This document discusses various methods for space closure during orthodontic treatment. It begins by stating that space closure is dictated by treatment objectives and can be achieved through different mechanisms. The goals for any space closure method are then outlined, including differential tooth movement control and producing an optimal biological response. Key determinants of space closure like the amount of crowding, anchorage, and tooth inclinations are also discussed. The document then goes on to compare sliding/friction mechanics versus loop/frictionless mechanics. It provides details on considerations for various anchorage situations and techniques for individual canine retraction. In summary, the document provides an overview of factors to consider for space closure and compares different mechanical approaches.
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Space closure by frictionless mechanics 2 /certified fixed orthodontic courses by Indian dental academy
1. SPACE CLOSURE BY
FRICTIONLESS MECHANICS
INDIAN DENTAL ACADEMY
Leader in continuing dental education
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2. Introduction:
Space closure is an important step in mechanotherapy,
solely dictated by clinical treatment objectives and is
irrespective of method employed
Space closure should be individually tailored based on the
diagnosis & treatment plan
Selection of any method should be based on desired tooth
movement
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3. Goals for any space closure method
Differential space closure capability
Axial inclination control
Control of rotation & arch width
Optimum biological response
Minimum patient cooperation
Operator convenience
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4. Determinants of space closure
Amount of crowding
Anchorage
Axial inclination of canine & incisors
Midline discrepancy & L/R symmetry
Vertical dimensions
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5. Amount of crowding:
Extractions are Usually done to relive crowding
In case of severe crowding anchorage control becomes
very crucial
Maintaining anchorage while creating space for
decrowding is important
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6. Anchorage:
Anchorage classification & concept of differential
anchorage is important.
Using the same mechanics for different anchorage need
limits the results
Reinforcement methods can be used in critical
anchorage situations.
Using a force system determined appliance design can
improve chances of success.
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7. Axial inclination of canines & incisors
Inclination of canine and incisor are particularly important.
When same force and moment applied to a tooth or a group
of teeth with different axial inclination will result in
different type of tooth movement.
Example in case of unfavorable positioned canine(root
mesial crown distal)
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9. Midline discrepancy & L/R symmetry:
Mid line discrepancies with or without an asymmetric
L/R occlusal relationship corrected as early as possible
Asymmetrical forces on L/R could result in unilateral
vertical forces, skewing of dental arch or asymmetrical
anchorage loss.
Vertical dimensions:
Undesired vertical forces may result in ↑ Lower Facial
Height, ↑ interlabial gap & excessive gingival display.
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10. Minor & major cuspid retraction:
Depend upon severity of crowding in anterior segment,
anchorage requirements & axial inclination of canine
• Minor : refers to uncontrolled tipping of canine when 1-2
mm arch length is required per side (lace back)
• Major :controlled tipping or translation of canine when
more than 3 mm arch length is required per side.
• If canine inclination is ideal then translation is preferred
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12. Retraction mechanics divided into
• Sliding (Frictional) mechanics involves either moving
the brackets along the arch wire or sliding the arch wire
through bracket & tube
• Loop (Frictionless) mechanics involves movement of
teeth without the brackets sliding along the arch wire
but with the help of loops
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13. Moderate Anchorage situation
Treatment with 18- slot:
either sliding or loop mechanics can be used.
Single or narrow twin brackets on canine & PM is ideally
suited for use of closing loops in continuous arch wire
Treatment with 22- slot:
As a general rule space closure done in two steps
First retracting the canine usually with sliding mechanics
2nd retracting four incisors usually with closing loop
Enmasse – using Opus or T loop but less than ideal
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14. Maximum Anchorage situations
Treatment with 18- slot:
Friction from sliding is usually avoided, and employing closing
loops preferred.
Anchorage is augmented & anchorage strain is reduced by:
Adding stabilizing lingual arch.
Reinforce maxillary posterior anchorage with Extra-Oral force.
