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VOLUME XLV NUMBER 12 653© 2011 JCO, Inc.
EDITORRobert G. Keim, DDS, EdD, PhD
SENIOR EDITOREugene L. Gottlieb, DDS
ASSOCIATE EDITORSBirte Melsen, DDS, DO (Aarhus, Denmark)Ravindra Nanda, BDS, MDS, PhD (Farmington, CT)John J. Sheridan, DDS, MSD (Jacksonville, FL)Peter M. Sinclair, DDS, MSD (Los Angeles, CA)Bjorn U. Zachrisson, DDS, MSD, PhD (Oslo, Norway)
TECHNOLOGY EDITORW. Ronald Redmond, DDS, MS (San Clemente, CA)
CONTRIBUTING EDITORSR.G. Alexander, DDS, MSD (Arlington, TX)Jeff Berger, BDS, DO (Windsor, Canada)S. Jay Bowman, DMD, MSD (Portage, MI)Robert L. Boyd, DDS, MEd (San Francisco, CA)Vittorio Cacciafesta, DDS, MSC, PhD (Milan, Italy)José Carrière, DDS, MD, PhD (Barcelona, Spain)Jorge Fastlicht, DDS, MS (Mexico City, Mexico)John W. Graham, DDS, MD (Litchfield Park, AZ)Robert S. Haeger, DDS, MS (Kent, WA)Warren Hamula, DDS, MSD (Monument, CO)James J. Hilgers, DDS, MS (Mission Viejo, CA)Masatada Koga, DDS, PhD (Tokyo, Japan)Björn Ludwig, DMD, MSD (Traben-Trarbach, Germany)James Mah, DDS, MS, DMS (Los Angeles, CA)Melvin Mayerson, DDS, MSD (Kettering, OH)Richard P. McLaughlin, DDS (San Diego, CA)James A. McNamara, DDS, PhD (Ann Arbor, MI)Elliott M. Moskowitz, DDS, MS (New York, NY)Jonathan Sandler, BDS, MSC, FDS RCPS, MOrth RCS (Chesterfield, United Kingdom)Georges L.S. Skinazi, DDS, DSO, DCD (Paris, France)Michael L. Swartz, DDS (Encino, CA)Flavio Uribe, DDS, MDS (Farmington, CT)
ExECUTIvE EDITORDavid S. Vogels III
MANAGING EDITORWendy L. Osterman
EDITORIAL ASSISTANTHeidi Reese
BUSINESS MANAGERLynn M. Bollinger
CIRCULATION MANAGERCarol S. Varsos
GRAPHIC DESIGNERJennifer Johnson
Address all communications to Journal of Clinical Orthodontics, 1828 Pearl St., Boulder, CO 80302. Phone: (303) 443-1720; fax: (303) 443-9356; e-mail: [email protected]. See our website at www.jco-online.com.
THE EDITOR’S CORNERBut I’ve Always Done It That Way!
We do many things the way we do, in both our per-sonal and professional lives, for no other reason than we were taught to do them that way. I heard a charming illus-tration of this maxim at a banquet during the 2007 Euro-pean Orthodontic Society Congress in Berlin. It went something like this:
A young bride was preparing supper for her new hus-band. Just before placing the sausages in the frying pan, she cut off both ends. When her groom asked her why, she replied, “My mother taught me that if you cut off the ends of the sausages before you fry them, you will have a deli-cious meal. That is how I have always done it.” This expla-nation didn’t really satisfy the husband, so the next time he saw his mother-in-law, he asked her about it. Her reply was the same as her daughter’s: “My mother taught me that if you cut off the ends of the sausages before you fry them, you will have a delicious meal. That is how I have always done it, and that is how I will always do it.” Still skeptical, the husband sought out his bride’s grandmother and asked her about it. The elderly lady looked puzzled, then chuck-led. She led the young man back to his apartment, where she questioned her granddaughter. “You are still cutting the ends off the sausages? Why?” “Because that’s the way the women in our family have always done it,” her grand-daughter replied. “May I see the pan you are using?” the old woman asked. As the young lady brought out her fry-ing pan for her grandmother’s inspection, the old lady roared with laughter. “Oh, my goodness! You are still using my tiny old pan!”
