CA2180106A1

CA2180106A1 - Tensioning system for an orthodontic outer brace

Info

Publication number: CA2180106A1
Application number: CA002180106A
Authority: CA
Inventors: Johan Anton Kooiman
Original assignee: Individual
Current assignee: Individual
Priority date: 1994-01-05
Filing date: 1995-01-04
Publication date: 1995-07-13
Also published as: EP0797412B1; AU692505B2; NO962792D0; JPH09507146A; DE69519174T2; DE69519174D1; US5667380A; EP0797412B9; US5915961A; WO1995018580A1; AU1284995A; NO962792L; NZ277570A; EP0797412A2; FI962755A0; FI962755A; ATE196985T1; NL9400009A

Abstract

The invention relates to a tensioning system for an orthodontic outer brace (21), comprising resilient means, and coupling means (9) for transmitting a tensile force exerted by the resilient means to the outer brace. The resilient means comprise a resilient element (5). The tensioning system comprises an arc-shaped guide path (4), along which the resilient element (5) is freely movable.
Coupling means can be fixed on one side to the outer brace and are connected to one another on the other side via the resilient element, such a way that the resilient element moves along the guide path when the patient turns his or her head. The guide path can comprise a tube or an arc-shaped strip of metal or can be formed in some other way. Preferably, the guide path is so flexible that the arc shape thereof can be adjusted to the curvature of the patient's neck. The resilient element preferably has a spring constant which decreases or is zero on further extension after a specific spring force or extension is reached. The resilient element is preferably a helical spring.

Description

wo 95118580 218 010 ~ Pcr~Lss/oonoc TENSIONING SYSTEM FOR AN UKlt .llC OUTER ~RACE
Descriplion The present invention relates to a tensioning system for an ~hnflnn~ir outer brace, comprising resilient mearls, and coupling mcans for ~ a tensile force exerted bythe resilient means to the outer bracc.
Tensioning systems of this type are generally known, for example from US-A
3 5~6 û35. This patene discloses a tensioning system for a so-called neck brace, rnnnrricinv a neck band on which a strip of flexible material is mounted. Two small protecti-e tubes are fixed to said strip, there being a spring in each tube. The springs are fixed on one side to the carrying strip and on the other side to onc end of coupling means, which can be fixed to the outer brace by their other end. By stretching the respecti-e springs and then fixing the coupling :neans to the outer brace in such a way that the springs remain stretchcd, a tensile force directed towards the neck is exerted on the outer brace. Via an inner bracc fixed to the outer brace at the mouth, said tensile force is transmitted to two or morc teeth, by which means the position of the latter can be corrected.
A further u~ odvll~ic outer brace having a tensioning system is disclosed in DE-A
3 417 756. In this case the ncck band is slidably mounted in plastic guide sleeves. Said neck band is provided at both ends with ~. . r(~,, l ir ,~ for adjustably fi~ing ends of resilient elements (in the form of clastic strips), which can be fixed at the opposite end to the outer brace itself. Rcsilient elements of this type attached to either side of the head between the ends of the neck band and the ends of the outer bracc requirc a ccrtain fitting length and fixing elements which seriously impede any freedom of head movement which the wearer '5 may have. Moreover, accurate adjustment of a desired tensioning force for correction of the teeth is made more difficult by the interaction of the two resilient elements joined to one another by the neck band.
The comfort of tensioning systems of this type for the wearer leaves something to be desired because the freedom of movement of the head is impeded. If the patient tums his or her head to the left or the right (that is to say shakes his or her hcad to indicate no), an additional CollllJlcS~iVc force directed towards the left side or the right side of the teeth and backwards (that is to sav towards the neck) will be e~certed on the teeth concemed, whilst on the other side of the teeth a tensile force dirccted frontwards will be exerted on the teeth WO 95/18580 ~ pcr/NLsslonoo6