Class III elastics from high pull head gear to supplement
retraction force in lower arch
Retraction of canine independently, preferably using a
segmental closing loop & then retracting incisors with 2nd
closing loop.
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15. Maximum Anchorage situations
Treatment with 22- slot:
Like 18 – slot Anchorage is augmented & anchorage strain is
reduced
Canine can be retracted with sliding by
Reinforcing posterior anchorage with extra oral force
Application of extra oral force directly against canine
to slide them posteriorly.
Use of segmented arch mechanics for retraction
Segmented arch mechanics for tipping/ uprighting
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16. Minimum Anchorage situations
Requires anchor control, to reduce incisor retraction by:
By incorporating as many teeth in anterior segment
Locating the extraction site more posteriorly.
Placing active lingual torque in incisor section of archwires
To breakdown posterior anchorage(moving one tooth a time)
Use of extra-oral force (face mask)
Use of implants/ onplants to protract posteriors.
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17. Retraction methods:
1. Staged approach:
Methods of canine retraction:
Friction
Frictionless: Paul Gjessing spring, Burstone T loop,
Delta loop, L loop, Omega loop
Extra oral: Head gear - Four hooked for both the arches
Other methods:
Retraction using Rare earth magnets
Rapid canine retraction through Distraction of PDL
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18. Staged approach:
Methods of en-masse retraction of four incisors:
Friction
Frictionless : P.G spring, Burstone T loop, Delta loop,
L loop, Retraction utility arch,
Omega loop arch wire or
Closing loop arch wire
Extra oral : Head gears
Intrusion & retraction of four incisors:
Burstone three piece intrusion arch
Rickets Retraction & intrusion utility arch
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19. 2. Enmasse retraction of six anteriors:
Friction
Frictionless – Closing loops,
Burstone T loop continuous arch wire,
Opus loop (Siatkowaski)
Simultaneous retraction & intrusion of six anteriors:
K - Sir Arch
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20. Sliding / Friction Mechanics:
Tooth is retracted or slides through the arch wire, it
involves either moving the brackets along the arch wire or
sliding the arch wire through bracket & tube.
It is used for both individual canine and enmasse
Retraction
Friction is present due to surface irregularities of arch wire
and bracket
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21. Various methods used:
Elastic modules with ligature wire
Elastomeric chains
Stainless steel
Closed coil springs
NiTi
Co-Cr-Ni
J hook head gear
Mulligan V bend sliding mechanics
Employing tip-Edge brackets on canines.
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22. Advantages:
Minimal wire bending time
More efficient sliding of arch wire through posterior
bracket slots
No running out of space for activation
Patient comfort
Less time consumption for placement
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23. Disadvantages of sliding mechanics:
1. Variable force.
2. Confusion regarding ideal force levels.
3. E-chain absorbs water and saliva when exposed to oral
environment causing degradation of force by 50%-70% by
the 1st day.
4. Excess Stretching of E-chain causes breakdown of internal
bond leading to permanent deformation.
5. Tendency of overactive elastic causing initial tipping & inadequate
rebound time for uprighting if forces are activated too frequently
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24. Disadvantages
6. Staining of E-chain
7. Dependent on patient cooperation in case of elastic bands
8. Due to friction and binding between bracket and arch wire
applied force should be higher than the required optimum force
because of decay in force
9. Generally slower than loop mechanics due to friction
Due to all these problems in friction or sliding mechanics,
frictionless mechanics stands in better position for retraction, as
monitoring of optimum force can be done effectively and it is
active for a longer duration of time.
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25. Loop / Frictionless Mechanics:
Loop (Frictionless) mechanics involves movement of teeth
without the brackets sliding along the arch wire but with the
help of loops
Force generated intrinsically by arch wire
By incorporating loops in arch wire
Energy is stored in loops and release it in slow and
continuous fashion
There is no friction between archwire and bracket
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26. Biomechanics of frictionless mechanics:
The teeth in an arch wire will invariably assumes the
passive position of the arch wire.
