claim 19, characterized characterized in that additional tunable laser wavelengths in the range of 325-550 nm can be generated by the nonlinear optical crystals with the aid of the pump laser system (1). Dental two-wavelength laser device according to claim 17, characterized in that the optical crystals for wavelength shifting are made of thulium-doped yttrium aluminum garnet (Tm:YAG), thulium-holmium-doped yttrium aluminum garnet (Tm,Ho:YAG), thulium-erbium-doped yttrium aluminum garnet (Tm,Er:YAG), holmium-doped yttrium aluminum garnet (Ho:YAG), erbium-doped yttrium aluminum garnet (Er:YAG) or erbium-doped yttrium scandium gallium garnet (Er:YSGG) with different doping of the laser-active atoms. Dental two-wavelength laser device according to claim 21, characterized in that the laser crystals can generate additional tunable laser wavelengths in the range of 1850-2160 nm or 2740-2940 nm with the aid of the pump laser system (1). Dental two-wavelength laser device according to claim 20, characterized in that the optical Q-switch (6) of the pump laser system (1) is activated to generate wavelengths in the range of 325-550 nm. Dental two-wavelength laser device according to claim 17, characterized in that the pivoting or insertion unit (10) is monitored in its respective position in a coded manner by inductive proximity switches (23) and (24). Dental two-wavelength laser device according to claim 17, characterized in that the output power of the laser radiation from the wavelength generating device (10) can be continuously varied by a second polarization filter (9). Dental two-wavelength laser device according to claim 1, characterized in that the ratio of the output power of the pump laser (1) to the output power of the laser radiation from the wavelength generating device (10) is determined by the first (8) and the second (9) polarization filter can be freely and continuously adjusted. Dental two-wavelength laser device according to claim 1, characterized in that an off-axis paraboloid is used for the simultaneous coupling of the laser radiation of the pump laser system (1) and the laser radiation from the wavelength generation device (10).
28. Dental two-wavelength laser device according to claim 1, characterized in that the connection unit (13) of the dental laser handpiece (18) has an optical fiber transmission unit (12) for the laser radiation, an optical fiber unit (14) for incoherent illumination and a connection (15) for an air/liquid mixture from a supply unit (16).
29. Dental two-wavelength laser device according to claim 28, characterized in that a tetracycline is added to the liquid Dental dual wavelength laser device according to claim 29, characterized in that the tetracycline is a derivative of doxycycline, chlortetracycline, demeloxycycline, oxytetracycline or rolitetracycline.
31. Dental dual-wavelength laser device according to claim 28, characterized in that the air/liquid mixture is an air/water aerosol under superatmospheric pressure. 30