2~~ 2 ~
concemed which are located on the right or OD the left. Thcse addi~ional forces can be fairly large, are unpleasant for the patient and are u,..l~sildbl~ from the standpoint of the v.~l~odo,.lic treatment. Similar problems arise in the case of the movement of the head to indicate yes, in which case the resilient means are strctched further.
The aim of the present invention is to provide a tensioning system for an orthodontic outer bracc with which the tensioning force to be transmitted to the teeth remains as constant as possible and the comfort for the wearer and thc freedom of mov~ment of the patient are increased.
According lo the invention, this aim is achieved in that the resilient means comprise a resilicnt element, in that the tensioning system comprises an arc-shaped guide path, along which the resilient element is movable, and in that the coupling means can be fixed on one side to the outer brace and are connected to one another on the other side via the resilient element. As a result of thcse measures, the resilient element moves along the guide path when the patient tums his or her kead. With this ~",."g~ .,...,~ the resilient element, such I5 as, for example, an elastic band or a coil spring, is, as it were, fitted between two pairs of coupling means, such as, for example, two pieces of cord-like or strip-like material, in such a way that if a pull is exerted on one coupling means, a tensile force is transmitted via the spring to the other coupling means. The spring and thc coupling means are able to mo~ e freely along the guide path in the direction of the guide path. If the tensioning system "O is fitted to a patient's neck and th~ coupling means are fixed to the outer brace, the entirc unit, comprising the arms of the outer brace, the coupling means and the rcsilient element, forms, as it were, a closed "ring", which runs around the neck, the cheeks amd the mouth of the patient. If the head is moved to the left or to the right, the "ring~ tums in concert via the mouth and the outer brace, and the resilient element guided along the guide path 25 will therefore move around in the same direction. With this ~ .I.L~ the resilient element will be subjected to no or hardly any additional stretching, as a result of which the forces exerted on tlle teeth remaim virtually constant. Large peaks in these w,~ ;v~:
forces, such as occur with ~Ull~ iUll~ l tensioning systems, are largely avoided.
In order to protect the movable resilient element and to guarantee the free movabilit~v 30 thereof, it is dV~UI~ ,VU~, according to the invention, for the guide path to comprise a rube. An additional advantage is that the patientls hair does not get caught in the rcsilient elemeM and does not impede the movement backwards and forwards along the guide path.
To ensure optimum comfort in wcar and to ensure that the resilient element is WO 95/18580 2 18 0 10 6 PCT/NL9~C/00006

