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  • 专利说明
  • 权利要求
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    • 专利摘要:
    An orthodontic appliance comprising a one-piece shape memory ribbon whose cross section is variable as a function of the longitudinal position of said transverse section, and comprising a bonding zone shaped to have a shape substantially identical to that of a tooth.
    公开号:FR3051352A1
    申请号:FR1654422
    申请日:2016-05-18
    公开日:2017-11-24
    发明作者:Dan Benarouch;Delphine Majbruch
    申请人:D and D;
    IPC主号:
    专利说明:

    SHAPE MEMORY TAPE
    TECHNICAL FIELD The invention relates to an orthodontic appliance with shape memory, active or passive, and a method for designing such an appliance.
    State of the art
    A passive orthodontic appliance or "attéle de contention" is a device for holding a patient's teeth in position, typically after active orthodontic treatment.
    An active orthodontic appliance is an apparatus for moving teeth in malposition of a patient. The most common orthodontic appliance, called "multi-fasteners", consists of "brackets" glued to the teeth and into which an arc is inserted. The action of multi-fastening active orthodontic appliances results in a set of forces exerted on the teeth, through the arches, which cause their movement and alignment.
    In general, the alignment is obtained by the action of a sequence of arcs that have specific roles: - nickel / titanium alloy arcs: - round section: alignment thanks to a succession of arches of increasing cross section and leveling the teeth of the same arch; - rectangular section: correction of the long axis of the teeth (or torque); - Rectangular steel arches: correction of torque and inter-arch shifts by the action of intermaxillary elastics; - TMA alloy rectangular section arches (titanium and molybdenum alloy): finishing movements in all directions of space.
    Shape memory materials are widely used in orthodontics. These materials are particularly described in the report "Shape memory alloys" - CARMA (CENTER FOR REGIONAL ANIMATION IN ADVANCED MATERIALS) - Update December 2001, or in the document titled "Nickel-Titanium alloys (NiTi)" by L JORDAN, P. ROCHER, of the Francophone Society of Dental Biomaterials (2009-2010). There is also an AFNOR Standard: "Shape Memory Alloys: Vocabulary and Measurements" (classification index: A 51-080.), April 1991.
    Steel alloys offer arc stiffness that allows the use of intermaxillary elastics without parasitic effects.
    TMA alloys allow the orthodontist to finish folds with lower forces than with steel, which is better tolerated by patients. The quasi-standardized use of this sequence of arcs has the following drawbacks: the first round-section arches do not allow alignment in all directions of the space, in particular for torque corrections, which lengthens the duration overall treatment; many appointments at the orthodontist are necessary, especially to change the arches. On this occasion, pain is often felt by patients because a sequence of arcs can generate discontinuous forces; - risk of brackets being detached or arching exposing the patient's cheeks to lesions; - repetitive act, very routine for orthodontists; - need to make time-consuming finishing plies.
    There is therefore a need for an orthodontic appliance that does not have these disadvantages.
    An object of the invention is to respond, at least partially, to this need. SUMMARY OF THE INVENTION The invention provides an orthodontic appliance comprising a monobloc shape memory ribbon, whose cross section is variable as a function of the longitudinal position of said cross section, and comprising a bonding zone shaped so as to have a shape substantially identical to that of a tooth.
    As will be seen in more detail in the following description, the modification of the cross section along the ribbon advantageously makes it possible to apply forces in several directions of space from the beginning of the treatment. These forces can be adapted according to the size of the roots of the teeth to be moved. As a result, it is possible to shorten the duration of treatments and limit the number of appointments to the orthodontist.
    In addition, the shape of the bonding zone allows the shape memory ribbon to be "directly" attached to the teeth. The orthodontic treatment is advantageously simplified.
    Finally, the treatment can be more precise, which limits the pain and phenomena of hyalinization in the patient.
