WO2012175724A2 - Endodontic instrument having at least one frontal cutting edge - Google Patents

Abstract

The invention relates to an endodontic instrument comprising, along a longitudinal axis, a sleeve and an active part for working on a root canal, which active part extends between the sleeve and a distal end opposite the sleeve, and having at least one cutting edge in the area of said active part, characterized in that it has at least one cutting edge extending to the end of a toothing situated between the sleeve and said distal end, said cutting edge being inscribed within a cutting plane orthogonal to said longitudinal axis.

Description

 Endodontic instrument having at least one cutting edge.

 The field of the invention is that of the design and manufacture of instruments for practicing dental care. More specifically, the invention relates to endodontic instruments used to make and / or work a canal in a tooth.

 When a tooth is affected by deep decay, it is sometimes necessary to devitalize the tooth. To do this, it is necessary to remove the infected tissue from the tooth and the root of the tooth, and to form a channel intended to be closed by a constituent material of Gutta or other canal filling paste.

 To perform these operations, we use endodontic instruments that are similar to small diameter drills and that allow to drill and / or cut the tooth of the tooth to shape the channel.

 These endodontic instruments are, in their design, designed to have sufficient hardness to pass through the dentin which is a medium-hard material, while having a certain degree of flexibility to be able to follow the trajectory (or curvature) of the root canal of the tooth and respect the canal anatomy as much as possible.

 To this end, it has been proposed for several years endodontic instruments made of stainless steel or alloy of nickel and titanium.

 In general, the current endodontic instruments are made from a cylindrical rod on which one or more helical cuts are cut, traditionally by a grinding process. The cutting surfaces generate at their intersection an edge.

These instruments are dedicated to one of the following types of use: rotating, continuous or alternating, combined movements (rotation / linear for example), vibration, according to the practitioner's equipment, while adapting, according to the profiles proposed, to all types of animation (motorized or manual). Currently, the edges of the endodontic instruments are linear and continuous, such a ridge then constituting a continuous and smooth cutting edge.

 These instruments are dedicated to one of the following types of use: manually or mechanically, in rotation, continuously or alternatively, combined movements (rotation / linear for example), vibration, according to the practitioner's equipment.

 Such instruments require great vigilance and precise dexterity on the part of the practitioner, for example when they are used in continuous rotation.

 Indeed, with endodontic instruments provided with a continuous and smooth classic cut, two opposite phenomena can occur:

 either the edge of the endodontic instrument slides on the dentinal material;

 either the edge of the endodontic instrument engages too quickly in the dentinal material (necrotic or not), which leads to a phenomenon referred to as the "weathering", at the end of which the instrument gets stuck in the matter.

 In both cases, the machining of the channel does not operate correctly, or even not at all.

 It should be noted that in the case where the endodontic instrument gets stuck in the material, it is frequent that this incident causes a cracking of the root and / or a breakage of the instrument. In some cases, part of the broken endodontic instrument remains stuck in the tooth, which requires a long and tedious procedure on the part of the practitioner to remove the part of the instrument in question.

In addition, the repeated failure of the instrument tends to increase the operating costs for the practitioner. Furthermore, the current endodontic instruments have a general shape such that they fit into a conical envelope, which leads therefore to obtaining a channel also conical.

 Such instruments exert a significant radial force on the root of the tooth, at the risk of cracking or breaking it.

 The invention particularly aims to overcome these disadvantages of the prior art.

 More specifically, the invention aims to provide an endodontic instrument that is more effective than those of the prior art, and which is simpler to use for the practitioner, while adapting according to the proposed profiles, to all types of animation (rotation, vibratory, motorized or manual ...).

 Another object of the invention is to provide an endodontic instrument which limits the lateral forces on the root.

 Yet another object of the invention is to provide an endodontic instrument which limits the screwing effects of the instrument in the root.

 Another object of the invention is to provide such an endodontic instrument that can be easily manufactured, without requiring an excessive number of phases or resumptions machining resulting in greatly increase its manufacturing cost.

 These objectives, as well as others which will appear later, are achieved thanks to the invention which relates to an endodontic instrument comprising, along a longitudinal axis, a handle and an active part of working a channel. root canal, said active portion extending between the handle and a distal end opposite the handle, and having at least one cutting edge on the height of said active portion, characterized in that it has at least one cutting edge s' extending at the end of a toothing located between the handle and said distal end, said cutting edge being in a cutting plane orthogonal to said longitudinal axis.

