IT202100007388A1 - SYSTEM FOR EVALUATING A PLACEMENT OF A DENTAL IMPLANT. - Google Patents

Description

DESCRIPTION

Attached to a patent application for INDUSTRIAL INVENTION having the title

System for evaluating the placement of a dental implant.

The present invention relates to a system for evaluating the positioning of a dental implant.

In the field of dental implants, the activities which are carried out are essentially the drilling of the bone crest necessary to create an artificial surgical alveolus aimed at accommodating the implant that will be? screwed inside.

? important, during the activities? above, carefully evaluate where the hole is made and the correct size of the implant, as from what? the correct assembly and positioning of the system itself depends. In particular, this evaluation phase, ? necessary to allow that the? implant is positioned centrally, with respect to the space between two teeth and above all, to determine the correct dimensions of? implant that can? be placed in the available space. ? in fact, it is important to note that, how much more? a plant has large dimensions, the more? this will be resistant and strong. Therefore, ? It is important to plan a plant with the maximum possible dimensions in line with the available space.

Furthermore, this evaluation of the space, ? necessary even if they are positioned more? systems, one next to the other. There? in fact, it allows you to avoid that, for example, the last system is too large to fit into the remaining space.

In the field, other systems are known which allow these functions to be performed. In particular, ? known the use of resin guides, guided surgery or annoying measurements of edentulous surgical sites on radiographs.

Such systems are complex, time consuming and impractical.

Purpose of the present invention ? making available a system for evaluating a positioning and a method which overcome the drawbacks of the prior art mentioned above.

Said purpose ? fully achieved by the system and method of the present invention , which is characterized by what is contained in the claims set out below.

According to one aspect of the present description, the present invention provides a system for evaluating the positioning of a dental implant.

The system comprises a milling tool, elongated along a respective longitudinal axis between one end? of milling, configured to mill a bone seat, and an extremity? coupling device, configured to be connected to a rotary motor, to rotate the milling tool.

Does the system include a probe, elongated along a respective longitudinal axis between one end? graft, configured to be inserted inside a cavity? made with the? milling tool, and one end? of grip.

Advantageously, the gripping tool comprises a respective plate, extending along a plane perpendicular to the corresponding longitudinal axis. The plate of the gripping tool? disposed, along the? longitudinal axis, between the? extremity? of milling and the? Extremity? of hooking.

Furthermore, in one embodiment, the probe comprises a respective plate, extending along a plane perpendicular to the corresponding longitudinal axis. The plate of the probe? disposed, along the? longitudinal axis, between the? extremity? of graft and the? extremity? of grip.

The presence of the plate on the milling tool and on the plate allows for a rapid and immediate spatial evaluation. In fact, the milling plate makes it possible to determine, during the milling of the bone seat, to evaluate the size of the dental implant, which has dimensions equal to those of the plate. Furthermore, once the probe has been positioned in the hole made with the milling tool, it is It is possible to always have a confirmation of the overall dimensions of the implant that can be positioned in said hole, managing to make a further hole with the milling tool correctly spaced from the previous one. Indeed, the plate of the probe and the plate of the milling tool simulate the space occupied by each dental implant. It should be noted that, preferably, the two plates, of the probe and of the milling tool must be spaced, in use, by at least 2mm. In one embodiment, the end? milling diameter has a maximum diameter between 0.8 mm and 2.0 mm. In other words, the milling tool allows you to make holes with a diameter between 0.8 mm and 2 mm. Preferably, the maximum diameter of the end? of milling ? of 1.2mm.

This feature? very important for the flexibility? of the system. In fact, these values are an excellent compromise between the following needs: have a hole of reduced dimensions which, in the event of an error, allows the center of the hole to be changed elsewhere by incorporating the previous hole; have an end large enough not to break during milling operations.

Note that the hole made with the milling tool is not ? the hole on which the?implant must be inserted, but it constitutes a first attempt, the cio? a hole test that will have to? be verified with the probe, through its plate, which will have? the same diameter as selected plant, (as said hole is wider.) therefore, keeping the hole under certain dimensions, ? It is possible to incorporate the hole, in the event of an error, in the hole which is subsequently enlarged, simply by moving the center of the hole elsewhere with respect to the first attempt made with the milling tool. therefore, you get a flexibility? high and a possibility to correct errors in a very simple and minimally invasive way without significantly altering the anatomy of the surgical site.