    An orthodontic appliance according to the invention may also have one or more of the following optional and preferred characteristics: the contour of the transverse section and / or the angular position of the cross section around the main direction the cross section is (are) variable (s) depending on the longitudinal position of said cross section; the nature of the material (s) defining the cross-section and / or the arrangement of the materials defining the cross-section is (are) variable as a function of the longitudinal position of said cross-section; the cross section comprises first and second zones defined by the same material, the properties of the material defining the first zone being different from those of the material defining the second zone; - The said different properties result from a different heat treatment depending on the area considered; the cross-sectional area and / or the composition of the cross-section defining material (s) and / or the mechanical properties of the cross-section defining material (s) is (are) variable as a function of the longitudinal position of the cross-section; said cross section; the variation of the cross-section along the main direction X is progressive over more than 1%, preferably more than 5%, of the length of the shape-memory ribbon; the variation of the cross-section comprises a thinning; at least two sections of the shape-memory ribbon, each representing more than 5% of the length of the shape-memory ribbon, have different cross-sections from those of the adjacent section (s); the shape memory ribbon comprises at least one region made of a material chosen from the group formed by NiTi, CuAlZn and CuNiAl nickel-titanium alloys, and steels; the orthodontic appliance comprises attachment sections and inter-linked sections, said attachment sections and inter-attachment sections succeeding one another along the main direction of the shape-memory strip and being made of a NiTi alloy or steel; the orthodontic appliance comprises attachment sections made of a material without shape memory and inter-attachment sections made of a shape memory material, said attachment sections and inter-attachment sections succeeding one another along the main direction; shape memory tape; - The orthodontic appliance further comprises a reinforcement, preferably steel, and the shape memory ribbon has a groove in which the reinforcement can be housed to stabilize the shape of said shape memory ribbon. The invention also relates to a method of manufacturing a ribbon of an orthodontic appliance according to the invention, said method comprising the following steps: a) determining an orthodontic treatment adapted to the treatment of the teeth of a patient; b) determining a set of forces to be exerted locally on said teeth to obtain said orthodontic treatment and the shape of the surface of the teeth on which gluing areas of said shape memory ribbon are to be glued; c) manufacturing said shape memory ribbon, the local cross section of said memory ribbon being determined according to said forces and so as to define gluing areas substantially identical to the surfaces of said teeth on which they must be glued.
    A method according to the invention thus makes it possible to manufacture an orthodontic appliance whose shape and action are individualized.
    In one embodiment, in step c), one or more regions of the shape memory ribbon are thermally treated to locally reduce the forces exerted on the teeth in the operating position.
    Preferably, in step c), the intensity (duration and / or temperature) of the heat treatment of a region of the shape memory ribbon depends on the distance of the teeth in the vicinity of said region, in the service position , with respect to the incisors of said patient.
    BRIEF DESCRIPTION OF THE FIGURES Other features and advantages of the invention will become apparent on reading the detailed description which follows and on examining the appended drawing in which: FIGS. 1, 3 and 5 (5a-5c) each represent a general view of an orthodontic appliance according to the invention, in its service position (position in which the orthodontic appliance exerts its action on the teeth); FIG. 2a shows an exemplary main direction X of an orthodontic appliance according to the invention and three planes PI, P2 and P3 in which a shape memory tape of an orthodontic appliance according to the invention has been sectioned for the Figures 2b to 2j; FIGS. 2b-2j and 4 illustrate some examples of variations of the cross section of a shape memory ribbon along the main direction X; FIG. 6 is a schematic representation of an example of a shape memory ribbon according to FIG. invention, comprising a longitudinal reinforcement; - Figure 7 (7a and 7b) illustrates the operation of an orthodontic appliance according to the invention.
    In each of FIGS. 2b-2j, the left-hand shape represents the section in the transverse plane P1 of FIG. 2a, the central shape represents the cross section in the plane P2 and the right-hand shape represents the section in the plane P3.
    These forms are provided for illustrative purposes. In practice, the angles and ridges are preferably rounded to improve comfort.
    In the various figures, identical or similar members are identified by identical references. Definitions
    A "mban" is a piece whose length is more than 3 times, preferably more than 5 times greater than the greatest width and / or the greatest thickness. The ratio between the greatest width and the greatest thickness is not limited.
    The "length" is measured in the main direction X, preferably curved, of the shape memory ribbon.
    A "cross section" is a section in a plane perpendicular to the main direction X.
    A "section" of the shape memory ribbon is a segment of this ribbon delimited by two cross sections.
    The term "cross sectional profile" is a graphic representation of the cross sections of a shape memory ribbon along the main direction X, as shown in FIGS. 2, 3b or 4.
    The verb "to behave" must be interpreted broadly, not exclusively
    "Orthodontist" means any professional involved in orthodontic treatment. The manufacturer of the orthodontic appliance is included, even if he does not have a degree in orthodontics.
    detailed description
    Orthodontic appliance
    FIG. 1 represents a first example of an orthodontic appliance according to the invention consisting of a shape memory ribbon. The orthodontic appliance is monobloc, that is to say that it comprises only one piece, namely the shape memory ribbon.