When a bend is placed in the middle of the archwire and
engaged into brackets two equal and opposite moments are
produced
When offset bend is placed differential moments are
produced. (as anchor bend in Begg technique.)
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27. Biomechanics
Greater clockwise moment
(extrusion) in posterior
segment (near to the v- bend)
& smaller anti-clockwise
moment (intrusion force) in
anterior segment (away from
the v- bend) is produced.
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28. This same principles apply in Frictionless mechanics
where instead of a bend a loop is placed in the wire.
Bends are placed on the mesial & distal legs of loop, called
Alpha (α) & Beta (β) bends respectively.
These bends produce Alpha and Beta moments when wire is
placed into bracket
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29. If β moment > α moment
Biomechanics
anchorage enhanced by mesial root movement of
posterior segment
posterior extrusion & anterior Intrusion
If α moment > β moment
anchorage of anterior segment is increased by distal root
movement
anterior Extrusion & posterior Intrusion
If both equal
no vertical force
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31. Biomechanics
Moment is determined by the loop design
Activation of loops produces the force in frictionless
mechanics.
Activated by pulling the distal end of wire through molar
tube and cinching back or by soldering a tie back mesial to
molar tube on archwire
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32. Biomechanics
Moment to force ratio (M/F) determines the type of tooth
movement.
Moment to force ratio for various tooth movements:
M/F Ratio
Tooth movement
5:1
-
Uncontrolled tipping
8:1
-
Controlled tipping
10 : 1
-
Translation
>10 : 1
-
Root movement
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33. Biomechanics
According to Charles Burstone - moment to force ratio for
translation is about 10:1.
A regular 10mm high vertical loop offers a M:F ratio of
only 3:1 when it is activated by 1mm.
To get M:F ratio of 10:1, activation should be reduced to
0.2mm, but the force level is not sufficient for retraction
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34. Biomechanics
M/F could be increased by (Burstone & Koenig)
By ↑ vertical dimension of loop (but it has limitation as
available space in the vestibule)
↑ horizontal dimension in apical part of loop
↑ Apical length of the wire
Helix incorporation
Angulations of loop legs
↓ inter bracket distance
Positioning loop close to tooth to be retracted bodily
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35. Biomechanics
The most effective way to increase M:F ratio is placing
Pre Activation Bends Or Gable Bends.
These bends can be placed within the loops or where loop meets
the arch wire.
As we try to engage the wire into bracket we pull the horizontal
arm of the loop down producing a moment called the activation
moment and the loop is said to be in NEUTRAL POSITION
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36. Biomechanics
The M:F ratio increases as spring gets deactivated as the
space closes.
Sequence of tooth movement with changes in M/F ratio:
Controlled tipping (8:1)
Translation (10:1)
Root movement (12:1)
So spring should not be activated too frequently
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37. SPACE CLOSING LOOPS
Design considerations:
Closing loop arch wires should be fabricated from rectangular
wire to prevent wire from rolling in the bracket slot
The performance of the loop, from the perspective of
engineering theory, is determined by 3 major characteristics
1. Spring properties
2. Moment it generates
3. Its location
[William. R. Proffit]
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38. 1. SPRING PROPERTIES
The amount of force it delivers and the way the force changes
as the teeth move.
It is determined almost totally by the
Wire material - Stainless steel
- Beta-Titanium
Size of the wire
Distance between points of attachment
distance between bracket
amount of wire incorporated
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39. Changing the size of the wire produce largest change in
its characteristics, but the amount of wire incorporated in
the loop is also important
[William. R. Proffit]
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40. 2.Moment it generates
To close an extraction space while producing bodily tooth
movement closing loop must generate not only closing
force but also appropriate Moments to bring the root apices
together
This requirement to generate a movement limits the
amount of wire that can be incorporated to make a closing
loop springier, because if the loop becomes too flexible, it
will be unable to generate the necessary moments
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41. Loop design is also affected.