Of course, the only reason the grandmother had ever cut off the ends of the sausages was that she didn’t have a big enough frying pan. It had no effect on the flavor of the outcome.
Once in a while, I find myself doing something in my orthodontic practice simply because “that’s how I’ve al -ways done it”. Take, for example, the exercise of sealing or tying off the jackscrew of a rapid palatal expander (RPE) after the expansion has been completed and transverse treatment goals have been realized. Most of us were taught
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that if we didn’t do that, the expansion screw would “back off” and some of our meticulous ex -pansion would be lost. I know I have followed this protocol for years, ever since the completion of my graduate training, without ever questioning whether there was any evidence to support it.
As it turns out, there is none. In this issue of JCO, Drs. Luis Tomas Huanca Ghislanzoni, Lorenzo Franchi, and the late Tiziano Baccetti present a well-conceived clinical study that tests the old paradigm of sealing off the expansion screw in a simple yet elegant manner. Forty-eight consecutive cases were treated with an RPE. Following active expansion, the twice-daily turns of the screw were discontinued and the appliance was left in place, with no mechanism applied to prevent the screw from backing off. Not wanting to spoil the surprise, I’ll leave it to you to read the entire article for the thrilling conclusion—and a well-thought-out theoretical explanation of why
things turned out the way they did. Suffice to say, the results did not concur with the way we were all taught.
While evidence-based decision making has its detractors, it has gradually become the law of the land in dentistry. There’s a lot to be said for track record, but cold, hard, objective evidence wins the contest every time. “That’s how I’ve always done it” or “That’s how I was taught to do it” is no longer a good enough rationale for any clinical procedure. In this month’s article, Dr. Huanca and colleagues call into question a time-honored, widely accepted “way of doing things” and demonstrate convincingly that conventional wisdom isn’t always correct. Based on their find-ings, I’m going to take a good look at the way I’m doing everything in my practice and make sure there is cold, hard evidence to support my “para-digms”. You can bet that I will not be cutting the ends off my sausages. RGK
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EDITOR’S CORNER
JCO/DECEMBER 2011
VOLUME XLV NUMBER 12 657
The rapid palatal expander (RPE) is widely used to correct maxillary constriction. Clinically,
there are only a few differences among the various expansion protocols, including the number and frequen cy of turns (activation rate) of the midline jack screw for rapid or slow expansion,1,2 the attachment method (banded or bonded acrylic),3 and the decision whether to use deciduous or permanent teeth for anchorage.4
The screw of an RPE is commonly blocked with composite or a stainless steel ligature after the desired expansion has been achieved, the ob jective being to prevent relapse due either to the forces generated by stretched tissues of the en larged maxillary bone trying to return to their previous state5 or to backturning from manipulation by the tongue.6 Little research has been published, however, that might confirm such relapse.
We used a prospective clinical trial and a
theoretical approach to investigate whether it is necessary to lock the screw after active expansion.
Materials and Methods
The prospective clinical trial was performed in Dr. Huanca Ghislanzoni’s private practice. Be cause a statistical power greater than .9 was de sired, a sample size of at least 45 subjects was needed. Fortyeight consecutive patients (21 males and 27 females) presenting with maxillary deficiency, as indicated by a unilateral or bilateral crossbite, were chosen for treatment with rapid palatal expansion. The mean age at the start of treatment was 7.8 ± 1.2 years.
A Hyrax expansion screw* coated with a
© 2011 JCO, Inc.