    The shape memory ribbon extends in a main direction, or "axis" X, shown in broken lines, preferably substantially in a general plane P (plane of the sheet in Figure 1). The shape memory ribbon is preferably shaped so that, in the service position, the general plane P is substantially parallel to the occlusion plane.
    It is shown in a service position in which it exerts an action to move teeth Di (i = 1..7) (referenced hereinafter, generically, by "D") relative to each other.
    Preferably, as shown in FIGS. 5a to 5c, at least one, preferably each of the ends 10a and 10b of the shape memory ribbon have rounded shapes, preferably devoid of sharp edges. In case of detachment, the risk of injury to the patient is limited.
    Along the main direction X, fastening sections 11 and interattached sections or "bridges" 14 succeed one another.
    An attachment section 11 is a section of the shape memory ribbon which has a bonding zone 12 for fixing the shape memory ribbon on the teeth. Along the main direction X, an attachment section 11 is delimited by the boundaries of the bonding zone 12 (FIG. 6).
    Each bonding zone 12 is fixed, preferably rigidly, "directly" to a tooth D, that is to say without the intermediary of fasteners, preferably on the underside of the teeth, that is to say without say on the lingual surface of the teeth, which advantageously makes the shape memory ribbon invisible.
    The shape memory tape can also be glued to the buccal surface of the teeth, especially when the clinical situation indicates it.
    The bonding may be in particular carried out by means of a bonding composite commonly used in orthodontics, for example the Transbond XT (3M), the FUJI ORTHO LC, or the chemopolymerizable RELIANCE.
    In a preferred embodiment, all the bonding areas are shaped to have a shape substantially identical to that of the teeth D on which they are intended to be fixed. The determination of this shape can result from a three-dimensional scan of the patient's teeth or from measurements made on a plaster model of the patient's teeth, obtained by means of a fingerprint.
    The bonding areas preferably have a surface condition improving the bonding. In particular, a bonding zone may have a textured surface, in particular a sanded or knurled surface, for example in the form of a grid. The textures conventionally applied to the bonding surfaces of the fasteners of conventional orthodontic appliances can be applied to a bonding area to increase the bonding area.
    Preferably, at least a portion of the bonding areas 12, preferably each of the bonding areas 12 has an area greater than 1 mm 2, preferably greater than 2 mm 2, preferably greater than 5 mm 2.
    A bridge 14 is a part of the orthodontic appliance that is not glued, directly or indirectly, to a tooth. A bridge 14 may extend between two adjacent teeth or not.
    At least a portion of the shape memory ribbon is of a shape memory material.
    In particular, the shape memory material may be selected from the group consisting of materials having properties of superelasticity, simple shape memory and / or double direction.
    The shape-memory material may in particular be chosen from the group formed by nickel-titanium alloys NiTi, CuAlZn and CuNiAl, preferably from NiTi alloys.
    The shape memory material may also be a biocompatible polymer.
    Nickel-titanium alloys are preferred materials.
    In one embodiment, the shape memory ribbon comprises one or more reinforcements 22 and / or hooks, preferably made of steel, allowing the attachment of intermaxillary elastics.
    The purpose of the presence of a reinforcement is to avoid parasitic deformation of the shape-memory ribbon when using accessories that generate a force greater than the elastic range of certain sections of the ribbon, especially when using the ribbon. inter-maxillary elastics.
    A reinforcement 22 is preferably arranged in front of a bonding zone, on the side of the ribbon opposite to said bonding zone, preferably in a concavity formed in the ribbon, for example a groove 24.
    In one embodiment, a reinforcement extends along the shape memory ribbon over a length greater than 1 cm, greater than 2 cm, or greater than 5 cm.
    The reinforcement can take the form of a wire, in particular the shape of an arc.
    The reinforcement can be embedded within the shape memory ribbon. In one embodiment, it is disposed in a longitudinal groove (that is to say substantially parallel to the main direction X), preferably formed on the extrados face of the shape memory ribbon, that is to say, say on the face of the shape memory ribbon which, in the service position, is oriented towards the inside of the mouth.
    In a preferred embodiment, the reinforcement is disposed in the longitudinal groove only after the teeth have been repositioned, ie after the shape memory ribbon has ceased to be active and has a stable shape. The longitudinal groove thus serves as a housing for a reinforcement, preferably made of steel, for transforming the shape memory ribbon into a passive orthodontic appliance. Advantageously, the same apparatus can therefore be successively active and then passive. Conversely, a passive device can be activated by removing a reinforcement.
    The hooks are arranged at locations specific to the treatment envisaged.
    Hooks may in particular be arranged on a reinforcement and / or in an attachment section.
