FR2773986A1 - Dental composite materials hardening device - Google Patents

Abstract

A box includes a light source (11), a central control unit (2) for controlling the light source while a light wave guide (4) is coupled to the box at one end. A treatment wand is connected to the other end of the light wave guide. An optical filter set (5) is interposed in the light path between the light source and the treatment wand. The filter provides at the treatment wand a light beam having a spectral band ranging from 250-750nm. The filtering set (5) includes a first infrared filter (50) stopping the infrared radiation harmful to the behavior of the optical fiber (4) and having no useful purpose in the present application. A second filter (51) of the low-pass type cuts the high frequencies above 500nm. A third filter (52) of the high-pass type eliminates frequencies below (450nm. The combination of the three filters (50,51,52) allows a frequency band to pass transmitting a fraction of the emission spectrum of the lamp.

Description

 The subject of the present invention is a device making it possible in particular to harden composite materials used in the dental field.

 The composite materials used in dentistry are generally based on a photopolymerizable resin whose molecular structure is transformed under the effect of radiation of a wavelength determined as a function of the absorption capacity of said composites. .

 The photopolymerization of the composite material is carried out by means of a source emitting radiation of a wavelength activating the photoinitiators of the material, for a calculated exposure time, as a function of the energy of the radiation, to avoid excessive heating of the tissues surrounding the treatment area.

The wavelength, radiation intensity and exposure time parameters are also determined according to the color of the material, in particular by setting a higher intensity for a composite with a darker color or with a higher charge. However, the increase in the intensity of the radiation emitted involves a risk of excessive heating of the surrounding tissues.

 Devices are known for hardening soft composite materials which use mercury vapor lamps, but these emit in the ultraviolet spectrum, which is dangerous for the eyes and the oral mucosa of the patient.

 Other devices use halogen lamps which have the disadvantage of having a low lumen / watt ratio and a high heat dissipation compared to the light energy produced, which means that the rise in power must be limited to obtain greater intensities.

 Some devices are equipped with a laser, but the light beam they generate is monochromatic light which, due to its narrow wavelengths, can polymerize only a limited number of composites. In addition, the laser is an expensive device which presents a high cost of maintenance and implementation.

 Other devices use on the one hand a light source generated by two spaced electrodes and subjected to differences in electrical potential capable of producing an electric arc through which a gas which is partially ionized at high temperature passes, and on the other hand a system for filtering the light emitted comprising an infrared filter placed immediately in front of the source and making it possible to obtain a light emission spectrum between 400 and 800 nm and a low-pass filter placed after said infrared filter and making it possible to fix the high cutoff frequency of the filter at approximately 515 nm.

 Document FR-A-261132 describes a device for cutting or treating hard or soft materials, in particular living tissue, by producing a stream of ionized gas, the emitted light of which can be used to activate the photopolymerizations of substances, especially certain resins, using filters placed in front of the source.

 However in these devices the filtering system does not make it possible to increase the light power of the source without danger, because the light energy absorbed by the biological tissues can lead to their destruction in the event of a sharp rise in temperature. In addition, the energy profile, which represents the variations in light intensity over time, cannot be adjusted according to the application, in particular to adapt to composite materials of different colors.

 The object of the present invention is to remedy these various drawbacks of known devices by proposing a device for treating composite materials, with a view in particular to their hardening, using radiation whose energy profile can be changed dynamically. , depending on the application, to carry out a gradual photopolymerization making it possible to reach the different layers of the composite, whatever its color, and which also makes it possible to greatly reduce the processing time of said material.

 The treatment device according to the present invention is of the type comprising a central control unit, a light source connected to said central unit, a light wave guide for applying light energy to the area to be treated and, between said light source and said guide, a means of filtering the emitted light, this device being characterized essentially in that the filtering means is chosen so that the light spectrum leaving the light wave guide lies in a band ranging from 450 to 500 nm and in that the central control unit comprises on the one hand electronic means making it possible to define and / or memorize an energy profile as a function of the color of the composite to be treated and / or of the type of photoinitiators that the composite contains , and on the other hand electronic means for controlling the light power of the source and possibly the filtering means to vary the characteristics said filtering.