In one embodiment, the system comprises an additional probe, forming a plurality of probes. of probes, each elongated along the respective longitudinal axis between the respective extremity? of graft and the extremity? of grip. Each probe comprises a corresponding plate.

In one embodiment, the plates of said plurality? of probes have different diameters.

There? allows the user to evaluate different dimensions of the system (by applying the different probes equipped with plates of different diameters), until determining the maximum usable dimension.

In one embodiment, for each size of the plates, more? of a probe. In this way, you can place more? of a probe of the same size l?one close to?the other to evaluate the positioning of pi? of a plant.

In one embodiment, the system comprises an additional milling tool, forming a plurality of milling tools. of milling tools, each elongated along the respective longitudinal axis between the respective extremity? of milling and the extremity? coupling and including a corresponding plate.

In one embodiment, the plates of said plurality? of milling tools have different diameters.

There? allows the user to evaluate different implant dimensions during drilling, until determining the maximum usable dimension.

Preferably, the clay pigeons of said plurality? of probes and/or the plates of said plurality? of milling tools have a diameter value that can be selected from the following values: 2.7 mm; 3.3mm; 3.8mm; 4.2mm.

Preferably, in which each plate ? colored with a pre-established color, which ? directly related to the diameter of the plate itself. There? it considerably facilitates the rapid identification and evaluation of the necessary implant and also avoids errors regarding the diameters selected in the phase of evaluation of the implant.

In one embodiment, the milling tool comprises, at the end of milling, a point (converging) lanceolate.

In this way, the aggression? of the tip allows rapid drilling of the bone site and maximum stability? avoiding dangerous slips along the oblique bone crests.

In one embodiment, the milling tool pan is? spaced a safe distance from? milling along the longitudinal axis. Said safety distance? less than 10 mm.

The optimal safety distance? preferably equal to 6 mm.

This feature allows you to avoid drilling too deep, as the plate finds (it compulsorily stops on) the bone crest after a maximum drilling of 6 mm.

Does the probe include a coupling portion, which can be housed inside the cavity? made with the milling tool. The graft portion? disposed, along the? longitudinal axis, between the? extremity? coupling and the plate. Preferably, the coupling portion has a conical shape, converging in a direction oriented from the plate towards the end? of graft.

The conical shape of the coupling portion allows the probe to be wedged into the hole made, providing the probe with greater stability.

According to one aspect of the present description, the present invention provides a method for evaluating the positioning of a dental implant.

The method comprises a step for preparing a milling tool, elongated along a respective longitudinal axis between one end? milling and one end? coupling, configured to be connected to a rotary engine.

The method comprises a step for preparing a probe, elongated along a respective longitudinal axis between one end? of graft and one extremity? of grip.

The method includes a phase of milling of a bone seat and creation of a cavity using the milling tool.

Does the method include a phase of positioning the probe inside the cavity? milled.

The method comprises a spatial evaluation step, in which, in the milling step, the milling tool comprises a respective plate, having an extension that simulates a size of a dental implant, to evaluate the size of the dental implant, to be mounted .

In the probe positioning step, the probe comprises a respective plate, having an extension which simulates the size of a dental implant, to evaluate the size of the dental implant to be mounted.

The method includes a drilling step in a position of the bone crest adjacent to the probe, which is inserted in a hole previously made with the milling tool.

This and other characteristics will become more evident from the following description of a preferred embodiment, illustrated purely by way of non-limiting example in the attached drawings, in which:

figure 1 schematically illustrates a milling tool of a system according to the present invention;

- figure 2 schematically illustrates a probe of a system according to the present invention;

- figure 3 schematically illustrates an application of the system according to the present invention on a bone crest.

With reference to the attached figures, yes? indicated with 100 a system for evaluating the positioning of dental implants. The 100 system can? also be defined as a control and spatial evaluation kit for the placement of a dental implant.