    In a preferred embodiment, the shape memory ribbon is entirely in a shape memory material, for example NiTi, possibly with the exception of said reinforcements and said hooks.
    Preferably, the shape memory ribbon is shaped to withstand the spurious effects of intermaxilary traction elastics. Preferably, it has for this purpose local overthicknesses and / or reinforcements. Preferably, it also comprises hooks for hanging such elastics.
    In one embodiment, the shape memory ribbon has a variable cross section over at least a portion of its length. Thus, there are at least two cross-sections that differ from each other.
    The variation of the cross section may comprise or even consist of a variation in shape, that is to say in a variation of: - the contour of the cross section, for example because the contour rounds off; and / or - the angular position of the cross section around the main direction, that is to say of its orientation.
    The variation may comprise or even consist of a variation in composition, that is to say in a variation of: the nature of the material or materials that define the cross section; and / or - the arrangement of the materials that define the cross-section.
    The variation may also include a variation of properties of the same material, in particular under the effect of a different heat treatment depending on the cross-sectional areas considered.
    Variations of form
    Preferably, the variation of the cross section, along the main direction X, is progressive. Advantageously, a gradual shape variation avoids creating an edge likely to injure the patient.
    In one embodiment, the variations of the cross section include a modification of the contour and / or the orientation with respect to the main direction X.
    The variation of the contour can lead to a modification of the general shape of this contour. For example, it may be parallelepipedic in a first section of the shape memory ribbon, then circular in another section.
    In Figure 2d for example, the general shape of the cross section varies along the main direction X.
    In one embodiment, the contour of the cross section locally has a concave curvature as shown in Fig. 2e (left and right shapes). This concave curvature can evolve along the main direction X. It can in particular be used to define a bonding zone.
    The variation of the contour can lead to a variation of the cross section.
    In Figure 2b, the general shape of the cross section remains rectangular, but the width and length of the section are variable depending on the position along the main direction X.
    In one embodiment, the variation of the contour can constitute a simple homothetic modification of the contour.
    In Fig. 2c, the contour of the cross section remains constant, but the orientation around the main direction X varies depending on the position along the main direction X.
    In one embodiment, the variation of the cross-section necessarily involves a modification of the contour, with or without modification of the cross-section, independently of any variations in the orientation around the main direction X.
    In one embodiment, the variation of the cross-section is a thinning, preferably in a lateral direction, that is to say parallel to the general plane P.
    The shape memory ribbon, and in particular an inter-fastener section, may take the form of, for example, a straight cylinder, with or without folds, possibly twisted on itself, of a spring, presenting a loop. opening or closing of space, an intrusion loop (force on the tooth in the direction of the bone socket), an egression loop (action opposite to an intrusion), an loop adapted to exert a torque (torsion on field of an inter-fastener section, as if one twisted an arc).
    The shape memory ribbon may consist of a single shape memory material (FIGS. 2b to 2e).
    When the shape memory tape consists of a single shape memory material, it preferably has extra thicknesses in the attachment sections. Advantageously, an excess thickness makes it possible to limit the deformations likely to be at the origin of delamination of the bonding zones.
    Heat treatment variations
    The inter-attachment sections may also undergo heat treatments reducing the forces exerted on the teeth, while maintaining the shape memory properties.
    Such heat treatments are in particular described in the report "Shape memory alloys" - CARMA (CENTER FOR REGIONAL ANIMATION IN ADVANCED MATERIALS) - Update December 2001.
    In one embodiment, the mesial regions of the shape memory ribbon, that is to say intended to be the closest to the lips in the operating position, do not undergo heat treatment. Preferably, the shape memory ribbon locally receives heat treatments whose duration increases as the treated region is close to an anterior end of said ribbon, that is to say from an end remote from the lips in position. on duty.
    Such a difference in heat treatment is particularly advantageous when the front sector of an arch, composed of single-rooted teeth, must undergo lower forces than the posterior sector. A modification of the shape of the cross section is advantageously not always essential.
    Variations of composition
    In one embodiment, as shown in FIGS. 2f to 2j, the shape memory ribbon comprises a plurality of materials, at least one of which is of shape memory. In one embodiment, all materials are in shape memory.
    One or more materials may be visible in a cross section. For example, in Figure 2j, the contour of the cross section is constant, but the nature of the material that defines the cross section is variable along the main direction X. However, each cross section is defined only by a single material .
    In one embodiment, along the main direction X, the shape memory ribbon comprises a succession of sections in a shape memory material and sections in a material without shape memory.