Thus, as will be explained in more detail later, the presence of one or more cutting edges in an orthogonal cutting plane to the longitudinal axis of the instrument tends to form one or more protuberances (at the level of the tooth or teeth in the active part) in correspondence in the radial direction, which give the instrument a more effective action on the material of the tooth, avoiding the instrument to slide on the dentine or get stuck in it.

 More specifically, an instrument according to the invention exerts an essentially longitudinal force on the root (in which direction it is the most resistant), and not radial (avoiding the risk of breakage of the root). In addition, an instrument according to the invention does not tend to screw into the tooth; the practitioner must push the instrument in the root, unlike the instruments of the prior art with which the practitioner must hold the instrument (which tends to screw).

 Indeed, the protuberances thus created generate a machining that is more like a "scraping" or milling, in comparison with the action of conventional endodontic instruments that are similar to a simple cut. An instrument according to the invention is therefore used more simply to the extent that it avoids, by design, the disadvantages of the instruments of the prior art. The practitioner can therefore operate the dentine machining without particular concern.

 In addition, the risk that the instrument gets stuck in the dentin being removed, it limits the phenomena of breakage of endodontic instruments.

In addition, as will subsequently appear, the edge or edges forming part of the cutting plane orthogonal to the longitudinal axis of the instrument make it possible to create a dental canal of optimized shape for positioning and holding in place a filling paste. Indeed, the presence of the edges in a plane orthogonal to the longitudinal axis of the instrument will allow to machine an annular bearing which will constitute a bearing surface against which the sealing paste is supported more reliable only with a conical channel. As will become clearer later, the annular bearing surface may be flat or not. It should also be noted that an instrument according to the invention is flexible and can therefore be adapted to the shape of the root canal. In addition, it can be used in different modes of animation (motorized, manual, continuous rotation or not, vibratory ...).

 According to a first embodiment, said cutting edge which extends in a plane orthogonal to said longitudinal axis is rectilinear.

 According to a second embodiment, said cutting edge which extends in a plane orthogonal to said longitudinal axis is curvilinear.

 In either case, said cutting edge which extends in a plane orthogonal to said longitudinal axis extends to the end of a toothing in the form of a hook.

 In the case where the hook is oriented towards the handle, the instrument allows to extract root material, for example a nerve. If the hook is oriented towards the distal end, the instrument allows, in a conventional manner, a dental canal machining. If there is a combination of hooks facing the handle and the distal end, then this configuration allows axial work back and forth to cumulate the 2 advantages and further to limit the risk of screwing by eliminating the grooves or threads as they appear in the canal wall.

 According to a preferred embodiment, the instrument comprises at least two cutting edges which each extend in a cutting plane orthogonal to said longitudinal axis, a first edge occupying a lower position with respect to the second edge over the height of the active portion, said second edge having at least one end remote from the longitudinal axis by a distance greater than that of the two ends of the first edge with respect to the longitudinal axis.

In other words, the instrument has at least two edges one above the other and intended to form bearing surfaces at two distinct stages of the dental canal, the highest stage having a surface annular support of a diameter greater than that of the lower stage. In the case of a plurality of bearing surfaces at different heights of the dental canal, the diameter of the bearing surfaces is increasing from bottom to top of the dental canal, evenly or not.

 According to an advantageous solution, said active part also has at least one second cutting edge extending between two distinct points of the height of the active part. In this case, the second cutting edge is preferably helical.

 According to a particular embodiment, the active part has, at a cutting plane orthogonal to the longitudinal axis in which the edge extending in the plane orthogonal to the longitudinal axis, a section of which the form belongs to the following group:

 - round;

 ovoid;

 triangular;

 square;

 - rectangular;

 - polygonal.

 Of course, other forms of the section in question can be envisaged without departing from the scope of the invention.

 In addition, an endodontic instrument according to the invention can be produced according to one or other of the following variants:

 the general shape of the section at each edge extending in the plane orthogonal to the longitudinal axis is constant, or,

 the general shape of said section at each edge extending in the plane orthogonal to the longitudinal axis is variable.