System 110 comprises a milling tool 1.

The milling tool 1 ? stretched along a respective longitudinal axis A1 between one extremity? milling 1A and one end? hook 1B.

The end? of milling 1A comprises a tip 11. The tip 11 comprises a plurality? of faces 111, converging in one end? of the tip 11. Preferably, said faces 111 are three and are angularly out of phase with each other by 60 degrees.

Preferably, at least a 111 face? inclined with respect to the longitudinal axis A1 by an operating angle AO, between 10 degrees and 20 degrees, preferably 12 degrees.

Preferably, the remaining faces are inclined by an angle greater than the operating angle AO, with respect to the longitudinal axis A1. In other embodiments, the remaining faces are also inclined with respect to the axis A1 by an angle between 10 degrees and 20 degrees.

The end? of milling 1A comprises a rectilinear portion 112, connected to the tip 111 by the part facing the end? hook 1B.

The working tool 1 comprises a respective plate P1. The P1 plate? disposed along the longitudinal axis A1, between the extremity? of milling 1A and the? Extremity? hook 1B. In particular, the plate P1 ? connected to the straight portion 112, on the opposite side with respect to the tip 111.

In one embodiment, the tip 111 and the straight portion 112 have an overall longitudinal extension equal to a safety distance DS. The P1 plate? distant from? extremity? of the tip 111 by a value equal to the safety distance DS. Preferably, the safe distance? equal to 6 mm.

The end? of coupling 1B ? configured to be connected (for example through a transmission system) to a rotary motor, to set the milling tool 1 in rotation around the longitudinal axis A1. The milling tool 1 ? configured to drill a FP trial hole on the CO crest bone.

The rectilinear portion 112 of the milling tool 1, which penetrates inside the bone crest CO, has a diameter D1 between 8 mm and 25 mm. However, the main advantages are obtained with diameters between 10 mm and 15 mm. Finally, the preferable solution? the one with a diameter equal to 12 mm.

The plate P1 of the milling tool 1 extends along a plane perpendicular to the longitudinal axis A1. Preferably, the plate P1 has a circumferential shape but, in other foreseeable embodiments, this shape can be square, prismatic.

Plate P1 has a diameter D21 equal to one of the following values: 2.7 mm; 3.3mm; 3.8mm; 4.2mm. These values are entered as an example as the diameter of the plate can? be chosen on the basis of the transversal extension (i.e. along the bone crest) of the implant to be mounted. There? allows you to simulate the size of the dental implant and therefore, to quickly verify its correct positioning. The system 100 comprises a probe 2. The probe 2 extends along a respective longitudinal axis A2 between one end? of graft 2A and one extremity? of grip 2B. The end? of grip 2B ? configured to be hooked by a user, for example through his hands or by means of a positioning clamp.

The end? of graft 2A ? configured to be inserted (or wedged) inside the test hole FP made on the bone crest CO by the milling tool 1.

The end? coupling 2A of the probe 2 comprises a tip 211 and a coupling portion 212. Furthermore, the probe 2 comprises a respective plate P2, interposed, along the longitudinal axis A2, between the end? of graft 2A and the? extremity? of grip 2B.

The graft portion 212 ? interposed, along the longitudinal axis A2, between the tip 211 and the plate P2.

The graft portion 212 ? preferably conical in the direction facing the tip 211. The coupling portion 212 has a maximum diameter a greater than the diameter D1 of the straight portion 112 of the milling tool 1, preferably ? greater than a value between 0.5 and 3 tenths of a millimetre.

There? allows it to wedge perfectly into the FP test hole.

The plate P2 of the probe 2 extends along a plane perpendicular to the longitudinal axis A2. Preferably, the plate P2 has a circumferential shape but, in other foreseeable embodiments, this shape can be square, prismatic.

Plate P2 has a diameter D22 equal to one of the following values: 2.7 mm; 3.3mm; 3.8mm; 4.2mm. These values are entered as an example as the diameter of the plate P2 can? be chosen on the basis of the transversal extension (i.e. along the bone crest) of the implant to be mounted. There? allows you to simulate the size of the dental implant and therefore to quickly check its correct positioning even during the drilling phases of further FP test holes adjacent to the previously drilled test holes. In this way, by positioning different probes 2, with plates of specific dimensions, ? is it possible to simulate the placement of a plurality? of implants along a very transversely extended CO bone crest.