    Preferably, the attachment sections 11 are included in sections made of a material without shape memory. The material without shape memory can be in particular a steel. Advantageously, the shape of the attachment sections 11 is thus stable, which limits the risks of detachment or detachment.
    The shape memory material is preferably a nickel-titanium alloy. Preferably, the sections of a shape memory material are included in respective inter-link sections.
    In one embodiment, along the main direction X, the shape memory ribbon comprises, over at least a portion of its length, a succession of sections of steel fasteners and inter-fastener sections NiTi.
    In one embodiment, as shown in Figures 2g-2i, a cross-section may be defined by more than one material. In these figures, the nature and / or arrangement of the material or materials that define the cross section are variable along the main direction X.
    Different materials may be arranged in the form of superposed layers, for example according to the general plane P or in a plane perpendicular to the general plane P, as represented in FIG. 2f
    The variation of the nature of a material can be continuous, the content of this material being progressively increased or reduced. The variation in the behavior of the shape memory ribbon 10 can in particular result from a gradual change in the constitution of the shape memory alloy.
    In one embodiment, the posterior regions of the shape memory ribbon have a composition different from the previous regions. Such a difference in composition is particularly advantageous when the front sector of an arch, composed of single-rooted teeth, must undergo lower forces than the posterior sector. A modification of the shape of the cross section is advantageously not always essential.
    Figure 3 shows another example of an orthodontic appliance according to the invention.
    In FIG. 3, the one-piece shape memory tape 10 extends in front of three teeth D1, D2 and D3. It is bonded, by bonding areas 12i and I2i, to the outer teeth D1 and D3, the bonding areas 12i and I2i having complementary shapes to the surfaces of the teeth D1 and D3 to which they apply.
    The shape memory ribbon is shaped to act on the tooth D2 to move when it returns to its stable position. Preferably, the shape memory ribbon is supported on the tooth D2.
    FIG. 3b shows the evolution of the cross section along the main direction X. The shape memory tape 10 comprises in particular thinned sections 16 in which the surface of the cross section is reduced.
    The reduction of a dimension of the cross section of the shape memory ribbon, and in particular of its thickness, can in particular be used for inter-linked sections, if the movements to be applied are simple and of low intensity. The reduction of a dimension is accompanied by a decrease in the force applied. The application of a low intensity force is particularly sought in the prior dental areas in which the teeth are monoradiculate and the relatively small roots. The reduction in the intensity of the forces applied can also result from a thermal treatment of the inter-attachment sections, as explained above.
    Preferably, the reduction of the dimensions of the cross section is effected in a preferred direction, for example along a direction in the general plane P and perpendicular to the general direction X. The shape memory ribbon thus tends to bend around an axis perpendicular to the general plane P. The orientation of the cross section around the main direction X also serves to orient the bending of the ribbon 10.
    In the central region, the structure is composite, the section 18 may be in a first shape memory material and the second section 20 may be in a second shape memory material.
    A composite structure may also result from a particular property of a region resulting from the application of a particular treatment, for example a specific heat treatment to reduce the forces exerted. For example, a heat treatment may be applied to an anterior region of the shape memory ribbon, so that the delivered forces are small and thus provide a significant deflection of an inter-linked section. The exercise of weaker forces may be particularly useful for the incisors, which have small roots.
    Whatever the embodiment, preferably at least two, preferably more than two, more than three, more than four, more than five, or even more than eight sections of the shape memory ribbon, each representing more than 1 %, preferably more than 5%, preferably more than 10%, or even more than 20% of the length of the shape memory ribbon. have different cross-sections from those of the adjacent section (s). In Figure 4 for example, the cross sectional profile comprises five sections Li to L5, each having a cross section different from those of (the) section (s) adjacent (s).
    In one embodiment, the shape memory ribbon comprises at least one, preferably at least two, preferably more than two, more than three, more than four, more than five or even more than eight sections in which the section transverse is continuously variable, each of said sections extending over more than 1%, preferably more than 5%, preferably more than 10%, or even more than 20% of the length of said tape. For example, the shape memory ribbon shown in FIG. 3b has a single section in which the cross section varies continuously along the main direction X.
    More preferably, no portion of the shape memory ribbon represents more than 80%, more than 60%, more than 40%, more than 20%, more than 10%, more than 5%, or even more than 2% of the Ribbon length has a constant section. In other words, there is no long section of the ribbon of constant section.