Thus, according to some embodiments of the invention, the shape of the section of the endodontic instrument at each edge extending in the plane orthogonal to the longitudinal axis may be different. This difference in shape can consist of a simple difference in dimensions of two sections, which are then homothetic. It can also consist of a radical difference in the general shape of the section, which may for example be triangular at one section and square at another section.

 Thus, according to one possible embodiment of the invention, the active part of the endodontic instrument may comprise a tip zone and a work zone, the work zone itself being composed of several successive segments having different sections. , which can vary almost to infinity, whose shape is not necessarily homothetic.

 Other features and advantages of the invention will emerge more clearly on reading the following description of a preferred embodiment of the invention, and the appended drawings in which:

 Figures 1 and 2 are views of a preferred embodiment of the endodontic instrument according to the invention, respectively seen in perspective and viewed from the side;

 Figures 3 and 4 are each a partial view of a dental canal made with an endodontic instrument according to the invention;

 Figures 5 to 11 are each a view of an alternative embodiment of an endodontic instrument according to the invention. As illustrated by FIGS. 1 and 2, an endodontic instrument according to the invention comprises, along a longitudinal axis X:

 a handle 1, which can constitute an assembly member for mounting the endodontic instrument on a tip of a mechanized or manual tool;

an active working part 2 of a dental canal, having at least one cutting edge, and in this case a plurality of cutting edges, distributed over the height of the active part (the term "height" being of course to consider when the endodontic instrument is presented vertically), extending from the handle and to a distal end 10 (opposite the handle).

 According to the principle of the invention, the endodontic instrument has in its active part at least one cutting edge 20 extending at the end of a toothing 200 and forming a cutting plane orthogonal to the axis longitudinal X of the instrument.

According to the present embodiment, the active part of the instrument has a plurality of cutting edges 20 in a cutting plane P _n , P _n + i. . . orthogonal to the longitudinal axis X at the intersection of two inclined surfaces 21, 22 with respect to the section plane.

 As shown in FIG. 2, each of the cutting edges 20 forming a cutting plane orthogonal to the longitudinal axis of the instrument extends at the end of a toothing 200 forming a radial protuberance which is capable of to generate, during the rotation or vibration of the instrument a "scraping" effect as already mentioned above.

 In addition, the cutting edges 20 forming a cutting plane orthogonal to the longitudinal axis of the instrument exert an action on the dentine material in a substantially longitudinal direction, this in contrast to the conventional cutting edges, shaped by helical example, which have a machining action in a radial direction on the material of the tooth when moving in a direction corresponding to the longitudinal axis of the instrument in the tooth.

In this sense, the action of the cutting edges forming part of a cutting plane orthogonal to the longitudinal axis of the instrument according to the invention is "frontal" in the dentinal material, and this during a displacement of the instrument in a direction corresponding to the longitudinal axis of the instrument. In other words, an endodontic instrument according to the invention is machined "at the end" of the toothing, this being at each of the edges forming a plane orthogonal to the longitudinal axis of the tooth. 'instrument. With reference to FIGS. 3 and 4, an endodontic instrument according to the invention leads to obtaining a root canal 3 having at least two successive sections 31, 32, of cylindrical or slightly frustoconical shape, at the intersection of which extends a bearing in the form of a bearing surface 30, annular and orthogonal to the axis X 'of the root canal. It should be noted that the bearing surface 30 can take another form. For example, it may take the form shown in dashed lines in Figure 3, this shape corresponding in this case to a toothing of the hook-shaped instrument as will be described in more detail later.

 It is understood that the axis X 'of the dental canal corresponding to the X axis of the endodontic instrument when it is moved in the dentinal material along its own longitudinal axis.

 FIG. 4 illustrates the fact that a root canal made with an endodontic instrument according to the invention may have a plurality of bearing surfaces 30 as mentioned above, the number of these bearing surfaces varying according to the number of edges cutter 20 forming a cutting plane orthogonal to the longitudinal axis of the instrument, and depending on the depth of penetration of the instrument in the dentinal material.

 Moreover, as illustrated by FIGS. 1 and 2, the cutting edges 20 forming part of a cutting plane orthogonal to the instrument at the longitudinal axis of the instrument are here rectilinear, but may, according to a Another embodiment conceivable, being curvilinear. It is also conceivable that these cutting edges extend along a broken line.