Locking the Screw after Rapid Palatal Expansion: A Superfluous Procedure?LUIS TOMAS HUANCA GHISLANZONI, DDS, MSLORENZO FRANCHI, DDS, PHDTIZIANO BACCETTI, DDS, PHD
Dr. Huanca Ghislanzoni is a doctoral student, Department of Human Morphology, University of Milan, and Dr. Franchi is an Assistant Professor, Department of Orthodontics, University of Florence, Florence, Italy, and a Thomas M. Graber Visiting Scholar, Department of Orthodontics and Pediatric Dentistry, School of Dentistry, University of Michigan, Ann Arbor; e-mail: [email protected]. Dr. Baccetti, who was killed in a tragic accident in November (see The Editor’s Corner, JCO, November 2011), was a Contributing Editor of the Journal of Clinical Orthodontics, an Assistant Professor, Department of Orthodontics, University of Florence, and a Thomas M. Graber Visiting Scholar, Department of Orthodontics and Pediatric Dentistry, School of Dentistry, University of Michigan.
Dr. BaccettiDr. FranchiDr. Huanca Ghislanzoni
*Part A0620, Leone S.p.A., Sesto Fiorentino, Florence, Italy; www.leone.it.
©2011 JCO, Inc. May not be distributed without permission. www.jco-online.com
JCO/DECEMBER 2011
friction agent was cemented to the first molars of each patient (Fig. 1). A full turn of the screw provided .8mm of expansion. The treatment protocol was the same for each patient: two quarterturns per day (.4mm of expansion), with weekly visits to note progress. The active expansion phase lasted a mean 15 ± 3 days. In each case, when the amount of expansion was judged satisfactory, with a slight overcorrection, a notch was carved with a diamond bur into the lingual surface of the screw spindle (Fig. 2). The notch served as an unambiguous reference point for any backward movement of the screw components, since such movement would cause a displacement of the notch. The screws were not blocked with composite or ligatures.
After an average 5.5 months of retention with passive expanders, the appliances were removed. At the debanding appointment, each screw’s notch position was checked, and the number of reverse turns needed to deactivate the screw was counted to verify that none of the screws had reversed by exactly one or more full turns, which might have created an illusion of stability.
Results
All 48 patients completed the treatment. An average 30 quarterturns were made, resulting in an average screw opening of 6.1 ± 1.2mm. None of the notches was found to be displaced, and the
number of “deactivation” turns matched the number of activations in each subject. Since there had been no relapse in any of the patients, no further statistical analysis of the results was required.
Discussion
Locking the jackscrew in place after achieving the desired rapid palatal expansion is a universal clinical management tip that actually appears to have little substantiation. The resistance force of the maxillary tissues against the expander was studied by Isaacson and colleagues in five patients, using a modified RPE with a dynamometer connecting the expansion screw and the bands on one side of the mouth to an acrylic plate placed against the palatal alveolar process of the opposite side.79 The expansion screw was activated .8mm per complete turn, as in many current RPE designs. In four of the patients, the forces measured by the dynamometer dropped to zero five to seven weeks after the end of active expansion. In the fifth pa tient, for whom the maximum possible daily activations were performed in the clinic, a drop to zero was noted after only five days. This sudden decrease was attributed to backturning of the screw, perhaps caused by masticatory function or manipulation by the patient. In a more recent study, Halazonetis and colleagues measured the contribution of the stretched cheeks in resisting maxillary
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Locking the Screw after Rapid Palatal Expansion: A Superfluous Procedure?
Fig. 1 Rapid maxillary expander cemented to first molars.
Fig. 2 Notch carved in lingual surface of spindle as reference mark to indicate any relapse of expansion screw.
VOLUME XLV NUMBER 12
Huanca Ghislanzoni, Franchi, and Baccetti
expansion; results showed a negligible .6g/cm2 per millimeter of expansion.10
Other factors that could be considered potential causes of backturning are vibrations and lubrication. Vibrations at a particular resonance frequency can cause a screw to unseat. In the mouth, the voice can produce vibrations ranging from 60 to 2,000Hz, with averages of 100Hz for an adult man, 200Hz for an adult woman, and 400Hz for a child.11,12 Although no data have been published on the resonance frequency of an RPE screw system, it seems unlikely that vocal vibrations could affect the stability of expansion treatment.
