DIFFERENTIAL ARCHWIRE

DESCRIPTION

TECHNICAL FIELD AND BACKGROUND OF THE INVENTION The present invention relates to an archwire to be utilized as a component of fixed orthodontic appliances.

It is known that orthodontic appliances are utilized to move teeth along the three planes of the space. Fixed orthodontic appliances include a series of brackets glued to the teeth, and archwires secured to the slot present in the brackets. Brackets having slots with rectangular cross-sectional shape are called "edgewise", and they are the ones most frequently used today. The forces used to move the teeth are generated by coil springs or elastic chains attached to the brackets, or by closing loops modeled on the arch wires.

In many phases of the orthodontic treatment it is necessary to move the incisors of the upper dental arch backwards. This movement is often encountered in the final phase of the treatment of the malocclusion of second class, characterized by the fact that the upper dental arch is positioned too far mesially in relation to the lower dental arch. The distalizing class I force used to move the upper incisors backwards is generated by elastic chains or coil springs running from the molars to the incisors, or by closing loops modeled on the arch wires.

Up to date there are two techniques used to move the incisors backwards: techniques that utilize sliding mechanics, and techniques ^v that utilize non-frictioning mechanics. Sliding mechanics is the basis of the "straight wire technique". An arch wire with costant cross-sectional size on all teeth is utilized. Slots of the brackets have the same cross-sectional dimension on all teeth. A backward force is generated by elastic chains or coils running from incisors to molars. As incisors retract, the arch wire slides through the slots of the brackets of canines, premolars, molars. The critical point of this technique is the cross-sectional size of the arch wire. An arch wire with small cross sectional size slides well along the brackets of posterior teeth, but it gives no control to the bucco-lingual inclination of the incisors during their retraction. In fact the wire has too much play and is free to rotate inside the slots of the brackets of the incisors. As a consequence, during the retraction, incisors rotate around a center of resistance 21 placed at the apical third of the root, and become more upright. This effect is negative because this way upper incisors end up hitting the lower incisors

(fig- 5).

On the other hand, an archwire with big cross-sectional size gives good control to the bucco-lingual inclination of the incisors during their retraction, but it generates too much friction on the brackets of the posterior .teeth, hampering the sliding of the arch wire along the brackets of posterior teeth.

The "Bidimensional technique" utilizes sliding mechanics, and it has been introduced with the aim to solve the above-cited problem. In the "bidimensional technique" the slots of the brackets of the inciors have cross-sectional size 0.018 by 0.025 inches, and the slots of the brackets of canines, premolars and molars have cross-sectional

size 0.022 by 0.028 inches. The arch wire used to retract the incisors has cross- sectional size 0.018 by 0.022 inches. This arch wire fills completely the slots of the incisors, assuring good control of the bucco-lingual inclination (torque) of the incisors during their retraction. At the same time this arch wire with cross-sectional size 0.018 by 0.022 inches has a lot of play inside the slots of canines, premolars and molars, assuring low friction and good sliding of the wire along these brackets. The main drawback of the "bidimensional technique" is that the thickest arch wire that can be utilized has cross-sectional size 0.018 by 0.022 inches, because the brackets of the incisors have slots with height 0.018 inches. This archwire cannot control the bucco-lingual inclination (torque) of the posterior teeth (canines, premolars, molars), which is important in other phases of the orthodontic treatment (for example during the repositioning of impacted canines or during the up-righting of linguo-inclined molars).

Wool in his patent (U.S. patent number 6,811,397) describes an orthodontic archwire characterized by an anterior segment with rectangular cross-section, that can have a good control of the bucco-lingual inclination of the incisors, and by two posterior segments with round cross-section that have the aim to reduce the friction between said posterior segments and the slot of the brackets of the posterior teeth. The main drawback of this design of archwire is that the round cross-section of the posterior segments doesn't generate enough rigidity of the archwire along the horizontal plane. As a consequence, the forces utilized to move the teeth cause the tipping of the posterior teeth towards the side of the tongue, and distort the shape of the dental arch. Foerster in his patent (German patent with title "torque-bogen", number DE441947 IAl), describes an archwire with non-circular cross-section characterized by an anterior segment constituted by super-elastic material and possessing a torsional component. This torsional component has the aim to increase the torque of the roots of the incisors towards the palate, during the retraction of the incisors. The main drawback of this design is that the anterior segment, constitued by super-elastic material, doesn' t generate enough rigidity of the archwire along the horizontal plane. As a consequence, the forces used to move the teeth backwards cause a tipping of the teeth towards the side of the tongue.

Chikami in his patent (patent number EP 1 092*398 Al) describes an orthodontic wire. However this wire is to be utilized as a retainer wire and is a removable appliance; it is not utilized as part of fixed orthodontic appliances.

Non-frictioning mechanics utilize closing loops modeled on the archwire in a position distal to the lateral incisors (see as a reference the U.S. patent number 5,131,843 by Hilgers). The archwire is positioned in the brackets, and the part of the archwire that is behind the bands of the molars is pulled backwards and blocked with a 90 degree bend. This way the closing loop is opened and activated. The closing loop, because of the elasticity of the material that constitutes the archwire, tends to close itself and to pull the incisors backwards. The archwire that is utilized has big cross-section size in order to folly engage into the slot of the brackets and to control the bucco-lingual inclination of the incisors.