 In addition, the inclined surfaces 21, 22 at the intersection of which the cutting edges 20 extend may be flat or curved.

According to the present embodiment, the cutting edges 20 are made on the height of the active part so that the bearing surfaces 30 of the root canal obtained have a diameter increasing from the bottom of the channel to the top of the channel. This is achieved by the following: Whereas a first edge occupying a lower position with respect to a second edge on the height of the active part (the instrument being presented vertically with its handle at the top), the second edge has at least one of its ends at a distance from the axis longitudinal axis X of the upper instrument to one and / or the other of the two ends of the first edge relative to the longitudinal axis X. Indeed, each cutting edge 20 does not necessarily extend so symmetrical with respect to the longitudinal axis of the instrument X. Also, it suffices that one end of a cutting edge above another cutting edge is farther than one and / or the other. other ends of the other cutting edge so that the diameter of the bearing surface machined by the highest cutting edge is greater than the diameter of the bearing surface formed by the cutting edge placed at a lower position on the pa active.

 Furthermore, the instrument also has at least one second cutting edge extending between two distinct points of the height of the active part. According to the present embodiment, the cutting edges 20 are connected by binding cutting edges 23 (that is to say "second cutting edges" according to the expression previously used), preferably having a helical shape . According to the present embodiment, the active part has, at each cutting plane orthogonal to the longitudinal axis in which a cutting edge 20 is embedded, a section of rectangular shape. However, this section may, according to other conceivable embodiments, present a form belonging to the following group:

 - round;

 ovoid;

 - triangular;

 square;

 - polygonal.

Any other form of section may generally be envisaged, including any forms, without departing from the scope of the invention, it may however cause possible difficulties of realization. It is noted that the general shape of the section mentioned above at each edge extending in the plane orthogonal to the longitudinal axis can be constant (without necessarily leading to a homothetic ratio) or, conversely, variable ( without homothetic relationship).

 In general, the protuberances generated by the presence of the cutting edges 20 may vary in number, size, shape and be distributed in different ways on the active part of the instrument.

 According to preferred embodiments, represented in particular by FIGS. 1, 2 and 5 to 8, the protuberances 200 carrying the ridges 20 are defined over the entire width of one face of the instrument, the ridge 20 being then substantially parallel to this face of the instrument. These embodiments are distinguished from those shown in FIGS. 8 to 11, in which the protuberances 20 are defined on edges separating two of the faces of the instrument. Embodiments in which the protuberances 200 carrying the ridges 20 are defined over the entire width of a face of the instrument have the advantage of allowing the manufacture of stronger instruments with a lower risk of breakage. .

As regards the dimensions of said toothing, these can vary in section size (for example from 0.01 mm ² to 1 mm ² ) and height (for example from 0.01 mm to 1 mm).

 As regards their distribution on the active part of the instrument, the protuberances can be arranged in a dense or dispersed manner, around the entire or only part of the active part.

 An endodontic instrument according to the invention can be used in alternating or continuous rotation. It will generally be used during an axial displacement but may for specific needs be used in radial displacement. An endodontic instrument according to the invention can also be used in vibration.

Various embodiments of an endodontic instrument according to the invention are described hereinafter with reference to FIGS. 5 to 11. According to the embodiment illustrated in FIG. 5, the instrument has a plurality of cutting edges 20 each entering a cutting plane orthogonal to the longitudinal axis of the instrument, these edges being distributed over the height of the active part of the instrument. As illustrated, the cutting edges 20 in the vicinity of the distal end 10 each extend at the end of a toothing in the form of a simple radial protuberance, while, approaching the handle 1, the teeth 200 extend in a radial component and along a longitudinal component, so as to take the form of a hook, each defined in particular by a notch 201.

 According to the embodiment illustrated in FIG. 5, these hooks are oriented towards the handle 1; such an endodontic instrument makes it possible to remove root material, for example a nerve, without the disadvantage of risking the loss of barbs, as on conventional pullers. Such an instrument can participate in a finishing work during a root canal treatment, the work of the instrument, by removal of material, being performed during removal of the instrument.

 It should be noted that the hook-like teeth of an instrument according to the present embodiment tend to fold slightly radially towards the instrument in the channel, while the teeth work in a direction of withdrawal of the instrument. instrument from the channel tending to resume their original position.