    FIGS. 5a to 5c illustrate variations in the cross section of the ribbon in height (FIG. 5a) or in thickness (FIG. 5c). The transverse dimensions of the ribbon may be increasing or decreasing as one approaches its ends.
    Manufacturing process
    The manufacture of a shape memory ribbon according to the invention preferably comprises the steps a) to c) described above. In step a), the orthodontist determines the patient's maleated teeth and how they are to be moved to achieve the desired arrangement from an initial arrangement of said teeth. For this purpose, the orthodontist can take an impression of the teeth, make a model in plaster of the teeth, then evaluate how the different teeth must be moved.
    Preferably, the orthodontist performs a three-dimensional scan of the teeth in patient malposition, so as to obtain an initial digital model of the teeth. The orthodontist then performs a simulation, preferably computer, of the treatment to determine a set of movements and forces to be exerted on said teeth to obtain said treatment.
    In particular, it can modify the initial numerical model until a final numerical model corresponding to the desired arrangement of the teeth is obtained. A comparison of the final and initial numerical models allows him to precisely determine the different displacements required. In step b), the orthodontist evaluates all of the forces required to move the patient's teeth to the desired final arrangement. Preferably, it also determines when these forces should be applied. In step c), the orthodontist manufactures the orthodontic appliance, and in particular the orthodontic ribbon, so that it can exert all the forces determined in step b), at the appropriate moment.
    In particular, the dimensions of the inter-attachment sections are adapted according to the force or the anchorage to be exerted. Anchoring is intended to fix the shape memory tape to one or more teeth that will be able to remain substantially immobile. Preferably, a plurality of teeth are rigidly secured to one another by means of an "anchor section" of the shape memory ribbon. Preferably, the anchoring section is made of steel and / or has a cross section adapted to limit its deformation, in particular an excess thickness. An adaptation of the cross section is particularly suitable when the shape memory tape is entirely made of a shape memory material.
    In steps b) and c), the orthodontist preferably implements a suitable computer program. In particular, to predict the behavior of an orthodontic appliance according to the invention, that is to say to simulate and "program" the shape memory ribbon, it can use methods whose principles are well known:
    In particular, it is possible to theorize the behavior of materials according to their environment, and in particular as a function of interactions with other materials.
    Alternatively, the behavior can be anticipated from different tests. The multiplication of the tests and their analysis thus makes it possible to anticipate, empirically, the behavior of a specific shape memory ribbon.
    These two approaches, theoretical and empirical, lead to a numerical model of the behavior of the shape memory ribbon, according to its environment and time. This model, called "predictive", allows to predict the action of a particular shape memory ribbon. Conversely, to obtain a particular desired action, the predictive model allows the orthodontist, preferably assisted by the computer, to develop a shape memory ribbon according to said desired action.
    In practice, the orthodontist can create a digital model of a shape memory ribbon to be tested, and then, with the predictive model, simulate the action of this shape memory ribbon on the teeth, as a function of time. He can thus search, preferably using the computer program, the ribbon configuration best suited to the targeted treatment.
    The degree of precision of the empirical approach is generally lower than that obtained with the theoretical approach. However, the empirical approach is simpler to implement. In step c), the orthodontist can thus determine the local cross section of said ribbon as a function of the force to be exerted locally, and, preferably, as a function of the moment at which this force must be exerted. Preferably, the force to be exerted "locally", and thus the "local" configuration of the cross section, are evaluated for each tooth to be displaced.
    When designing the ribbon, the width and thickness of said ribbon may vary depending on the intensity of the forces to be applied and the size of the root surface. These dimensions can also be increased without applying forces. In this case, it is on the contrary to prevent certain types of movement, including parasitic movements of loss of anchoring, bowing effect, rabbiting ...
    To make the shape memory ribbon, the orthodontist preferably uses a 3D printer. Such a printer advantageously makes it possible to manufacture a shape memory ribbon of complex shape and / or in several materials, with good accuracy. 3D printing also allows immediate fabrication of the shape memory ribbon.
    As an alternative to 3D printing, metallurgical techniques can also be used to manufacture a shape memory ribbon according to the invention.
    Preferably, during manufacture, the orthodontist deactivates the shape memory by cooling below the corresponding threshold temperature. He then conforms the shape memory ribbon, in three dimensions, so that it corresponds to the initial state of the dental arch with its malpositions. Preferably, the conformation is carried out by means of a robot. The companies Sure Smile or Incognito proposes robots capable of such conformation.
    In a subsequent step d), the orthodontist sticks the shape memory ribbon while maintaining the temperature below said threshold temperature.
