ITPI20080067A1 - EQUIPMENT TO TEST THE EFFICIENCY OF DENTAL INSTRUMENTS - Google Patents

Description

Description of the industrial invention entitled "EQUIPMENT FOR TESTING THE EFFICIENCY OF DENTAL INSTRUMENTS"

DESCRIPTION

Scope of the invention

The present invention relates to the dental sector and in particular refers to an equipment for testing the efficiency of dental instruments, in particular dental instruments made of metal material such as files made of Ni-Ti alloys.

Brief notes on the known art

A wide range of instruments for endodontic, orthodontic and conservative dentistry treatments are used in dental practice.

In particular, endodontic surgery involves the removal of pulp tissue affected by inflammation or infection due to the presence of deep caries and related bacterial contamination, or following trauma. The pulp tissue is removed both at the level of the crown and at the level of the roots and replaced with a permanent filling in gutta-percha and root canal cement after adequate shaping of the root canals.

Acute or chronic inflammation can spread outside the apex of the tooth root and spread to the surrounding bone causing lesions defined as abscess, or granuloma, and visible on x-rays.

In recent years, new operating procedures have become increasingly widespread in the field of endodontics that guarantee a better result in cleaning the root canal with a much shorter intervention time than traditional techniques. The basis of the new intervention techniques is the introduction of innovative tools that guarantee their efficiency even in extremely unfavorable operating conditions.

An example of such tools, commonly called files, is shown in Figures 1 to 3.

In particular, a common file 10 comprises a working portion 15, having a shape similar to that of a small drill bit, and a portion 16 for coupling to a dental instrument 500 (Figure 2). The file 10 also comprises a stop element 18 usually a ring made of a plastic resin mounted movable longitudinally to the file 10. In particular, the stop element 18 is preliminarily arranged in a position determined by the dentist according to the tooth to be undergo endodontic surgery. Under operating conditions, the portion 15 is introduced into a channel 81 of the tooth 80 to be subjected to endodontic surgery and by rotating at high speed it expels the dental pulp as it advances inside it (Figure 3).

The files can be made of steel, or an equiatomic alloy of Nickel and Titanium.

The former have a rigidity that increases with the size of the instrument, which therefore tends to maintain its initial shape when inserted into a curved canal, exerting forces that tend to straighten the canal itself. These forces are particularly exerted at the junction between the tip and the sharp blades of the file and cause transport, aberrations and perforations of the canal, which lead to a shape of the canal section that is more difficult to obturate, to areas of the endodontum that are not instrumented and to damage to the structure of the root.

During their use the files are subjected to high fatigue and torsional stresses that can cause damage, or even fracture, of the instrument. At each turn of the rotation performed inside the curved canal, the instrument is subjected to a complete tension-compression cycle. In fact, the portion that remains externally to the curvature is subjected to tension, while the internal portion is subjected to compression. Obviously, the greater the extent of the curvature, the greater the stress and, with the same curved shape of the canal, larger and therefore more rigid instruments are subjected to higher stress. In the clinic, therefore, larger instruments should not necessarily be considered safer, especially if they engage significant coronal curvatures with the generation of considerable stress.

Also the changes of crystalline phase, linked to the variation of stress and therefore of temperature, play an important role because during the modification of the crystals the instrument is very prone to fracture. Abrupt variations in the number of revolutions during rotation break the bonds of the metal matrix, generating crack formation and propagation.

Therefore it is essential to have a motor capable of maintaining the material in its martensitic state, subjecting it to controlled stress by means of a constant rotation speed. It is also important to activate rotation before inserting the instrument into the canal and moving it axially to distribute the stress along the instrument. An extremely unfavorable condition occurs when restarting the rotation of the file after a stop occurred due to the locking of the file in the dentin.

Another variable to be considered is the torsional load applied to the tool, which depends on both the manipulation by the operator and the shape of the tool. The shape of the tool must, in fact, be such as to avoid stress concentrations at the cutting blades.