3 :
movable as flexibly as possible, it is a~iv~ult~5~vus, according to the invent~.on, if the gulae path is flexible, in such a way that the arc shape thereof can be adjusted to the cur~atur~
of the patient's neck. in this context, it is ~ ulculy ad~antageous if the arc shape, as it were, continuallv adjusts to the shape of the neck during use.
Acco~ciing to the invenrion, a nexible tubular guide path can be advantageousi~
obtained bv shaping the guide path from a wire or strip wound to gi~e a spiral-like winding. However, ordinary tubes made of a fiexible material are aiso very suitable.
in order to pre~ent, for ~xample, thc patient's hair from getting caught between the spiral-like winding it is d ivdllL..~ous, :according to the invention, if the outside of the 10 spiral-like winding, is provided with a covering which covers the winding.
Ver,v suppie movement of tbe resilient element is achieved, according to the invention, in that the guide path compris~s an arc-shaped strip, preferably made of metai, which has an essentiallv smooth sliding plane for the resilient element. The cross-seclional shape of thc sliding plane can, if necessary, be inatched to the cross-sectional shape of the 15 resilient element. The arc-shaped strip then forms a guide channel which has a sliding plane on the inside.
The rcsilient element can move along the guide channel with vcry little friction.
Wire-like coupling means made of plastic, such as nylon, will make contact with the guide path because of the arc shape of the latter, so that there will be some question of friction.
0 This friction is ~ery small if the guide path has a smooth metal sliding plane.
in the case of a tubular guide, the intcmal .7;.,...,C;fl..~ of thc tube will be matched to the cross-section of the resilient element.
The guide for the rcsilient element can comprise a tube, an arc-shaped strip or both.
However, the guide can also be fommed in another way, for example by means of a rail.
'~ The tube or the guide strip can be madc of a wear-resistant plastic, such as tcflon.
According to the inventiorl, it is aiso d~lvau~.5_vus if the spring constant (C) of the resilient element decreases on further extension of the resilient element, preferably from a certain spring force (F) or extension (L). The equation F = C x L givcs the ~
berween the spring force, the spring constant and the extcnsion hcre. i~f the resilient element 30 has to become a little longer when the patient moves his or her head, a resilient element of this type ensures that the additional forccs excrted on the teeth remain rclatively smail.
This is ~u~icul~u;y a iv~l~ Ju~ when the head is not only turn~d to the left or right but is also tilted a little up or down, such as, for example, when nodding to indicate yes. iln this 2180~ 4 context, it is particularly d~iVdll~d!j.lJU:~, according to the invention, if, abûve a certain spring force or extcnsion of the resilient element, the spring force of said element remains essentiallv constant on further ~xt~nsion th~r~of. Resili~nt elem~nts of this typ~ ar~ known per se and can be produced, for example, from wires made of a so-called Nitinol alloy.
Nitinoi is a so-called sup~r-clastic nickel-titanium alloy. Nitinol wires of this type ate knows in orthodontics because of their particular elastic properties and are fitted in the mouth as aids when correcting the position of incisors or molars. Nitinol wires are described in, for example, US-A 4 037 3A)4 and are described more extensively in the literature references cited in column 7 of US-A 4 037 3A'4, which literature references are 10 ill~Ul~Oldl~ i in the present Appliciltion by way of reference.
Nitinol wires are marketed by, amongst other companies, GAC r"~ ",Al Inc., New York, USA and Al p O~ o iù..li~ inc., La Porte, indiana, USA, under the trade names Sentallû-~ and Refiex' ~e~
A;he invention also rclates to an ~ aid provided with a tensioning system 1~ according to the invention.
A~he invention will be explained in more detail below with the aid of an illustrative ,l,o~ ,l shown in the drawing. In the drawing:
Fig. 1 shows a perspective view of a tcnsioning system according to the invention with an outer brace;
A)O Fig. A~ shows a detail of a tensioning systcm according to the invention;
F~g. 3 shows a perspective view of a tensioning systcm according to the invention with an outer brace: in this figure the enciosing tube fûr the tensioning system has been omitted;
Fig. 4 shows a detail of a tensioning systcm according to the invention, showing the A)5 fixing of the tensioning systcm to a neck band;
Fig. 5 shows a detail, partially in cross-section, of the fixing of the coupling means tû the outer bracc; and Fig. 6 shows, in ~ section, a detail of a ~ ;.,ulAulv d iVdu.l~ uus ~mhoflimrAt of the tensioning system according to the invcntiûn; and Figures 7a and 7b show graphs of spring ~ of a hclical spring according to the invention made from Nitinol wire.
Fig. 1 shows a known outcr brace, indicated by '1, with outcr arms 1, to which the i~mcr arms A' are fixcd at 17. Bends are formed in the inner arms ' at 3, the free ends of WO 95/18580 2 1 8 0 1 0 ~ PCT/NL95/00006 said bends being used for fixing the inner arms to the teeth. The outer brace ''1 is pro~ ided.