Placing some of the wire within the closing Loop in a
horizontal rather than vertical direction improves its ability
to deliver the moments needed to prevent tipping.
To generate appropriate moments additional moments must
be generated by Gable bends
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42. 3.Its location:
Its location is very important for its performance in
closing space.
As gable bends are incorporated, the closing loops
functions as the V bend in the arch wire. Effect of V bend
is very sensitive to its location
There can be 3 locations of V bend
1.Equal distance
2.Closure to anterior
3.Closure to Posterior
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43. If it is in the center of the span a V-bend produce:
Equal forces and
Equal couples on the adjacent teeth
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44. If it is one-third of the way between adjacent brackets,
the tooth closer to the loop - extruded &
moment - root toward the V-bend,
tooth farther away - intrusive force but no moment
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45. 4.Additional design principle
Fail safe: this means that, although a reasonable range of
action is desired from each activation, tooth movement
should stop after that, even if patient does not come for
scheduled appointment.
Design should be as simple as possible
During activation of loop it is considered more effective
when it is closed rather than opened
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47. INDIVIDUAL CANINE RETRACTION:
It is important to do individual canine retraction in
maximum anchorage cases.
Correct positioning of the canine after retraction is
imperative for function, stability and esthetics
This requires the creation of a bio mechanical system to
deliver a predetermined force and a relatively constant
moment-to-force ratios in order to avoid distal tipping and
rotation.
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48. For translation of canine :
The displacement of canine depends on the relationship
between the line of force and the center of resistance (CR)
Application of force through CR.
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51. Anti-tip and anti-rotation moment-to-force conditions
necessary for translation of canines with average dimensions.
Anti-Tip:- 11:1 Anti-Rotation:- 4:1
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55. T-LOOP SPRING:
(BURSTONE/AJO/1976)
Burstone called it the Attraction Spring
used for:
Canine Retraction - severe crowding cases and
high anchorage (group-A) cases.
Enmasse Retraction - four incisors after canine retraction
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56. T-LOOP SPRING:
Wire selection for loop:
18- slot: 16 x 22 SS or 17 x 25 TMA
22- slot: 18 x 25 SS or 19 x 25 TMA
Base arch wire: 21 x 25 in SS
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57. Neutral Position:
Activated position:
The pre-activated spring with the anti tip (M/F- 11:1) and anti
rotation (M/F- 4:1) is placed
Activated by pulling it and giving a distal cinch back.
Activation on insertion is 6- 7mm
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59. Activation on insertion is 6-7mm
The M/F ratio is 8:1 – controlled tipping
Now as the tooth moves the activation reduced to 4mm the
force is reduced.
M/F ratio is further increased to 10:1 - bodily movement
The activation is reduced to 2mm – force is further reduced
M/F ratio increased to 12:1 – root uprighting
So spring should not be activated too frequently
Spring usually activated every 4-6 weeks
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60. Composite T loop attraction spring:
Composite TMA 0.018 - 0.017 x 0.025 in retraction spring.
A 0.018 in round T spring is welded directly to a 0.017 x
0.025 in base archwire.
Used in the segmented arch technique for both canine and
enmasse retraction.
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61. CUSPID RETRACTOR:
(RICKETT’S/AJO/1976)
Developed by Ricketts in Scotland in 1976.
Rate of canine retraction by Ricketts was 1.38mm/month
Additional effects:
- Mesial crown tipping
- Disto-palatal rotation
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62. POUL GJESSING CANINE RETRACTION
SPRING:
(P.GJESSING/AJO/1985)
. Poul Gjessing of Denmark 1985
. The spring is constructed to resist rotational and tipping
tendencies during retraction
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63. Loop Configuration:
made from: 016 x 022 in SS wire.
predominant element - OVOID DOUBLE HELIX LOOP
extending 10 mm apically, and 5.5 mm in width.
smaller occlusal loop - 2 mm diameter, incorporated to lower
the levels of activation.