For the aforementioned reasons, files made of "nitinol", ie an alloy of Nickel (Ni) and Titanium (Ti), are commonly used for endodontic treatments. This material has a very low modulus of elasticity and therefore has marked superelasticity characteristics. Therefore, during endodontic interventions the nitinol files exert lower forces on the lateral surface of the canal than those produced by the steel files in addition to a reduced straightening action of the canal walls.

However, despite the increase in flexibility, Ni-Ti instruments also suffer from fracture. The phenomenon is essentially linked to the repeated cycles of metal fatigue to which they are subjected. In fact, it is not uncommon for the file to break during endodontic surgery, remaining trapped inside the canal of the patient's tooth with

In addition to the fracture that occurs due to torsional overload, a file still has a life limit linked to the fatigue accumulated in the different cycles and dependent on the radius and angle of curvature of the channels treated as well as on the diameter of the tool and the rotation speed. Assessing the stress immediately is easier in steel tools, which, when the plastic deformation limit has been exceeded, show a visible unwinding of the coils. This is also observable with NiTi, but the progressive fatigue of the NiTi alloy remains more easily hidden, thanks to the ability to restore the original shape.

Therefore, the decision to discard an instrument is based on the number of channels treated, on the resistance and curvature of these, on the time of use within them.

Typically, file manufacturers indicate an average number of treatments after which the tool must be replaced.

However, in the presence of channels with very tight curves it may be necessary to discard the file after only one use.

Summary of the invention

It is therefore the aim of the present invention to provide a method for testing the efficiency of a dental instrument capable of performing a non-destructive test.

It is also an aim of the present invention to provide a method for testing the efficiency of a dental instrument that is quick and easy to use.

These and other purposes are achieved by the equipment for testing the efficiency of a dental instrument, in particular a superelastic endodontic mechanical instrument, such as files, reamers, and the like, comprising:

- means for applying vibrations at a given frequency at a first point of said dental instrument, said vibrations propagating through said instrument to be analyzed,

- means for detecting said vibrations propagated through said instrument at a second point and for generating a respective propagation signal,

- means for processing said propagation signal and suitable for generating an integrity signal of said instrument.

In particular, the means for applying and / or the means for detecting may comprise a contact end adapted to be put in contact with the instrument to be analyzed.

Advantageously, the equipment also comprises a support comprising a seat for the instrument under investigation. In particular, the site and the instrument to be analyzed comprise respective mutually engageable surfaces.

In particular, the first point can be placed at one end of the instrument to be analyzed and the second point at the opposite end.

In an embodiment envisaged by the invention, the means for applying and the means for detecting are arranged on the opposite side with respect to the instrument to be analyzed.

Advantageously, the means for applying and / or the means for detecting are provided longitudinally movable to the instrument to be analyzed.

In particular, the means for applying and / or the means for detecting can be integral with the support. For example, the means for detecting can be housed inside a seat obtained in the support.

In particular, the support can comprise a first seat for the instrument to be examined and a second seat for a reference sample. In such a case, the means for processing compares the propagation signal for the dental instrument with a propagation signal relative to the reference sample.

In particular, the means for applying the vibrations can comprise an ultrasound emitter adapted to convert an electrical signal into a vibration.

Advantageously, the means for detecting vibrations can be selected from:

- an ultrasound receiver, for example a piezoelectric sensor adapted to convert the vibration into an electrical signal,

- an optical sensor.

In one embodiment provided, the receiver and the emitter can be integrated within an ultrasound transducer.

In particular, the ultrasound emitter can be chosen from:

- a piezoelectric transducer;

- a magnetostrictive transducer.