at its ends which are located outside the p~tient's mouth during use, with U-shaped hooks 7.
The tensioning system according to the in~ ention compnses a helical spring 5, which S at its opposing ends is fixed to one end of cord 11, and, ~cs,~ iv~l~, to one end of cord 1~. The other ends of cords 11 and 1', respecti~ely, are clamped by means of a scr~w 10 in a shoe 9. The shoes 9 are provided with safety hooks 8, which can be coupled to the hooks 7 of the outer brace '21 Fig. 5 shows, in detail, the fixing of a safety hook 8 to a U-shaped hook 7, which 10 is shown partially, in cross-section. The legs of the safety hook are able to spread apart resiliently, so that the linkage is broken if a certain tensile force, for example of 1000 gram, is exerted.
The safety hooks 8 are thus uncoupled if a pull of a certain force is exerted on the outer brace 1.
The spring 5 is fitted in a flexible hube 4, a detailed view of which is shown in Fig.
_.
Fig. 3 shows the tensioning system according to the invention together with an u.L~Odu~iC brace, the tube 4 being omitted in this figure. Fig. 3 clearly shows the arc-shaped guide 13 in the form of a metal strip which has an essentially smooth sliding plane.
'20 Stops 19, in the form of small hubes through which the wireS 11 and 1~ pass, are fixed at the ends of the guide path. Said stops 19 ensure that the spring can not run off the guide path. The guide path 13 having a smooth sliding plane matched to the shape of the spring makes it possible for the spring 5 to be able to be moved smoothly along the guide path without jolts or vibrations. Fig. 3 also shows bush-shaped plugs 18, which can be fitted 25 in the ends of the hube 4. Said p~ugs are provided with l~ ngih~ n~l holes for the wires 10 and 11.
Fig. 2 shows a detailed view of a hube 4 according to the invention. Said hube 4 is formed from a helical spring 15 which is covered on the outside by a covering 14, for e:cample a so-called shrink sleeve. Said covering 14 ensures that none of the patient's hair 3û can get caught between the windings of the helical spring 15. The whole easily adjusts to the shape of the patient's neck.
The tensioning system according to the invention fitted in the hube 4 can, as can be seen from hg. 4, be fL~:ed by means of, for e:sample, a Velcro fastening to a neck band 6, wo 95/18580 Pcr/NL95/00006 218~106 6 which is known per se. Said n~ck band 6 to some extent distributes the pressure over the neck and can easily be replaced when it has becomç soiled.
The way in which the tensioning system according to th~ inYention which is shownin the drawing is fitted on the patient largely UUIIC~ lld~ to the fitting method as described in US-A 3 5~6 035. The inner arms are placed in the mouth, the tensioning system is placed on the neck and the hooks 8 and 7 are engaged on either side of the patient's he~d.
The orthodontist can adjust th~ pre-tensioning of the spring 5 by means of the sews 10 which clamp the cords 11 and 1'' in the shoes 9.
When fitting the tensioning system and the brace, the tube 4 adapts, because of its fiexibility, to the shape of the patient's neck. Pro~iding it is sufficiently flexible, the tube also continues to adjust dunng use to the shapes of the neck, which, or example, is very pleasant when the patient is sleeping.
In Fig. 1, arrows show, ~ y, the flm~tinnin~ of the tensioning system according to the invention. In this figure, the patient is imagined to have tumed his or her head to the right in accordance with arrow R. As a result of this movement, the centre of the spring 5 has moved in accordance with arrow r. The distance r over which the centre of the spring 5 has moved is equal to the difference between the distances b and a, which show the respective distances berween the shoes 9 and stops 18. The entire unit comprising the outer arms 1 of the outer brace ''1, cord 11, spring 5 and cord 1'2, thus forms, aS it were, a "ring" which partially passes through the tube 4, which "ring" turns as the patient's head is turned, whilst the tube 4, which is fixed relatively firmly to the patient's neck, remains in place unchanged. It will be clear that with this ~ l the tensioning force of the spring can remain constant because the spring 5 slides aiong the guide 13 through the tube 4. If the head is turned in a purely rotary movement, R is equal to r.
~5 The friction between, on the one hand, the arc-shaped guide 13 and the resilient element 5 and, on the other hand, between the arc-shaped guide and the coupling e~ement 11, such as a plastie eord, is very small with this ~ , 50 that said frietion has hardly any infiuence on the forees exerted on the teeth. This is highly ,:d~ (,u~ from the standpoint of .,.ll.,,.l.,"l;. ~l",~"l. .AII~I~ and for comfort in wear.
Fig. 6 shows, ~ lly, an r~ Ol~ of the tensionirlg system in which a metal spring 5 is able to move with low friction, without shocks and virtuallysoundlessly, i.e. barely audibly, over a metal guide path 13. To this end, plastic sleeves 30 are fitted around the spring 5 and sieeves 31, which are closed at one end and to which the wo 95/18580 1 8 01 0 6 PCT/NL95/00006 ~= =