Anti-tip bend (Alpha) 15˚.
Beta-bend 12˚ for II premolar,
30˚ for I molar.
Anti rotation bend 35˚.
Distal sweep for molar.
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64. PG CANINE RETRACTION SPRING
35º
Anti rotation bend
5.5 mm
Apical loop
30º
15º
Beta bend
Anti tip bend
12º
2 mm
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Occlusal loop
65. Spring design:
Ovoid Double Helix Loop - reduce the load deflection of
the spring
Placed gingivally - activation will cause a tipping of the
short horizontal arm (attached to the canine)
In a direction that will increase the couple acting on the
tooth.
Smaller loop - occlusally - lower levels of activation on
insertion in the brackets in the short arm (couple)
Formed so that activation further closes the loops.
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66. sweep in the distal leg - eliminates undesirable ß moments
acting at second premolar bracket
(which tend to move the root apex too far mesially)
Activation:
By pulling the distal, horizontal leg through the molar tube.
Force level of approximately 160 gm is obtained when the
two sections of the double helix are separated 1 mm.
Activation is repeated every 4 weeks, and the canine is
expected to undergo approximately 1.5 mm of controlled
movement with each activation.
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68. inserted into buccal and gingival tubes, which are part of
the molar and canine brackets
special canine brackets
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69. Spring design:
similar to traditional retraction springs except for the extra helix in the
anterior (a) portion.
helix, in conjunction with the gables placed in the posterior (b) legs of
the spring, provides the required couple "counter-moment" for the
moment of the force
allows for the translation of the canine or molar during space closure.
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70. • Three angles in the spring to consider
• Ø1 and Ø2 - bends posterior & anterior to contraction helices
• Ø3 - angle of the anterior leg of the helix.
Mandibular model
• Ø1
Ø2
• 45°
45°
• 45°
45°
• 45°
45°
Ø3
0° - Anterior retraction
15° - Reciprocal attraction
30° - Posterior protraction
Maxillary model
• Ø1
• 45°
• 45°
• 45°
Ø3
15° - Anterior retraction
30° - Reciprocal attraction
45° - Posterior protraction
Ø2
45°
45°
45°
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71. NITI CANINE RETRACTION SPRING:
(Yasoo Watanabe, JCO/2002)
Made from .016" ×.022" Titanal wire, with anti-tip and antirotation bends incorporated in closing loop.
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72. Clinical implications:
Major advantage of this spring is the ability to use it
without a preliminary leveling stage,
Because it can simultaneously retract the canines and level
the posterior teeth.
Its light, continuous force allows an activation of as much
as 10mm to complete canine retraction without reactivation
of the closing loop.
Spring provides continuous forces and moments over a
broad range of activation.
And the closing force can be maintained within normal
biological and physiological limits.
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74. EN-MASSE RETRACTION:
Retracting group of teeth together as a single unit.
Can effectively be employed in moderate and minimum
anchorage cases
Simultaneous intrusion and retraction of the anterior teeth,
maintaining torque control may also be employed
En-masse retraction is done with a continuous arch wire with
one closing loop each side distal to cuspid.
Differential force technique and location of loop can be placed
depending on the type of anchorage.
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75. VARIOUS RETRACTION ARCHWIRES:
Various loop designs are available for retraction
All are having pre-determined vertical heights
Ranging from 7-10mm in vertical direction to keep it
closure to center of resistance of tooth
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76. OPEN VERTICAL LOOP:
Originated by Dr. Robert W. Strang (1933).
Used for retraction of anterior teeth
CLOSED VERTICAL LOOP:
Only being difference is horizontal overlapping.