Brief description of the drawings

The invention will now be illustrated with the following description of an embodiment thereof, given by way of non-limiting example, with reference to the attached drawings in which:

- Figure 1 shows in a plan view a file of known technique for endodontic interventions that can be analyzed by means of the equipment, according to the invention, to verify the degree of efficiency;

Figure 2 shows in a front view the file of Figure 1 during an endodontic intervention of the known art;

- Figure 3 schematically shows the configuration assumed by the file within a curved canal of a tooth subjected to endodontic surgery in Figure 2; - Figures 4 to 9 schematically show some possible embodiments of the equipment, according to the invention.

Description of the preferred embodiments

With reference to Figure 4, an embodiment of an apparatus 1, according to the invention, for measuring the degree of integrity, and therefore the efficiency, of a dental instrument, in particular a dental instrument made of superelastic material such as Ni-Ti alloys , comprises means 150 for applying vibrations at a given frequency in correspondence with a point P1 of the analyzed instrument and means 250 for detecting the vibrations which arrive at a point P2, after having traveled the distance d existing between P1 and P2. The means 250 for detecting the vibrations at the point P2 may comprise an optical sensor 251 capable of detecting the oscillation produced at the free end 11 and sending a corresponding signal to a processing unit 155. This provides for processing the received signal and generating a corresponding propagation signal expressing the degree of integrity of the dental instrument 10.

The processing unit 200 can be adapted to measure the degree of efficiency of the file 10 by measuring the vibrations that pass through the file 10 without undergoing substantial changes. The analysis is therefore conducted by measuring the extent of the vibrations that are able to pass through the dental instrument 10 without suffering dispersions due to the presence of imperfections, or structural irregularities that could lead to the breakage of the instrument itself during a subsequent endodontic surgery.

Furthermore, a monitor, for example an oscilloscope, can be provided to display the position of any defects present in file 10.

The dental instrument can be, for example, a file 10 for endodontic treatments comprising a working portion 15, having a shape similar to that of a small drill bit, and a portion 16 for coupling to a dental instrument 500.

As shown in Figure 4B, the means 150 for applying the vibrations to the file 10 can comprise an ultrasound source 100 operatively connected to an ultrasound emitter 20 positioned in contact with the file 10 to be analyzed at a point P1 to apply the high vibrations. frequency, or starting echo, generated by the source 100. The means 250 for detecting the vibrations can also comprise an ultrasound receiver 25 arranged in contact with the file 10 and able to detect the vibrations, or return echoes, which reach a point P2 placed at a distance d from P1. More in detail, the emitter 20 is arranged in contact with the file 10 at the free end 11 of a working portion 15, while the receiver 25 is arranged in contact with the file 10 at the other end 12 of the working portion 15. The file 10, before being subjected to the test, can be arranged on a support 50 provided with a seat 55 having a surface that can be mutually coupled to that of the coupling portion 16 (Figure 4).

In the example of figure 5, the emitter 20 and the receiver 25 are arranged on the opposite side with respect to the file 10 to be analyzed and are provided to be movable longitudinally to it. In particular, the emitter 20 and the receiver 25 are mounted sliding on respective guides 120a and 120b substantially parallel to the file 10 to perform a scan aimed at identifying any areas of deterioration of the instrument.

In the embodiment illustrated in Figure 6, the file 10 is arranged on a support 50 able to keep it in a vertical position. The support 50 also provides a seat 55 in which the emitter 20 is housed which then transmits the vibrations at the end 16 of the file 10.

According to an embodiment illustrated in Figure 7, the ultrasound emitter and receiver can be integrated into an ultrasound transducer 300, for example of the piezoelectric type. The ultrasound transducer 300 is provided integral with a carriage 115 slidably mounted on a guide 110 substantially parallel to the file 10 to be analyzed so as to allow the transducer 300 to traverse the file 10 longitudinally for at least a portion thereof.

In further variants illustrated in Figures 8 and 9, the apparatus 1 comprises a support 50 provided with a seat 55 in correspondence with which the file 10 to be analyzed is arranged and with a second seat 55 'in correspondence with which a sample 10 is arranged ' of reference.