 According to an additional characteristic of the device according to the invention, the filtering means comprises, arranged successively from the source towards the entry of the light guide, a first infrared filter then two low-pass and high-pass filters, arranged in this order .

 According to another additional characteristic of the invention at least one of the low-pass or high-pass filters is a polarizing filter electrically connected to the central unit and the transmission characteristics of which can be modified by said central unit as a function of the energy profile corresponding to the composite to light-cure.

 In a first embodiment of the invention the central unit includes in its memory a table of energy profiles each corresponding to a composite of determined color or to a composite whose photoinitiators react to another wavelength of the radiation, selectable by means of keys arranged on the box enclosing said central unit.

 In another embodiment, the energy profile of a composite of a given color is calculated automatically by means of a spectro-colorimeter, the measurement signal of which, representative of the color of the material to be hardened, is processed by the unit. central to determine an energy profile possibly stored.

 The advantages and characteristics of the present invention will emerge more clearly from the description which follows and which relates to the appended drawing, provided by way of simple illustration of the invention, with respect to which it has no limiting character.

In the attached drawing
- Figure 1 shows the block diagram of the device according to the invention.

 - Figure 2 shows the source spectrum and the frequency band at the output of the device filter as well as the frequency band of the filters of existing devices.

 - Figure 3 shows the block diagram of the central unit of the device.

 - Figure 4 shows a plan view of the filtering device in a particular embodiment.

 If we refer to Figure 1 we can see that a device according to the invention comprises a housing 1 housing a light generator 10 comprising a lamp 11, controlled by an electronic central unit 2 intended for managing the control of the generator of light as a function of the parameters of a composite material 3 to harden by exposing it to the light radiation emitted by the lamp 11. The light radiation is conveyed on the material to be treated by means of an optical fiber 4 connected by one of its ends at the outlet of a filtering device 5 placed in front of the light source 11 and by its other end to a bent end piece 40.

 The case 1 is provided with a keyboard 12 comprising thirteen tactile keys 13 and control lights 14 to allow the operator to interact with the device.

 Among the thirteen tactile keys 13, eight keys 130 allow the user to adjust the application time, three keys 131 serve to adjust the power level of the lamp 11, and two keys 132 allow to select an operating mode of the device.

 The tests have shown that the light spectrum leaving the light waveguide should preferably be situated in a band ranging from 450 to 500 nm and that the light intensity measured at the output of the waveguide, that is to say say where the light intensity useful for the photopolymerization of the composite 3 to be cured is available, must be at least of the order of 1 W / cm 2, and preferably of 1.3 W / cm 2.

 It will also be noted that the length of the optical fiber 4 must be determined so as to avoid a significant attenuation of the amplitude of the light radiation and therefore of its efficiency, and that it must preferably be equal to approximately 1.8 meters.

 The coating of the optical fiber 4 and the end piece 40 must be a material resistant to commonly used disinfection products, such as silicone, which is perfectly suitable for the medical field.

 The optical fiber 4 is preferably a liquid fiber allowing better transmission of light in the chosen spectral range and resistant to high energies, while the end piece 40 is made of a multi-strand polymer.

 The insertion of the optical fiber 4 into the light generator 10 is of the Push-Pull type and the bent end piece 40 is magnetically secured to the fiber 4 so as to promote its rotation.

 The light generator 10 preferably comprises a discharge lamp 11 delivering a power of the order of 300W, supplied by an alternating voltage source 15, and provided with focusing optics 16. The identical light spectrum of the lamp 11 that of the discharge lamps used in current devices is very wide, being in particular between 400 and 800nm.