    Once stuck, the ribbon temperature rises to the body temperature of the patient. The temperature thus exceeds the threshold temperature, which activates the shape memory and immediately generates custom forces to obtain correction of the positioning of the teeth, in the three dimensions of the space.
    Figure 7a illustrates how a shape memory ribbon 10 can bring two teeth DI and D2 closer together. The shape memory ribbon is bonded by respective bonding areas 12i and 122 to the faces of the teeth DI and D2, respectively. The shape memory ribbon has a loop 30 which, under the conditions of temperature of the mouth, tends to close, and thus bring the teeth DI and D2 closer to each other.
    FIG. 7b illustrates a shape memory ribbon making it possible both to separate DI and D2 teeth from one another, by extension of a shape memory section 14i, and to align a tooth D3 with the teeth DI and D2, by extension of a second shape memory section 142 fixed not only on the teeth DI and D2, but also on the intermediate tooth D3. Unlike the shape memory ribbon shown in Fig. 7a, the shape memory ribbon shown in Fig. 7b has loops that tend to open when the shape memory ribbon is disposed in the patient's mouth.
    As now clearly apparent, the invention provides a custom shape memory ribbon, i.e. programmed specifically for a particular orthodontic treatment. This programming makes it possible to ensure that at all times the action of the orthodontic appliance corresponds precisely to the desired action. The action of the orthodontic appliance can thus be optimized for rapid treatment and / or to limit the phenomenon of hyalinization. Optimization also makes it possible to limit the number of orthodontic treatment modifications, and in particular the number of orthodontist appointments.
    Moreover, unlike the orthodontic treatments of the prior art, it is not necessary to multiply the number of orthodontic arches to achieve alignment of the teeth.
    In particular, the orthodontic appliance according to the invention adapts perfectly to the contours of the teeth to be aligned. It exerts forces of variable intensity according to the importance of the malposition of the tooth as well as according to the root surface of the teeth. The larger the area, the more forces to apply.
    Controlling forces applied during orthodontic treatment also limits the risk of detachment.
    Moreover, the shape memory ribbon may advantageously be fixed directly on the teeth, which simplifies its setting in the service position.
    Orthodontic treatment is therefore faster, more efficient and cheaper.
    Of course, the invention is not limited to the embodiments described and shown, provided for illustrative purposes only. In particular, the different variations described above can be combined.
    In addition, an orthodontic appliance may comprise a plurality of memory-form ribbons according to the invention.
    权利要求:
    Claims (15)
    [1" id="c-fr-0001]
    An orthodontic appliance comprising a one-piece shape memory ribbon whose cross section is variable as a function of the longitudinal position of said transverse section, and comprising a bonding zone shaped so as to have a shape substantially identical to that of a tooth .
    [2" id="c-fr-0002]
    An orthodontic appliance according to the immediately preceding claim, wherein the contour of the cross-section and / or the angular position of the cross-section around the main direction the cross-section is variable according to the longitudinal position. of said cross section.
    [3" id="c-fr-0003]
    An orthodontic appliance according to any one of the preceding claims, wherein the nature of the material (s) defining the cross-section and / or the arrangement of the materials defining the cross-section is (are) variable as a function of the longitudinal position of said cross section.
    [4" id="c-fr-0004]
    An orthodontic appliance according to any one of the preceding claims, wherein the cross-section comprises first and second zones defined by the same material, the properties of the material defining the first zone being different from those of the material defining the second zone.
    [5" id="c-fr-0005]
    An orthodontic appliance according to any one of the preceding claims, wherein the cross-sectional area and / or the composition of the material or materials defining the cross section and / or the mechanical properties of the cross-section defining material (s) is (are) variable (s) depending on the longitudinal position of said cross section.
    [6" id="c-fr-0006]
    An orthodontic appliance according to any one of the preceding claims, wherein the variation of the cross section along the main direction X is progressive over more than 1% of the length of the shape memory ribbon.
    [7" id="c-fr-0007]
    An orthodontic appliance according to the immediately preceding claim, wherein the variation of the cross-section along the main direction X is progressive over more than 5% of the length of said shape memory ribbon.
    [8" id="c-fr-0008]
    An orthodontic appliance according to any one of the preceding claims, wherein the variation of the cross-section comprises thinning.
    [9" id="c-fr-0009]
    An orthodontic appliance according to any one of the preceding claims, wherein at least two sections of the shape-memory ribbon, each representing more than 5% of the length of the shape-memory ribbon, have different cross-sections from those of the adjacent section (s).