cords 11 and 1'' arc also fixed, are fi~ed to the ends of the spring. The sleeves 30, 31 prevent direct metal-on-metal contact and make it possible for the spring to mo~e - smoothiy backwards and forwards along the guide path. Smoothing down the sleeves 30, and preferably also the sleeves 31, somewhat on the side where said sleeves make contact 5 with the guide path 13 prevents a screw movement of the spring with respect to the sleeves 30 from being able to take place, so that said sleeves 30 do not start to move along the spring.
Figs. 7a and 7b show spring . l,~ ~f l "~ of two different helical springs made of Nitinol wire. In these graphs the abscissa shows the elongation ~i in mm, whilst the 10 ordinate shows the spring force F in N. Both springs had an internal diameter of 2.0 mm and an external diameter of '.8 mm. The spring used for Fig. 7a had an unloaded length of 15 mm amd the spring used for Fig. 7b had an unloaded length of ~0 mm. The aws shown on the curves in Figs. 7a ~nd 7b indicate the direction of movement of the spring.
In these graphs an arrow pointing to the left indicates the spring 1,,.,,~ ;f during 15 extension, whilst an arrow pointing to the right indicates thc spring ..l,_. r ~ when the load on the spring is relaxed.
It can be seen that, for the spring in Fig. 7a above a spring forcc of about 3 N (about 300 g) and from an extension of about 30 mm, the spring constant decreases on further extension, which signifies that the gradient of the plot of the spring force against the 20 extension becomes smaller. From an extension of 30 mm, which ...~ to a springforcc of 3 N, this spring can be subjected to substantial additional extensions, for example up to 80 mm, whilst the spring force increases by only about 1 N.
Something similar applies m the case of the spring constant for the spring from Fig.
7b. However, the boundary in this case is at a spring force of about 3.8 N and an e~tension 25 of about 70 mm.
Springs having this type of spring . l.~ , as described above, can be used highly ~Ldv~L~ vu~l~ in a tensioning system according to the invention. After all, a specific spring forcc, which can be utilised for correction of the teeth, has to be achieved with a relatively smail extension of the spring, rclatively little of the freedom of movement 30 over the guide path being lost. If, when certain ulv~.,ul~lL~ are made, such as a nodding movement to indicate yes, the il-Ulllrc-c.. c of the, as it were, "closed ring", has to inease, springs of this type c~m be subjected to a relatively large extcnsion with a relatively small increase in the spring forcc, as a result of which the additional forces wo 95/18580 PCTINL95/OOnO6 2~ 6 8 exert~d on the teeIh r~main limit~d Th~ patient's freedom of mov~ment and the comfort in wear can be appreciably improvcd by this means.
When the pa~i~nt's head makes more complex movements and nodding lllO~
to indicat~ yes, the spring 5 will fr~quently also have to ~xtend in order to make th~se 5 L~u~ a possible. The forces exerted on the teeth will change as a resull, whjch is ad~ers~ for th~ treatm~nt and reduces comfort in wear. This can b~ d or prcv~nt~d by using, as the resili~nt element, an element for which the spring forcc increases only slightly or does not increase at all on further extension of the spring.
It is pointed out that th~ t~nsil~ forces which are to be ex~rt~d on th~ t~eth and are 10 customary and desircd in nrthn~nnrinc are generally less than 500 gram. These tensile forces are frequently 100-150 gram and sometimes 300-400 gram. It will be clear that with such relativelv small forceS the eff~ct of friction can easily b~com~ apparent. Friction must therefore be very low.
If the element used as the resili~nt ~l~ment is an element for which the spring force 15 remains essentially constant after a specific spring force is reached, or fo} which the spring constant decrcases on further extension after a specific spring force or extension is reached, it will b~ possible to take th~ a~u.~ ;n., ~ tensile forces customary in .~,II,n.~ as th~ so-callcd specific spring forc~. Said sp~cific spring force will thcn in gencral be less than 500 gram. D~p~nding on the corr~ction of th~ teeth to b~ carried out and on th~
20 ~ih~ this spring force will frequently be between 100 and 400 to 500 gram. Inpractice, tensil~ forces of 200 or 400 gram ar~ found to be highly a.lv~u.,..~,~o~,i.
As can be s~en from Fig. 1, the sprirlg 5 can move freely to the right or to the left in the Inn~ih~rlin:ll direction of the hube 4. Because the coupling elements 11 and 12 extend ;.,.."..cly from the ends of the spring 5 to the shoes 9 fitted to the hooks 7 and 8 of the 25 outer brace, a maximum freedom of movement for the patient'â head is obtained. After all, the spring can, in principle7 be moved unhindered along th~ entir~ guid~ path. Th~ pati~nt can, thcrcforc, tum his or h~r head frccly and unhindcrcd in a mov~ment of shaking the head to indicate no. With this ,.",~ ", ~ the tensile forces to be exerted on the teeth will remain esserltially constant, until thc spring S or a shoe 9 comcs to rest against a stop 19 30 or, I..a~ iv.,ly, a 5tOp 18. Whcrl, as will prcferably bc thc casc, the rcsilient clcment has a spring constant which decreases after a specific extension or spring forcc is reached, the increasc in the tensile force which occurs on onc side of !he teeth aftcr this contact is made will bc restricted or relatively small. A spring of this type for which the spring constant WO 9S118580 21 8 0 ~ Q 6 PCT/NL9SJ00006 decreases after a specific extension or tensile force is reached also increases the comfort in wear and the freedom of movement with regard to nodding movements of the head to indicate yes7 during which such a spring will necessarily be extended.
It will be clear that man-~ variants of the tensioning system according to the invention S are ~,o.,.,c;v~ , such as, for ~xample:
- the resilient element can be, for example, an elastic band, etc.;
- the guide path can be formed by an arc-shaped strip, a tube, a rail, etc., the important factor here being mainlv that the resilient element can be moved along without jerks;
- cords, cables, strips, etc. can be used as the coupling me~ns;
10 - the flexibility of the tube 4 can also be achieved in some other way than by means of a spiral-shaped winding 15;
- the spiral-shaped winding 15 can be made of metal, plastic and the like. The lighter the weight, the better;
- the guide path 13 can also be made of a plastic, which is preferably wear-reSiStant and causes minimal friction;
- a resilient element ha~ing the resilient special l ..,~ as explained in this ,~rplir ltir~n) such as a helical spring made of Nitinol wire, can also be used as an i~llllJUV~:bl~ tensioning means. Some of the advantages of the invention will then be lost.0