According to one aspect of the present disclosure, the present invention provides a method for evaluating the placement of a dental implant. In the following will come? described an exemplary form of this method, investigating two specific situations, the situation in which ? Is there a single implant between two teeth (or between two implants already installed or between a tooth and an implant already installed) and the situation in which it is present? It is necessary to place several implants in a very extensive CO bone crest placed between two teeth.

The method provides for the gingiva to be uncovered, in order to have access to the bone crest.

The method provides for a milling step using the milling tool 1. In particular, the doctor selects from the milling tools 1 each one having a specific diameter of the plate P1 and starts making the test hole FP on the bone crest CO. There? it allows him, right from the moment of drilling, to evaluate the space available for positioning the implant.

Once the hole test FP ? been performed, the probe 2 is selected having the plate P2 with the same diameter as the plate P1 of the milling tool 1 used. Probe 2 what? selected, it is then inserted into the FP test hole, to allow the doctor to correctly evaluate the space and to finalize the choice of the type and size of the implant. Indeed, in this phase, ? It is also possible to vary probe 2, by introducing a probe with a different diameter from that of the drill tool used, to better establish which is the optimal size of the implant. In this phase of inserting the probe 2 ? It is also possible to perform an evaluation of the positioning of the FP test hole. In other words, once probe 2 has been inserted, the doctor can visually evaluate at least one of the following aspects:

- SS safety spacing, i.e. the distance of the plate P2 from the teeth adjacent to it, on both sides. Preferably, the SS safety spacing should be at least 2mm and/or no more than 3mm;

- centering of the FP test hole with respect to the space between the two adjacent teeth. In other words, the doctor visually evaluates that the safety spacing on a first side of the plate P2 is substantially the same obtained on the opposite side.

Note that, in one embodiment, the step of evaluating clearance spacing and centering can be performed through additional diagnostic means, such as an X-ray plate. In this case, following the plate, the doctor can? quickly determine whether the placement conditions are met.

Note that the diagnosis via X-rays ? aimed, in particular, at identifying the drilling direction DP of the test hole FP, to verify that the latter is substantially perpendicular to the bone crest. There? avoid the possibility to have a correct center of the trial FP hole but an inclination of the trial FP hole which would determine a corresponding inclination of the implant, which would be too close to the adjacent tooth or adjacent implant.

At this point, if the clinician detects incorrect placement of the FP Trial hole, ? possible, without invasive interventions, to correct the FP test hole. Such a possibility? ? provided by the fact that the diameter of the hole test FP ? very limited compared to the hole d?plant FI, in which will? inserted the dental implant. Therefore, ? Is it possible for the doctor to perform an additional FP test hole?, decentralized with respect to the previous one but whose extension is ? however included in the diameter of the implant hole FI. There? ? allowed precisely by the limited diameter of the test hole FP. In fact, if the hole was too big, it would not be possible to correct the error cos? nimbly.

Once the hole test FP ? been verified and what ? Once the size of the implant to be installed has been defined, based on the diameter of the P2 plate of the probe used, the FP test hole is enlarged using an enlargement milling tip, which brings the FP test hole to the diameter necessary to install the implant .

In some embodiments of the method, where ? It is necessary to install several implants adjacent to each other, the doctor can? making a first test hole FP1, on which it positions a first probe 2?, and a second test hole FP2, adjacent to the first probe 2?. There? can? be reproduced an indefinite number of times, until reaching the last test hole, adjacent to the patient's tooth.

In this way, the doctor can determine primarily the set of implants that will be installed on the entire bone crest CO, already? aware of their dimensions and, therefore, certain that there will be no problems in positioning.

All the trial holes are then enlarged with the enlargement milling tip, and the corresponding implant chosen in the positioning evaluation phase is inserted into each hole.

