ITPR20010014A1 - DEVICE FOR DENTAL USE, IN PARTICULAR FOR PHOTOPOLYMERIZING RESINS, COMPOSITE RESINS AND / OR GLASS-IONOMERIC SUBSTANCES AND PHOTOPOLYMERIZATION METHOD. - Google Patents

Description

DESCRIPTION

attached to a patent application for INDUSTRIAL INVENTION entitled:

DEVICE FOR DENTAL USE, IN PARTICULAR TO PHOTOPOLYMERIZE RESINS, COMPOSITE RESINS AND / OR GLASS-IONOMER SUBSTANCES AND PHOTOPOLYMERIZATION METHOD

The present invention relates to a device for dental use, in particular for photopolymerizing resins, composite resins and / or glass ionomer substances and a photopolymerization method which uses one or more LED diodes (Light Emiter Diode) as a light source.

As is known, composite resins and glass ionomer substances are used in various fields of dentistry where restorative materials, crack sealants, adhesives for metal, polymeric and ceramic orthodontic brackets are used.

These materials are normally hardened by photopolymerization by irradiation, using a light source radiating at a predetermined wavelength or frequency. In the case of resins, composite resins and glass-ionomer substances, the optimal wavelength is about 470 nanometers and in any case is included in a range between 400 and 500 nanometers.

To obtain adequate photopolymerization, this light source must be placed near the material itself (about 1 mm) and perpendicular to its surface.

The light sources used for photopolymerization must not only radiate light at a predetermined wavelength, but must also meet the requirement of not overheating. In fact, excessive heating, especially if the material is made to harden on a patient's tooth, can cause permanent damage to the tooth itself.

Currently, irradiation is performed using halogen or plasma lamps that radiate light in a predetermined range of wavelengths.

Halogen lamps emit broad spectrum light in a wavelength range around 470 nanometers. This results in a lower photopolymerization efficacy, as a certain amount of radiant energy is dispersed over wavelengths that are not useful for the photopolymerization process; in this case, the irradiation time required to carry out the photopolymerization is about one minute.

Plasma lamps, on the other hand, emit light in a range of wavelengths narrower than that of halogen lamps and more centered on the wavelength of 470 nanometers. With plasma lamps it is therefore possible to obtain a more efficient photopolymerization, since, with the same electrical power absorbed by the network and the efficiency of the lamp, the radiant energy is concentrated on the wavelengths really necessary for the photopolymerization process. Therefore, a shorter irradiation time is required than that required for halogen lamps.

Both of these types of lamps comprise a fixed base, usually of moderate size, connected to the electrical network and a mobile handpiece, of smaller dimensions, connected to said fixed base to operate on the material to be photopolymerized. The light is guided inside the handpiece by optical fibers and is emitted from one end of the handpiece itself; this end is shaped in such a way that it can be suitably oriented with respect to the surface of the material to be irradiated.

The lamps used for the polymerization of materials for dental use briefly described above have some drawbacks.

First of all, halogen lamps radiate in a wide range of wavelengths, which, while including 470 nanometers, involves an irradiation time of about one minute to obtain an optimal result. In this way, the operator must keep the handpiece of significant size in the vicinity of a tooth for such a time that he struggles to keep his hand perfectly still and therefore risks making a non-homogeneous polymerization.

Disadvantageously, although plasma lamps polymerize in a shorter time than that required by halogen lamps, they have a very high cost.

Another disadvantage is represented by the fact that both the handpiece of halogen lamps and the handpiece of plasma lamps have non-optimal dimensions, weight and handling characteristics, carrying, in addition to the lamp, a cooling fan which also generates noise. .

Disadvantageously, the optical fiber that conveys the light in the aforementioned handpieces is rigid and does not allow easy orientation of the beam within the oral cavity.

A further disadvantage is represented by the considerable bulk of the fixed base, both of halogen and plasma lamps.

The purpose of the present invention is to eliminate the aforementioned drawbacks by making available a device for dental use, in particular for photopolymerizing resins, composite resins and / or glass-ionomer substances, which is precise, light, small, low consumption, manageable effortless, easy to use, with the light beam adjustable in several directions and convenient to sterilize.

Another object of the present invention is to propose a device and a method for dental use, in particular for photopolymerizing resins, composite resins and / or glass ionomer substances, capable of irradiating light in a wavelength range centered on about 470 nanometers and in any case in a range between 400 and 500 nanometers.

A further object of the present invention is to provide a device for dental use which is safe, has a high energy efficiency and does not require any power supply from the electrical network.

Another object of the present invention is to propose a device for dental use, in particular for photopolymerizing resins, composite resins and / or glass-ionomer substances, which is economical to manufacture.