 The filtering device 5 comprises, from the lamp 11, a first infrared filter 50 stopping the infrared radiation harmful to the holding of the optical fiber 4 and having no utility in the present application, followed by a second low pass type filter 51 cutting the high frequencies above 500nm, then a third high pass type filter 52 eliminating frequencies below 450nm.

 The combination of the three filters 50, 51 and 52 allows a frequency band 61 to pass, as can be seen in FIG. 2, transmitting a fraction of the emission spectrum 62 of the lamp.

 The high-pass filter 52 is an electrochemical filter electrically connected to the central unit 2, the molecular structure of which can be modified by sending an electrical signal, or by any other electrical or optical means changing its transmission characteristics from light and therefore the value of its low cutoff frequency 520.

 The low-pass filter 51 can also be controlled by the central unit 2 so as to also modify its high cut-off frequency 510.

 It should also be noted that it is also possible to have several filters remotely controlled or controlled remotely by radio or by an infrared fascia, by the central unit 2, selectively, automatically, or using electronic cards with insertable memories. in housing 1.

 It is also possible to modify this transmission by using filters sensitive to certain wavelengths. The method then consists in placing a photosensitive filter at a wavelength different from the wavelength used for the photopolymerization, as can be seen in FIG. 4. In this particular embodiment of the filtering device 5, the filter intermediate is a photosensitive filter 57 and the device comprises a plasma source 55 for the photopolymerization and a source 56 for the photosensitivity of the filter. Thus, depending on the desired intensity, the efficiency of the sensitive filter is more or less increased, which makes it possible to adjust the intensity transmitted in the optical fiber 4.

 We can also see in FIG. 2 a horizontal straight line 53 which represents the value of the power of the lamp 11. We know that the capacity for absorbing light by a composite material 3 is proportional to the total energy of the lines, represented schematically by the curve 62, being under the right line 53 in the frequency band 61 of the light emission and that it therefore becomes more important during an increase in power which has the effect of heating the tissues surrounding the. area to be treated if the exposure time is kept.

 The filtering device of the device according to the invention makes it possible to avoid this overheating by installing a more powerful light source 11 while significantly reducing the exposure time and the spectral area. Indeed, as shown in FIG. 2, the filters 50, 51 and 52 make it possible to use a lamp with a power 54 greater than that, 53, of current lamps and to greatly reduce the exposure time while retaining the same capacity for absorbing materials exposed to radiation, by reducing the width of the frequency band 60 that the filtering devices of current devices passing between 360 and 530nm allow to pass, the frequency band 61 being between 450 and 500nm.

 The low-pass filter 51 will preferably be inclined to avoid retransmission of reflections on the lamp 11.

 Given the geometry of the lamp 11 retained two heat sinks, not shown, held by a wedge of insulating material respecting the dielectric characteristics necessary for starting the lamp 11 and provided with connection pads will be fixed to the anode and to the cathode of the lamp 11, that of the anode will further comprise a bore intended to accommodate the optical filters 50, 51 and 52.

 Referring now to FIG. 3, it can be seen that the central unit 2 comprises a microprocessor 20 and read-only memories 21 and live 22, an electronic circuit 23 for controlling the power of the lamp powered from the source of alternating voltage 15 and connected to the microprocessor 20, which is also electrically connected to the keys 13 of the keyboard 12 and to the light-emitting diodes 14.

 The microprocessor 20 is electrically connected to the electrochemical filter 51 and controls the latter and the control circuit 23 as a function of an energy profile stored in the random access memory 22 corresponding to a processing cycle of a composite material of a given color and photopolymerizable by the radiation emitted by the light source 10.

 The energy profiles can be stored, in a first embodiment of the device according to the invention, beforehand, by the manufacturer, in the read-only memory 21 as a function of the color composites currently used, the user only having to select one of the thirteen keys 13 of the keyboard 12 of the box 1. In a second embodiment of the invention the energy profiles can be defined and stored by means of a measuring instrument making it possible to determine the optical characteristics of the material by sending to the microprocessor a signal representative of these characteristics which is processed using a processing program integrated into the read-only memory 21 in order to define the energy profile to be applied to the composite material by controlling the control circuit and possibly the filter 51, said energy profile also being stored in random access memory 22.