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77. BULL LOOP:
- Dr. Harry bull (1951)
Introduced a variation of standard vertical loop
Loops legs were tightly abutting each other
He recommended that these loops should be made from
.0215 x .025 stainless steel
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78. VERTICAL OPEN LOOP WITH HELIX:
Dr Morris Stoner
Main purpose is to increase the working range
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79. OMEGA LOOP:
As mentioned by Dr Morris Stoner
Loop named because of resemblance to the Greek letter ‘omega’
The loop is believed to distribute the stresses more evenly
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80. CLOSED VERTICAL LOOP WITH HELIX:
(MORRIS STONER/1975)
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81. DELTA LOOP:
It was described by Dr. Proffit.
Wire configuration:
0.018 slot - 16 x 22 inch
0.022 slot - 18 x 25 inch
Approximately 200 angulations on either side
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82. T-LOOP FOR ENMASSE RETRACTION:
Utilizes loops for space closure for
1.Anterior retraction
2.Symmetric space closure
3.Posterior protraction
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84. ASYMMETRICAL ‘T’ LOOP:
- JAMES. J. HILGERS (JCO/1992)
made of .016“ x 022" TMA (for .018" brackets) or
.0l9“ x 025" TMA (for .022" brackets),
with 5mm vertical step,
2mm anterior loop, and 5mm posterior loop.
archwire should have - exaggerated reverse curve of Spee
& strong distal molar rotation
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85. Pre activation of Asymmetric "T" loop:
A. Short mesial loop compressed
B. Long distal loop opened.
C. Loop after pre activation.
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87. Broussard combination closing and bite opening loop
with step between anterior and posterior segments.
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88. Hilgers modification with reduced loop size for patient
comfort and crossed "T" for greater mechanical
efficiency.
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89. Mushroom loop:
Apical addition of wire in Archial configuration
More patient friendly- reduces the horizontal part of wire
near vestibule
Beta-titanium CNA M loop- 0.017 x 0.025 in
Activation up to 5 mm
Reactivation- every 6-8 wks
Bypass premolars - ↑ IBD
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90. Preformed M loop space closing archwires:
Pre activation- separating the legs by 3mm.
Gable bends - mesial to increase anterior moment
- distal to increase anchorage moment
Torque in distal leg eliminated - wire passive in 3rd order in
buccal segment
Loop reactivated until there is at least 3 mm of space closure
After space closure, wire left in mouth for 1-2 visits- root
uprighting
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91. Double keyhole loop:
Roth treatment mechanics
Introduced by John Parker - 0.019 x 0.026 in
Concept:
Complete space closure with one set of archwires
Allows operator to select how space will be closed
Activation- cinching wire distal to last molar tube, activated
every 3-4 weeks
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92. POUL GJESSING RETRACTION ARCH:
- P.GJESSING (AJO/1992)
The PG retraction spring can be used as a module for
controlled retraction of both canines and incisors.
The suggested horizontal force - 100 gm for incisor
retraction
The incisor segment intrusion is induced with a magnitude
of 10 to 25 gm on each side between subsequent
activations
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93. Design:
Similar to canine spring with
some modifications.
Includes vertical slot in the lateral
incisor bracket.
750 bend 3mm mesial to the helix
to be inserted in the vertical slot
Activated by pulling distal end
separating the double helix and
producing 100gms force.
Activated every 4-6 weeks
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94. OPUS LOOP:
- RAYMOND.E.SIATOWSKI (AJO/1997 )
Used for en-masse retraction of all six anterior Teeth
Wire sizes: 0.016 X 0.022 S.S, or 0.018 X 0.025 S.S. wire.
0.017 X 0.025 inch TMA
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95. Development of opus loop:
M/F required for translation
Individual teeth: 7.1-10.2 mm
Groups of teeth: 8.0-9.1 mm
Most closing loops have inherent M/F 4-5 mm or less
To achieve net translation, need to add residual moments
Gable bends anterior & posterior
Posterior gable bend & anterior wire-bracket twist
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96. Development of opus loop:
Disadvantage of gable bend:
Cycle of Tipping- translation- uprighting (lower Young's
Modulus materials go through fewer of these cycles for a
given distance of space closure).