 The endodontic instrument illustrated in FIG. 6 has substantially the same shape characteristics as that illustrated in FIG. 5, with the difference that the teeth 200 in the form of hooks of the instrument are oriented towards the distal end of the instrument. 'instrument.

FIG. 7 illustrates another alternative embodiment of an endodontic instrument in accordance with the invention, according to which the active part of the instrument has a plurality of cutting edges 20 each falling in a cutting plane orthogonal to the longitudinal axis of the instrument. Each of the ridges 20 extends at the end of a toothing 200, taking the form of a front cutting edge. The instrument according to the present embodiment has some teeth oriented for some to the handle 1 and for others to the distal end 10. It can thus be used effectively pushed into the channel or pulled out of the channel. The teeth 200 are defined in particular by notches or pockets 201, each taking the form of a cylindrical recess extending orthogonally to the longitudinal axis of the instrument and angularly offset about the longitudinal axis of the instrument, step by step.

 The shapes of the pockets may be different on different instruments or on the same instrument. Thus, in the embodiment shown in FIG. 7, the pockets are of semicylindrical shape, the axis of the cylinder being able to be inside or outside the pocket. Thus, according to the notches or pockets 201, the entry of the pocket, defined by the cutting edges 20, may be the widest zone of the pocket, as is the case for the pockets near the distal end. of the instrument shown. On the contrary, for other pockets 201, especially those which are closer to the reed of the instrument shown, the entrance of the pocket, defined by the cutting edges 20, may be tighter than an inner part of the poached. Those skilled in the art can easily implement pockets having narrower openings, relative to the internal dimensions of the pocket, although those shown near the handle of the instrument. It could also create such pockets that have shapes not forming part of a cylinder and may, if necessary, have an opening narrower than an internal area of the pocket.

These pockets with a very narrow entry with respect to the dimensions of the pocket (of the order of 0.1 mm thick) make it possible to avoid significant removal of material at the edges and thus to preserve most of the material. length of the cutting edges. They also generate very sharp cutting angles (for example with a cutting angle of 30 °). Such bags can be made only by the wire electroerosion method, but not by grinding, which is the traditional machining method of the prior art in this field. Moreover, the pockets represented on the instrument of FIG. 7 have the advantage of greatly increasing the flexibility of the instrument. Indeed, these pockets of relatively large size in the instrument reduce its resistance to bending, in all directions, without reducing the outer diameter of the instrument. In addition, because of the cylindrical shape of the pockets, no sharp angle is cut in the instrument, which is therefore not excessively weakened by the presence of the pockets. Thus, the pockets according to the invention, having shapes not involving the machining of sharp angle in the instrument and, in some cases, having an opening each defining two cutting edges 20 each forming a plane orthogonal section to the longitudinal axis of the instrument and turned towards the handle and the other towards the tip of the instrument, have significant advantages over the notches that are provided in some embodiments of the invention. prior art.

 It should be noted that the skilled person may choose to distribute the pockets along the instrument, so that they are in communication with each other or on the contrary that they are separated from each other. Such an instrument can be used distinctly by pushing the instrument into the tooth or pulling the instrument from the tooth. Such an instrument proves flexible in all directions in space, the recesses of rounded shape avoiding breaking primers. It provides parietal support. Such an instrument can be used in continuous rotation, alternating rotation, vibration, manually or motorized ...

 Figures 8 to 11 illustrate further alternative embodiments of an endodontic instrument according to the invention.

According to the embodiment illustrated in FIG. 8, the cutting edges 20, forming part of a cutting plane orthogonal to the longitudinal axis of the instrument, extend at the end of the teeth 200, again presenting the hooks, oriented in this case to the handle 1 of the tool. As shown in FIG. 8, the teeth 200 have a decreasing width in the direction of the edge 20. In addition, the active portion has a plurality of rectilinear connecting edges 23 according to the present embodiment.

 The embodiment illustrated in FIG. 9 substantially resumes the same characteristics as those of the instrument described with reference to FIG. 8, with cutting edges 20 extending at the end of teeth facing towards the handle and presenting a decreasing width towards the cutting edge 20. The difference with the instrument illustrated in FIG. 8 lies in the fact that the active part of the instrument illustrated in FIG. 9 comprises a plurality of connecting edges 23 having a helical shape.