Claims (10)

A system (100) for evaluating a placement of a dental implant, comprising: - a milling tool (1), extended along a respective longitudinal axis (A1) between one end? of milling (1A), configured to mill a bone crest (CO), and an extremity? coupling (1B), configured to be connected to a rotary motor, to rotate the milling tool (1); - a probe (2), elongated along a respective longitudinal axis (A2) between one end? graft (A2), configured to be inserted inside a cavity? (FP) made with the milling tool (1), and one end? gripping (2B), the system (100) being characterized in that the gripping tool (1) comprises a respective plate (P1), extending along a plane perpendicular to the corresponding longitudinal axis (A1) and arranged, along the longitudinal axis (A1), between the? extremity? of milling (1A) and the? Extremity? coupling (1B), and in which the probe (2) comprises a respective plate (P2), extending along a plane perpendicular to the corresponding longitudinal axis (A2) and arranged, along the longitudinal axis (A2), between the end ? of graft (2A) and the? extremity? grip (2B). 2. System (100) according to claim 1, wherein the end? drill bit (1A) has a maximum diameter (D1) between 0.8 mm and 2.4 mm. 3. System (100) according to claim 2, wherein the maximum diameter (D1) of the end? milling (1A) ? of 1.2 mm. 4. System (100) according to any one of the preceding claims, comprising an additional probe, forming a plurality of of probes (2), each elongated along the respective longitudinal axis (A2) between the respective extremity? of graft (2A) and the extremity? gripper (2B) and including a corresponding plate (P2), the plates (P2) of said plurality? of probes (2) having different diameters, and in which the system (100) comprises an additional milling tool, to form a plurality? of milling tools (1), each elongated along the respective longitudinal axis (A1) between the respective extremity? milling (1A) and the extremity? coupling (1B) and including a corresponding plate (P1), the plates (P1) of said plurality? of milling tools (1) having different diameters. 5. System (100) according to claim 4, wherein the plates (P2) of said plurality? of probes (2) and/or plates (P1) of said plurality? of milling tools (1) have a diameter value (D21, D22) which can be selected from the following values: 2.7 mm; 3.3mm; 3.8mm; 4.2mm. 6. System (100) according to claim 4 or 5, wherein each plate (P1, P2) ? colored with a pre-established color, which ? directly correlated to the diameter (D21, D22) of the plate itself. 7. System (100) according to any one of the preceding claims, wherein the milling tool (1) comprises, at the end? milling cutter (1A), a converging tip (111). 8. System (100) according to any one of the preceding claims, wherein the plate (P1) of the milling tool (1) is? distanced of a safety distance (DS) from? Extremity? of milling (1A), along the longitudinal axis (A1), in order to avoid a too deep milling, and in which said safety distance (DS) ? less than 10 mm. 9. System (100) according to any one of the preceding claims, wherein the probe (2) comprises a coupling portion (212), which can be housed inside the cavity? (FP) made with the milling tool (1) and arranged, along the longitudinal axis (A2), between the extremity coupling (2A) and the plate (2B), and in which the coupling portion (212) has a conical shape, converging in a direction oriented from the plate (P2) towards the end? coupling (2A). 10. Method for evaluating a dental implant placement, comprising the following steps: - arrangement of a milling tool (1), extended along a respective longitudinal axis (A1) between one end? milling (1A) and one end? coupling (1B), configured to be connected to a rotary motor; - arrangement of a probe (2), elongated along a respective longitudinal axis (A2) between one end? of graft (2A) and one extremity? gripping (2B), - milling of a bone crest (CO) and creation of a cavity? (FP) using the milling tool (1); - positioning of the probe (2) inside the cavity? milled (FP), characterized in that it comprises a spatial evaluation phase, in which, in the milling phase, the milling tool (1) comprises a respective plate (P1), having an extension on a plane perpendicular to the corresponding longitudinal axis (A1) which simulates a dimension of a dental implant, to evaluate the size of the dental implant, and in which in the phase of positioning the probe (2), the probe comprises a respective plate (P2), having an extension along a plane perpendicular to the corresponding longitudinal axis (A2) which simulates a dimension of a dental implant, to evaluate the size of the dental implant.