More in detail, in the embodiment of figure 8, the seats 55 and 55 'are shown separate and two emitters 20 and 20' are provided, arranged in contact with the file 10 and with the sample 10 ', respectively, at the free ends 11 and 11 '. The receivers 25 and 25 'are, on the other hand, provided arranged in contact with rows 10 and 10' respectively, at the ends 12 and 12 'of the work portions 15 and 15'.

Alternatively, as illustrated in Figure 9, the seats 55 and 55 'of the support 50 can be in communication and provide a portion 55' 'in correspondence with which a single emitter 20 can be arranged which transmits the vibrations to both rows 10 and 10 'at the respective portions 16 and 16'. The vibrations are then detected at the free ends 11 and 11 'of file 10 and sample 10' by respective detectors 25 and 25 '.

In both cases illustrated in Figures 8 and 9, the processing unit 200 compares the signal associated with the response echo detected in correspondence with the file 10 to be analyzed with that detected in correspondence with the reference sample 10 'and calculates a corresponding degree of relative integrity of the examined file 10 with respect to the sample model 10 '. Furthermore, the variant of Figure 9, using a single emitter 20 to apply the vibrations to both file 10 and sample 10 ', allows to avoid possible measurement errors deriving from the use of two different emitters.

The above description of a specific embodiment is capable of showing the invention from a conceptual point of view so that others, using the prior art, will be able to modify and / or adapt this specific embodiment in various applications without further research and without departing from the inventive concept, and, therefore, it is understood that such adaptations and modifications will be considered as equivalent to the exemplified embodiment. The means and materials for carrying out the various functions described may be of various nature without thereby departing from the scope of the invention. It is understood that the expressions or terminology used have a purely descriptive purpose and therefore not limitative.

Claims (10)

CLAIMS 1. Apparatus for testing the efficiency of a dental instrument, in particular a mechanical dental instrument made of superelastic material, such as a dental file, or a similar endodontic instrument, characterized in that it comprises: - means for applying vibrations at a certain frequency in correspondence to a first point of said dental instrument, said vibrations propagating through said instrument to be analyzed, - means for detecting said vibrations propagated through said instrument at a second point and able to generate a respective propagation signal, - means for processing said propagation signal and suitable for generating an integrity signal of said instrument. 2. Apparatus for testing the efficiency of a dental instrument, according to claim 1, in which said means for applying and / or said means for detecting comprise a contact end adapted to be put in contact with said instrument to be analyzed. 3. Apparatus for testing the efficiency of a dental instrument, according to claim 1, in which a support is also provided comprising a seat for said instrument, said seat and said instrument to be analyzed comprising respective mutually engageable surfaces. 4. Apparatus for testing the efficiency of a dental instrument, according to claim 1, in which said first point is arranged at one end of said instrument to be analyzed and said second point is arranged at the opposite end. 5. Apparatus for testing the efficiency of a dental instrument, according to claim 1, in which said means for applying and said means for detecting are arranged on the opposite side with respect to said instrument. 6. Apparatus for testing the efficiency of a dental instrument, according to claim 1, in which said means for applying and / or said means for detecting are provided movable longitudinally to said instrument to be analyzed. 7. Apparatus for testing the efficiency of a dental instrument, according to claim 1, in which said means for applying and / or said means for detecting are integral with said support. 8. Apparatus for testing the efficiency of a dental instrument, according to claim 1, wherein, said support comprises a first seat for said instrument to be analyzed and a second seat for a reference sample, said means for processing by comparing said propagation relative to said dental instrument with a propagation signal relative to said reference sample. 9. Equipment for testing the efficiency of a dental instrument, according to claim 1, in which: - said means for applying the vibrations comprise an ultrasound emitter; And - said means for detecting vibrations are selected from: - an ultrasound receiver; - an optical sensor. 10. Apparatus for testing the efficiency of a dental instrument, according to claim 9, in which said emitter and said receiver are integrated in an ultrasound transducer, said ultrasound transducer being selected from: - a piezoelectric transducer; - a magnetostrictive transducer.