 FIG. 10 illustrates an alternative embodiment of an endodontic instrument according to the invention having substantially the same characteristics as the instrument illustrated in FIG. 8, with the difference that the teeth 200 are in the form of hooks oriented this time towards the distal end of the instrument.

 It should be noted that an instrument combining the characteristics of the instrument of FIG. 8 and that of FIG. 10 is conceivable.

 FIG. 11 illustrates an alternative embodiment of an endodontic instrument according to the invention according to which the instrument reproduces substantially the same characteristics as those of the instrument illustrated in FIG. 9, with the difference that the teeth 200 are presented under the shape of hooks oriented this time towards the distal end of the instrument.

 It should be noted that an instrument combining the characteristics of the instrument of FIG. 9 and that of FIG. 12 is conceivable.

 Furthermore, it should be noted that an endodontic instrument according to the invention has, in general, the following characteristics:

the instrument works with a plurality of active zones located on the height of the active part, unlike conventional instruments that provide a linear contact, usually helical; the instrument is generally not very stressed, with a homogeneous distribution of forces on each of the teeth of the instrument;

 the instrument is flexible, to allow to follow the curve of a channel;

 the teeth of the instrument are distributed in a staged manner;

 each toothing of the instrument has a well-defined work and is solicited independently of other teeth; the torques of effort are well distributed on all the teeth of the instrument;

 the evolution of the diameter of the cutting edges is moderate; each toothing removes a thickness of material from 1 hundredth to a few hundredths of a millimeter and is therefore weakly solicited which reduces the risk of breakage. The instrument has a variable geometry with a potentially infinite variability along the active part and by means of a machining unique without the need for oversize or machining

 Advantageously, the endodontic instrument according to the invention is manufactured in a single machining, implementing a single tool. This unique machining of a tool of complex shape can be easily achieved by a wire EDM machining process. This method thus makes it possible to manufacture at a much lower cost than conventional methods of manufacturing an instrument of complex shape, requiring a first machining followed by one or more overlays or reworking.

Claims

An endodontic instrument comprising, along a longitudinal axis, a handle and an active working portion of a root canal, said active portion extending between the handle and a distal end opposite the handle, and having at least one cutting edge. cutting on the height of said active part,

characterized in that it has at least one cutting edge extending at the end of a toothing located between the handle and said distal end, said cutting edge being in a cutting plane orthogonal to said longitudinal axis.

 Endodontic instrument according to claim 1, characterized in that said cutting edge which extends in a plane orthogonal to said longitudinal axis is rectilinear.

 Endodontic instrument according to claim 1, characterized in that said cutting edge which extends in a plane orthogonal to said longitudinal axis is curvilinear.

 Endodontic instrument according to any one of claims 1 to 3, characterized in that said cutting edge which extends in a plane orthogonal to said longitudinal axis extends at the end of a toothing in the form of a hook. .

 Endodontic instrument according to claim 4, characterized in that said hook is oriented towards the handle.

 Endodontic instrument according to claim 4, characterized in that said hook is oriented towards the distal end.

Endodontic instrument according to any one of claims 1 to 6, characterized in that it comprises at least two cutting edges which each extend in a cutting plane orthogonal to said longitudinal axis, a first edge occupying a lower position relative to at the second edge on the height of the active portion, said second edge having at least one end distant from the axis longitudinal greater than that of the two ends of the first edge with respect to the longitudinal axis.

 8. Endodontic instrument according to any one of claims 1 to 7, characterized in that said active part also has at least one second cutting edge extending between two points distinct from the height of the active part.

 9. endodontic instrument according to claim 8, characterized in that the second connecting cutting edge is helical.

 10. endodontic instrument according to any one of claims 1 to 9, characterized in that the active part has, at a cutting plane orthogonal to the longitudinal axis in which is inscribed the edge extending in the plane orthogonal to the longitudinal axis, a section whose form belongs to the following group:

 - round;

 - ovoid;

 triangular;

 square;

 - rectangular;

 - polygonal.

11. endodontic instrument according to claim 10, characterized in that the general shape of said section at each edge extending in the plane orthogonal to the longitudinal axis is constant.

12. endodontic instrument according to claim 10, characterized in that the general shape of said section at each edge extending in the plane orthogonal to the longitudinal axis is variable.