Said objects are fully achieved by the device and by the method for dental use, in particular for photopolymerizing resins, composite resins and / or glass ionomer substances, object of the present invention, which are characterized by the contents of the claims reported below.

These and other objects will be better highlighted by the following description of a preferred embodiment illustrated, purely by way of non-limiting example, in the accompanying drawing tables, in which:

Figure 1 shows a side view of a device for dental use, in particular for photopolymerizing resins, composite resins and / or glass ionomer substances, according to the present invention;

Figure 2 shows a side view of the device of Figure 1 with some parts removed to better highlight others;

- figure 3 shows the block diagram of the operation of the device illustrated in figure 1.

With reference to the figures of the attached drawings, the device for dental use, in particular for photopolymerizing resins, composite resins and / or glass-ionomer substances, according to the present invention, is generally indicated with the number 1 and is preferably made of plastic material and / or metallic.

The device 1 comprises a movable handpiece 2, shaped in such a way as to be inserted into the oral cavity of a patient. At one end 2a of said handpiece 2 is fixed, possibly in a removable way, at least one LED diode 3. In the illustrated embodiment, this LED diode 3 emits blue light in a wavelength range centered on about 470 nanometers and in any case within a range of 400 to 500 nanometers.

In an embodiment not shown, it is possible to fix said LED diode 3 inside the handpiece 2 and to guide the light emitted by the diode itself externally, by means of wave guides, typically optical fibers.

The end 2a of the handpiece 2 can be oriented at least in one plane and, in the illustrated example, this end 2a is made adjustable by means of the joint 2b, preferably made of polymeric material, or in any case elastic. By means of said orientable end 2a, it is easy to irradiate substances for dental use which are in positions of difficult access in the oral cavity of a patient. Alternatively, it is possible to insert said LED diode 3 at the end of a manually deformable cable and shaped in such a way as to stably assume any orientation.

In the preferred embodiment, the handpiece 2 also comprises a compartment 4 shaped in such a way as to allow the housing of a power supply unit 5, typically one or more batteries, and a corresponding cover 4a to close said compartment 4.

The LED diode 3 used in the example shown, provides for an ignition threshold of 3.5 volts and is able to generate a power equal to 3 candles with a power supply current of about 20 mA.

The device 1 can also comprise a lens 6, preferably made of glass and with a diameter between 2 and 13 millimeters, fixed to the end 2a of the handpiece 2, in order to protect and diffuse the light generated by the LED diode 3.

There are also means 7 for controlling, regulating and signaling the energy supplied over time to the LED diode 3, the block diagram of which is shown in Figure 3. These means 7 for controlling, regulating and signaling include:

- a 7805 type voltage regulator 8;

- a timer 9 type ICM 1555;

- a microcontroller 10 of the PIC12CXX type;

- a current regulator 11 composed of switchable precision resistors; - a photometer 12, in order to constantly check the intensity of the light beam emitted by the LED diode 3

In an embodiment not shown, it is possible to provide for remission of radiation suitably controlled by the end 2a of the handpiece 2, to allow a slight heating (not higher than 42.5 ° C) of the irradiated surface, since said slight heating is beneficial. and can promote the polymerization and hardening process of the material.

In an embodiment not shown, it is possible to use a fixed base of reduced dimensions in which to contain the mains and / or battery powered Trinity and the control means. A flexible electrical cable transmits the energy from the fixed part to the LED arranged, for example, in a short style equipped with a button to activate the light flow.

It is also possible to create a handpiece 2 equipped with a plurality of said LED diodes 3, each fixed to the same end 2a of the handpiece 2 or internally to the handpiece itself, guiding the light externally by means of optical fibers or other wave guides.

In an embodiment not shown, it is possible to supply the LED diode 3 by means of an alternating or pulsed current. In addition, it is possible to install a second LED diode that emits light on wavelengths sufficiently far from the range between 400 and 500 nanometers, in order to illuminate the area to be irradiated to make it easily visible to an operator.

In an alternative embodiment, it is possible to provide the device 1 with means for controlling, regulating and signaling the heat radiated by the LED diode 3 and with means for indicating, by means of light and / or acoustic signals, the activation of the beam. radiant.

The process of the present invention provides for the following steps.

The device 1 is switched on and positioned in such a way as to bring the light beam in the vicinity of the material to be photopolymerized, taking care to orient the light beam perpendicular to the surface of the material, in order to optimize the photopolymerization. Typically, irradiation occurs with light having a wavelength between 400 and 500 nanometers.

The irradiation is prolonged for a certain time interval, until a predetermined hardening of the material is obtained. In particular, the irradiation is prolonged for a time interval of less than 60 seconds.

At the end of irradiation, device 1 is turned off.

The invention achieves important advantages.