Correct magnitude of residual moments are difficult to
achieve
Changing areas of stress distribution in the pdl may not
yield most rapid, least traumatic method of space closure
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97. Development of opus loop:
Study: design and verify loop design capable of delivering
M/F inherently without adding residual moments.
Castigliano’s Theorem: to derive M/F ratio in terms of
loop geometry.
Using Castigliano's theorem, and refined, using FEM
simulations, and verified experimentally a new design, the
Opus Loop was developed.
capable of delivering a target M/F within the range of 8.09.1 mm inherently, without adding residual moments.
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98. Advantages:
more precise force systems with non varying M/F can be
delivered
Groups of teeth therefore can be moved more accurately
en masse space closure with uniform PDL stress distributions more rapid tooth movement with less chance of traumatic side
effects
neutral position is the same as the inactivated position - allows
known forces systems to be applied to the teeth
Disadvantages:
loops must be bent accurately to achieve their design potential.
All the dimensions are critical to the performance of the loop
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99. TRANSLATION ARCH:
- ROBERTO MARTINA (JCO/1997 )
kind of utility arch - simultaneously retract, torque, and intrude
or control the extrusion of the maxillary incisors.
made of .016" × .022" TMA for .018" bracket slots
anterior segment inserted into incisor brackets, and
two buccal segments into gingival first molar tubes
Two loops - connect the anterior and posterior segments
- extended as far vertically as possible
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100. A distal activation of 2mm on each end of the arch will produce
the 100g of horizontal force needed for incisor retraction
To achieve a moment-to-force ratio of 10, placing a 3rd-order
activation (root-palatal torque) in the anterior segment of the
arch.
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101. 3rd-order activation should produce an intrusive force of
about 20g on each molar.
Extrusive force exerted on the anterior teeth.
To compensate this side effect - tipback / arc (preferably)
bent into each buccal segment to produce an intrusive force
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102. K-SIR ARCH:
- VARUN KALARA(JCO/1998)
K-SIR: Kalra Simultaneous Intrusion and Retraction archwire
continuous .019" X .025" TMA archwire
with closed 7mm X 2mm U-loops at the extraction sites
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103. To obtain bodily movement and prevent tipping of the teeth
into the extraction spaces, a 90° V-bend is placed in the
archwire at the level of each U-loop
Centered 90° V-bend creates two equal and opposite
moments that counter tipping moments produced by
activation forces.
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104. Off-center 60° V-bend placed about 2mm distal to U-loop.
Off-center V-bend creates greater moment on molar, increasing
molar anchorage and intrusion of anterior teeth.
20° anti-rotation bends placed in the archwire just distal to U-loop
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105. A trial activation of the archwire is performed outside the mouth
trial activation releases the stress built up from bending the wire and thus
reduces the severity of the V-bends
Neutral position of loop
determined with mesial and
distal legs extended horizontally.
In neutral position, loop is
3.5mm rather than 2mm wide.
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106. The archwire is inserted into the auxiliary tubes of the first molars and
engaged in the six anterior brackets
Second premolar bypassed - ↑ IBD
First molar and second premolar are connected by segment of
.019" X .025" TMA wire
It is activated about 3mm, so that the mesial and distal legs of the loops
are barely apart
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107. archwire exerts 125 gm intrusive force on anteriors & similar amount of
extrusive force distributed between two buccal segments
archwire should not be reactivated at short intervals, but only every
six to eight weeks until all space has been closed.
Advantages:
Simplicity of design- ease of fabrication
Comfortable to the patient
TMA- low forces, low LDR, long range of action
En masse retraction- Shortens treatment time- prevents appearance of
unsightly space distal to incisors.
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108. CONCLUSION
A good understanding of mechanics is required
when using retraction loops or springs, because
minor errors in mechanics can result in major
errors in tooth movement
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