    [10" id="c-fr-0010]
    An orthodontic appliance according to any one of the preceding claims, wherein the ribbon comprises at least one region of a material selected from the group consisting of nickel-titanium NiTi, CuAlZn and CuNiAl alloys.
    [11" id="c-fr-0011]
    An orthodontic appliance according to any one of the preceding claims, comprising steel attachment sections (11) and inter-attachment sections (14) of a shape memory material, said attachment sections and inter- fasteners succeeding one another along the main direction (X) of the shape memory ribbon.
    [12" id="c-fr-0012]
    An orthodontic appliance according to any one of the preceding claims, wherein the shape memory tape has a groove (24) in which a reinforcement (22) can be accommodated to stabilize the shape of said shape memory tape.
    [13" id="c-fr-0013]
    13. A method of manufacturing a shape memory tape of an orthodontic appliance according to any one of the preceding claims, said method comprising the following steps: a) determining an orthodontic treatment adapted to the treatment of the teeth of an orthodontic appliance. patient; b) determining a set of forces to be exerted locally on said teeth to obtain said orthodontic treatment and the shape of the surface of the teeth on which gluing areas of said shape memory ribbon are to be glued; c) manufacturing said shape memory ribbon, the local cross section of said shape memory ribbon being determined according to said forces and so as to define gluing areas substantially identical to the surfaces of said teeth to which they must be glued.
    [14" id="c-fr-0014]
    The method of the immediately preceding claim, wherein in step c), heat-treating one or more regions of the shape memory ribbon to locally reduce the forces exerted on the teeth in the operating position.
    [15" id="c-fr-0015]
    The method of the immediately preceding claim, wherein in step c), the intensity of the heat treatment of a region of the shape memory ribbon is dependent on the distance of the teeth in the vicinity of said region, in the position of service, with respect to the incisors of said patient.
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    同族专利:
    公开号 | 公开日
    EP3457981A1|2019-03-27|
    AU2017266695A1|2018-12-06|
    KR20190028380A|2019-03-18|
    FR3051352B1|2021-08-27|
    CN109561946A|2019-04-02|
    WO2017198640A1|2017-11-23|
    AU2017266695B2|2021-10-21|
    CA3024189A1|2017-11-23|
    EP3457981B1|2021-09-08|
    US20190282336A1|2019-09-19|
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    US20050277083A1|2004-06-10|2005-12-15|3M Innovative Properties Company|Arch member for an orthodontic brace|
    WO2011036249A1|2009-09-25|2011-03-31|Antoine Meley|Orthodontic working arch wire, and orthodontic treatment system including said arch wire|
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    US8685184B2|2010-08-24|2014-04-01|Ormco Corporation|Shape setting a shape memory alloy dental arch|
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    CN110177521A|2016-12-02|2019-08-27|斯威夫特健康系统有限公司|Indirect Orthodontic bonding system and method for bracket placement|
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    FR3079737A1|2018-04-09|2019-10-11|D & D|DENTAL DEVICE|
    CN110974451A|2019-04-27|2020-04-10|北京大学口腔医学院|Periodontal splint and manufacturing method thereof|
    法律状态:
    2017-04-28| PLFP| Fee payment|Year of fee payment: 2 |
    2017-11-24| PLSC| Publication of the preliminary search report|Effective date: 20171124 |
    2018-05-29| PLFP| Fee payment|Year of fee payment: 3 |
    2019-05-31| PLFP| Fee payment|Year of fee payment: 4 |
    2020-05-26| PLFP| Fee payment|Year of fee payment: 5 |
    2021-04-28| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1654422A|FR3051352B1|2016-05-18|2016-05-18|SHAPE MEMORY TAPE|FR1654422A| FR3051352B1|2016-05-18|2016-05-18|SHAPE MEMORY TAPE|
    CN201780031012.2A| CN109561946A|2016-05-18|2017-05-16|Correction shape memory strip|
    US16/301,217| US20190282336A1|2016-05-18|2017-05-16|Orthodontic shape memory band|
    KR1020187036208A| KR20190028380A|2016-05-18|2017-05-16|Shape storage band for orthodontics|
    CA3024189A| CA3024189A1|2016-05-18|2017-05-16|Orthodontic shape memory band|
    EP17722828.5A| EP3457981B1|2016-05-18|2017-05-16|Orthodontic shape memory band|
    AU2017266695A| AU2017266695B2|2016-05-18|2017-05-16|Orthodontic shape memory band|
    PCT/EP2017/061661| WO2017198640A1|2016-05-18|2017-05-16|Orthodontic shape memory band|
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