First of all, this device is small, light and silent, therefore easy to handle and does not tire the operator's hand. Furthermore, given its small size and battery power supply, the device according to the present invention is suitable for being easily transported.

Secondly, the end of the handpiece is flexible and interchangeable and allows you to easily and freely orient the light beam inside the oral cavity.

The device is also accurate, reliable, robust, safe, low maintenance and low operating cost, as it is completely solid state and does not contain moving mechanical parts. Furthermore, a device according to the present invention does not dissipate heat, can be powered independently from the electrical network and the LED diode is characterized by a fixed threshold voltage, a high MTBF and a high efficiency. All this makes it possible to make the intensity of the beam perfectly repeatable for each application. The absence of heat dissipation allows the handpiece to be built in watertight, thus making the whole instrument easily washable and sterilizable.

Another advantage is represented by the fact that several LED diodes can be fixed on this device, in order to increase the power radiated by the device itself and consequently decrease the time required for photopolymerization, thus facilitating the operator; in fact, the latter does not struggle to keep his hand perfectly still for a few seconds and therefore does not risk damaging the pulp of the tooth.

Advantageously, a device for dental use according to the invention has a very high energy efficiency.

Claims (20)

CLAIMS 1. Device (1) for dental use, in particular for photopolymerizing materials such as resins, composite resins and / or glass-ionomer substances, characterized in that it comprises: a mobile handpiece (2) shaped in such a way as to be inserted into the oral cavity of a patient; at least one LED diode (3) associated with the handpiece (2) and intended to emit light at a wavelength such as to photopolymerize said materials; And at least one power supply unit (5) of said LED diode (3). 2. Device according to claim 1), characterized in that it also comprises means (7) for controlling, regulating and signaling the energy supplied over time to the LED diode (3). 3. Device according to claim 1), characterized by the fact that said LED diode (3) emits light in a range of wavelengths between 400 and 500 nanometers. 4. Device according to claim 3), characterized by the fact that said LED diode (3) emits blue light in a range of wavelengths centered on about 470 nanometers. 5. Device according to claim 1), characterized by the fact that said LED diode (3) is fixed to one end (2a) of the handpiece (2), said end (2a) being orientable at least in one plane. 6. Device according to claim 1), characterized in that said LED diode (3) is fixed inside the handpiece (2) and is operatively associated with means for guiding the light emitted by said LED diode (3) up to the outside of the handpiece (2) itself. 7. Device according to claim 6), characterized in that said means for guiding the light emitted by the LED diode (3) are optical fibers. 8. Device according to claim 1), characterized by the fact that said LED diode (3) is provided with a manually deformable cable and shaped in such a way as to stably assume any orientation at least in one plane. 9. Device according to claim 1), characterized in that it further comprises means for controlling, regulating and signaling the heat radiated by the LED diode (3). 10. Device according to claim 1), characterized in that it also comprises means for indicating, by means of light and / or acoustic signals, the activation of the radiant beam. 11. Device according to claim 2), characterized in that said means (7) for controlling, regulating and signaling the energy supplied over time to the LED diode (3) comprise a photometer (12) to check the intensity of the light beam . 12. Device according to claim 1), characterized in that said feeding unit (5) is arranged on the handpiece (2) itself. 13. Device according to claim 1), characterized in that it comprises a lens (6) arranged around the LED diode (3) to protect it and diffuse the light emitted by it. 14. Device according to claim 1), characterized in that it comprises a plurality of said LED diodes (3) fixed to the same end (2a) of the handpiece (2). 15. Device according to claim 1), characterized in that it comprises a plurality of said LED diodes (3) fixed internally to the handpiece (2) and operatively associated with means for guiding the light emitted by each of said LED diodes (3) until outside the handpiece (2) itself. 16. Device according to claim 15), characterized in that said means for guiding the light emitted by the LED diode (3) are optical fibers. 17. Device according to claim 2), characterized in that the power supply unit (5) and / or the means (7) for controlling, regulating and signaling the energy supplied over time to the LED diode (3) reside in a base fixed connected to the handpiece (2). 18. Method for photopolymerizing materials for dental use, in particular resins, composite resins and / or glass-ionomer substances, characterized in that it comprises the steps of: prepare at least one light-emitting LED diode in a wavelength range between 400 and 500 nanometers; turn on the power supply unit of the LED diode; place the LED diode near the material to be polymerized, irradiating it; prolong irradiation until the material has completely hardened; turn off the power unit of the LED diode. 19. Method according to claim 18), characterized by the fact that the LED diode emits blue light in a range of wavelengths centered on about 470 nanometers. 20. Method according to claim 18), characterized in that the irradiation is prolonged for an interval of time of less than 60 seconds.