The problems associated with the closing loops are that the loops can irritate the cheeks and that they tend to trap food and plaque. Furthermore the activation of the loops and the removal of the archwire requires a lot of chair-time.

The objective of the present invention is an archwire, called "differential archwire". characterized by an anterior segment 11 with big cross-section area, and by two posterior segments 12,13 with smaller cross-section area (fig. 1,2,3,4). The "differential archwire" is to be utilized in association with pre-adjusted brackets today available on the market. The cross-section dimensions of the slots is the same in all the brackets. The shape of the cross-section of the anterior segment and of the posterior segments of the archwire is preferably, but not necessarily rectangular with the long side of the rectangle placed along the horizontal plane. The "differentail archwire" is used to retract the incisors. After the retraction of the incisors is completed, the archwire can be easily changed with little cost and with little chair-time by an archwire with a big cross-section area along the entire archwire, in order to have full control of the torque of the posterior teeth. The material that constitutes the archwire is preferably, but not necessarily stainless steel.

The anterior segment of the archwire 11 is inserted into the slots of the brackets of the central and lateral incisors, the posterior segments 12, 13 are inserted into the slots of the brackets of the canines, premolars and molars (fig.6). The anterior segment of the archwire has a big cross-section area, in order to completely fill the slot of the central and lateral incisors, and to generate a good control of the the bucco- lingual inclination of the incisors during their retraction. The interaction between the archwire with rectangular cross-section and the slot, also with rectangular cross- section, generates a couple of forces that pushes the roots of the incisors towards the palate (fig. 7). The final result that is obtained is the backward translation of the incisors (fig. 9).

The posterior segments have a smaller cross-section area, in order to allow them to slide with low friction along the brackets of the canines, premolars, molars. A force, generated by elastic chains or coil springs, is applied from the incisors to the molars. As incisors retract, the posterior segments of the archwire 12,13 characterized by the small cross-section area, slide along the brackets of canines, premolars and molars (fig.8).

Furthermore, it is known that the rigidity of an archwire is directly proportional to the cross-section area of the wire. As a consequence, the anterior segment 11 that is thicker, is also more rigid and this helps to control the inclination of the incisors during their retraction. The posterior segments 12,13 have a smaller cross-section area in order to generate big play between the archwire and the slots of the posterior teeth. This allows the wire to slide with low friction along the brackets of the canines, premolars and molars when the incisors are retracted (fig. 8). Also, the posterior segments with smaller cross-section area are more flexible. It is known that the friction generated by two surfaces that have to slide on one-another is directly proportional to the force applied to the surfaces. Thinner wires are more flexible

and, when they are deflected, they give a lower force responce than the one given by thicker wires. The small cross-section area of the posterior segments helps them to slide with low friction along the brackets of the posterior teeth, also when these teeth are not perfectly aligned and deflect the posterior segments of the archwire. (From now on all dimensions are expressed in inches). For example, if we work with brackets with slots with dimension 0.022 by 0.028 inches on all teeth, the "differential archwire" will have preferably but not necessarily, section 0.021 by 0.025, or 0.020 by 0.025 in the anterior segment 11; the posterior segments 12,13 will have preferably, but not necessarily, section 0.018 by 0.022, or 0.017 by 0.022. If we work with brackets with slots of dimension 0.018 by 0.022 on all teeth, the differential archwire will preferably, but not exclusively, have section 0.018 by 0.022, or 0.017 by 0.025 in the anterior segment 11, and 0.016 by 0.020 or 0.016 by 0.018 in the posterior segments 12,13.

The shape of the cross-section of the anterior segment 11 or of the posterior segments 12,13, or of all three segments can be a polygon (square, rectangle, octagon, hexagon), or a trapezium. The shape is preferably, but not necessarily, rectangular with the long side of the rectangle placed along the horizontal plane of the space (fig. 4). The forces that are utilized to close the spaces present in the dental arch are exerted over a semicircle. Hence, these forces have a centripetal component, and they tend to push the teeth towards the side of the tongue and to generate a decrease of the transverse diameter of the dental arches. The component that resists these centripetal forces is given by the rigidity of the archwire. For this reason it is preferable to use an archwire with rectangular cross-section with the long side of the rectangle placed along the horizontal plane. This shape of the cross-section of the archwire guarantees a higher rigidity of the archwire along the horizontal plane (fig. 4). Sometimes the patient presents a big overlap of the upper incisors over the lower incisors (deep overbite), hi these cases it is necessary to intrude the upper incisors before their retraction, in order to avoid interferences of the upper incisors with the lower incisors during the retraction. In order to accomplish this objective, a step can be created between the anterior segment 11, and the posterior segments 12,13 of the archwire. This step will be created preferably, but not necessarily, by means of two bends 16,17 placed one on each side in a position distal to the lateral incisors, in the transition point between anterior and posterior segments 14,15 (fig. 10). This step will intrude the incisors 21,22 and will extrude the posterior teeth 23, 24, 25, 26, creating a reduction of the overbite (fig. 11). The fact that the posterior segments of the archwire are thin and hence more flexible, helps to keep the force applied to the canine and the friction at low levels, and to allow the sliding of the archwire along the brackets of the posterior teeth.