Claims

1. Tensioning system for an orthodontic outer brace, comprising coupling means (11, 12), fixable on one side to the outer brace (21) and fixed on the other side to the resilient element (5), for transmitting a tensile force exerted by the resilient element (5) to the outer brace (21), and comprising guiding means (4, 13) for the resilient element, characterised in that the guide means consist of an arc-shaped guide path (4, 13) along which the resilient element (5) is movable and that the coupling means (11, 12) are connected to one another on said other side via the resilient element (5), in such a way that the resilient element (5) moves along the guide path (4, 13) when the patient turns his or her head.

2. Tensioning system according to Claim 1, characterised in that the guide path comprises a tube (4).

3. Tensioning system according to one of the preceding claims, characterised in that the guide path is flexible, in such a way that the arc shape thereof can be adjusted to the shape of the patient's neck.

4. Tensioning system according to one of the preceding claims, characterised in that the guide path comprises a wire or strip wound to give a spiral-like winding (15).

5. Tensioning system according to Claim 4, characterised in that the outside of the spiral-like winding (15), is provided with a covering (14) which covers the winding.

6. Tensioning system according to one of the preceding claims, characterised in that the guide path comprises an arc-shaped strip (13), preferably made of metal, which has an essentially smooth sliding plane for the resilient element (5).

7. Tensioning system according to one of the preceding claims, characterised in that the spring constant (C) of the resilient element decreases on further extension, preferably from a certain spring force (F) or extension (L).

8. Tensioning system according to one of the preceding claims, characterised in that above a certain spring force or extension of the resilient element, the spring force of said element remains essentially constant on further extension thereof.

9. Tensioning system according to one of the preceding claims, characterised in that the resilient element is a coil spring (5).

10. Tensioning system according to Claim 9, characterised in that the coil spring is made from a Nitinol wire.

11. Tensioning system according to one of the preceding claims, characterised inthat the resilient element (5) is essentially unhindered movable along the entire guide path.

12. Tensioning system according to one of the preceding claims, characterized inthat the coupling means comprise coupling elements (11, 12) continuously extending from the ends of the resilient element (5) to the outer brace (21).

13. Orthodontic aid provided with a tensioning system according to one of the preceding claims.

14. Use of a resilient element according to one of Claims 7-10 to exert a tensile force on an orthodontic outer brace.

15. Use of a helical spring made of Nitinol wire to exert a tensile force on an orthodontic outer brace.