 In this last embodiment, the measurement of the color of the material can be made for example by spectrocolorimetry, either using optical fiber 4 which will transmit a measurement radiation whose return will be analyzed by the microprocessor to deduce the profile. energy, either from an independent measurement means connected to the housing 1. This embodiment allows automatic and immediate configuration, by the user, of a type of composite material to be treated whatever its color and composition, following the indication of a digital screen which would be integrated into the housing 1.

 The microprocessor 20 is also connected to a remote control means, not shown, such as a pedal, by means of a dry contact provided with an anti-rebound mechanism, hardware or software, allowing the user to start the photopolymerization cycle that he has previously selected.

 The device according to the invention makes it possible to obtain a gradual photopolymerization of the composite material to be treated in order to reach the different layers thereof in a very short time thanks to the variation of the power of the source 11 by means of the piloted control circuit. by microprocessor 20 according to a selected energy profile and perfectly suited to the composite.

 I1 also makes it possible to avoid excessive heating of the tissues surrounding the treatment zone by varying the frequency band of the filtering device 5 by virtue of a modification of the transmission characteristics of the filter 51, 52 or 56, under the effect of a signal emitted by the microprocessor 20 and determined as a function of the parameters of the selected energy profile.

 It will be noted that the modification of the color of the liquid of the optical fiber 4 can also make it possible to modify the light energy of the radiation that it carries.

Claims (9)

 CLAIMS 1) Device making it possible in particular to harden composite materials (2) used in the dental field of the type comprising a central control unit (2), a light source (11) connected to said central unit (2), a guide light waves (4.40) for applying the light energy to the area to be treated and, between said light source (11) and said guide (4.40), a means of filtering the emitted light, characterized in that the filtering means (5) is chosen so that the light spectrum leaving the light waveguide is in a band from 430 to 500 nm and in that the central unit (2) comprises on the one hand means electronic (20,21,22) for defining and / or storing an energy profile according to the color of the composite (3) to be treated and / or the type of photoinitiator that the composite contains, and electronic control means ( 23) the light intensity of the source and possibly t filter means (5) for varying the characteristics of said filtering. 2) Device according to claim 1 characterized in that the filtering means (5) comprises, arranged successively from the source towards the entry of the light guide, a first infrared filter (50) and two low-pass filters (51, 56) and high pass (52), arranged in this order. 3) Device according to claim 2 characterized in that at least one of the low-pass filters (51, 56) or passehaut (52) is an electrochemical or photosensitive filter whose transmission characteristics can be modified by said central unit (2 ) as a function of the energy profile corresponding to the composite (3) to be light-cured. 4) Device according to any one of the preceding claims, characterized in that the central unit (2) has in its memory a table of energy profiles, each corresponding to a composite of a determined color or to a composite whose photoinitiators react at another wavelength of the radiation selectable by means of keys (13) accessible on the housing (1). 5) Device according to any one of claims 1 to 3 characterized in that the energy profile of a composite of a given color is calculated automatically by means of a spectro-colorimeter whose measurement signal representative of the color of the composite material to be hardened is processed by the central unit (2) to restore an energy profile possibly stored therein (22). 6) Device according to any one of the preceding claims, characterized in that the optical guide (4.40) is an optical fiber (4) terminated at its free end by a bent end piece (40). 7) Device according to claim 6 characterized in that the optical fiber (4) is a liquid fiber (4) and in that the end piece (40) consists of a multi-strand polymer. 8) Device according to claim 6 or 7 caractésé in that 1'embout (40) is secured magnetically to the fiber (4) so as to promote its rotation. 9) Device according to any one of claims 7 or 8 characterized in that the light energy is selected according to the choice of fiber, with or

 bewildering.