This step, furthermore, generates a moment given by the intrusive force multiplied by the arm 31 and by the sine of the angle alpha delineated by the arm and the intrusion force (fig. 12). This happens because the point of application of the intrusion force is placed in a position that is buccal in relation to the center of resistance 51 of the tooth. This moment generates an increase of the buccal-crown torque of the incisors, that is very beneficial during their retraction.

The "differential archwire" can be utilized also in the clinical cases where the first premolars are extracted, in order to create space in the dental arches to align crowded teeth. In the clinical practice usually the first premolars are extracted, and then the canines are moved backwards in order to align the incisors. At this point, if residual space remains in the dental arches, many clinicians prefer to keep the position of incisors and canines unchanged, and to close the residual space by means of the advancement of the second premolars and of the molars. In this phase of treatment a differential archwire can be utilized, presenting the anterior segment with big cross- section area 11 occupying the brackets of the incisors 21,22 and canines 23, and the posterior segments 12,13 with small cross-section area occupying the brackets of the second premolars 25 and of the molars 26 (fig. 13). The anterior segment of the archwire with big cross-section area 11 gives good control to the inclination of the incisors and of the canines, while the second premolars and the molars can slide forward, under the effect of the class I force, and close the residual space of extraction. The posterior segments 12, 13 with small cross-section area generate low friction in the slot of the premolars and molars! Furthermore, the anterior segment of the archwire with big cross section-area 11, that runs from canine to canine, resists the centripetal forces and helps to keep a correct transversal diameter of the dental arches. This control of the transversal diameter of the dental arches is increased by the fact that the shape of the cross-section of the archwire is rectangular with the long side of the rectangle placed along the horizontal plane, both in the anterior segment 11 and in the posterior segments 12,13 of the archwire (fig. 4).

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1

Differential archwire, view from top

11= anterior segment of the differential archwire

12-13= posterior segments of the differential archwire

14-15= transition points between anterior and posterior segments

FIG. 2

Differential archwire, lateral view

11= anterior segment

13= posterior segment

15= transition point between anterior and posterior segment

FIG. 3

Differential archwire, frontal view

11= anterior segment

12-13= posterior segments

14-15= transition points between anterior and posterior segments

FIG. 4

Differential archwire, perspective view

11= anterior segment

12-13= posterior segments

14-15= transition points between anterior and posterior segments

FIG. 5

Lateral view of the incisor and of the molar, showing the loss of torque control of the incisor

51= center of resistance of the incisor

21= incisor

26= molar

28= occlusal plane

FIG. 6

Lateral view of the appliance in place

11= anterior segment

13= posterior segment

15= transition point between anterior and posterior segment

21= central incisor

22= lateral incisor

23= canine

24= first premoalr

25= second premolar - _χ

26= molar

FIG. 7

Lateral view of the cross-section of the anterior segment of the wire that completely fills the slot of the brackets of the incisors

11= anterior segment of the differential archwire, view of the section

21= incisor

41= incisor bracket

FIG. 8

Lateral view of the posterior segment with small cross-section area, that occupies the slot of the brackets of canine, premolars and molars

11= anterior segment of the differential archwire

13= posterior segment of the differential archwire

15= transition point between anterior and posterior segment

23= canine

24= first premolar _v

25= second premolar

26= molar

\

FIG. 9

Backwards translation of the incisor, lateral view

21= incisor

23= canine

24= first premolar

25= second premolar

26= molar

FIG. 10

Frontal view of the differential archwire, wherein a step is created between the anterior and the posterior segments of the archwire

11= anterior segment

12-13= posterior segments

14-15= transition points between anterior and posterior segments

16-17= bends placed on the archwire

FIG. 11 ^v

Lateral view of the appliance in place, wherein a step is created between anterior and posterior segments

11= anterior segment

13= posterior segment

15= transition point between anterior and posterior segment

17= bend placed on the archwire

21= central incisor

22= lateral incisor

23= canine

24= first premolar

25= second premolar

26= molar

29= bracket of the canine

FIG. 12

Lateral view of the incisor: moment created by the step placed between anterior and posterior segments of the archwire

51= center of resistance of the incisor

21= incisor

31= arm

FIG. 13

Lateral view of the appliance in place: in clinical cases with extraction of the first premolars the anterior segment with big cross-section area extends from canine to canine

11= anterior segment

13= posterior segment

15= transition point between anterior and posterior segments

21= central incisor

22= lateral incisor

23= canine

25= second premolar

26= molar

FIG. 14

Lateral view of the differential archwire, wherein the transition between anterior and posterior segments is gradual

11= anterior segment

13= posterior segment

15= transition point between anterior and posterior segments

FIG. 15

Lateral view of the differential archwire, with concentric anterior and posterior segments

11= anterior segment

13= posterior segment

15= transition point between anterior and posterior segments