A lubricant reduces the strength and number of bridges formed between the asperities of sliding surfaces.13 In studies using artificial saliva, friction has been variously found to decrease,14 stay the same,15 or increase16 during orthodontic treatment. Tselepis and colleagues reported a drop in frictional force between stainless steel brackets and archwires of as much as 60% under lubrication with artificial saliva.17 Even this much reduction in static friction would not be enough to allow any screw to turn back, however, as demonstrated by the following theoretical discussion.
Geometrical analysis shows that an RPE screw cannot be unintentionally turned back as long as the slope of each thread does not exceed a critical value of 36.5°. In fact, the slope of the threads is the key factor. Our calculations were based on the specific manufacturing details of the screw used for the present study, but they may be applied to virtually any screw of similar thread
pitch and slope.The Leone A0620 screw has a mean diam
eter of 1.5mm; a full turn provides .8mm of activation (expansion). Assuming the screw of the RPE is centered symmetrically between two metal blocks moving away from each other, this means that for every full turn, each block moves .4mm away from the center. That value also represents the pitch of the screw—the distance between the centers of two contiguous threads as measured along the long axis (Fig. 3A). The slope of the thread (the angle between the thread and a plane perpendicular to the long axis), can be calculated using the equation:
α = arctan ( pitch ) (Eq. 1)
By applying this equation to the A0620 screw, the threadslope angle, α, is shown to be 4.9°.
The forces from the stretched maxillary tissues, acting parallel to the long axis of the screw, may be broken down into two parts (Fig. 3B): F//
(parallel to the threads) and F⊥ (perpendicular to the threads). F// alone could theoretically cause the screw to turn back because it acts as a tangential force, creating a moment around the long axis of the screw. F⊥ is assumed to be the force responsible for frictional resistance to turning.
The force of static friction is calculated by multiplying the normal force by the coefficient of friction, which for stainless steel is about .74.18
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Fig. 3 Screw characteristics and resulting forces. A. Screw pitch and thread slope. B. Direction of forces.
π × diameter
F
Ff
1.5mm
0.4mm α°
F⊥
F//
A B
JCO/DECEMBER 2011
This force, Ff, acts in the same direction as, but in opposition to, F//. If F// is greater than Ff, the screw can turn around its axis; otherwise, it will not move. An angle of 36.5° (the arctangent of .74) is the critical angle at which F// is equal to Ff. Under normal conditions, it is impossible for a shallowerthreaded screw to turn back, because the frictional forces will always be greater than the parallel forces (Fig. 3B).
Projecting the compression force F onto a coordinate system parallel to the slope of the threads, F can now be expressed in terms of components parallel to (F//) and perpendicular to (F⊥) the threads:
F// = Fsin α (a) F⊥ = Fcos α (b)
Ff = μFcos α (c) (Eq. 2)
where α is the slope of the threads and μ is the coefficient of friction. The applied load cannot cause the screw to back out unless the component of the force parallel to the threads is greater than the force of friction:
F// > Ff (Eq. 3)
From the identities in Equation 2, it follows that for the screw to back out, the condition
tan α > μ (Eq. 4)
must be met. For μ to equal .74, α must be greater than 36.5°, which is unlikely with any normal thread design. Alternatively, for α to equal 4.9°, the coefficient of friction would need to be less than .09 in the static case described here.
Conclusion
Our prospective clinical trial and theoretical considerations show that locking the expansion screw of an RPE at the end of active expansion is an unnecessary precaution in most situations. The shallow slope of virtually any expansionscrew threads will prevent relapse of the expansion mechanism. Although our clinical study used a
screw coated with a friction agent, it appears from our calculations that such coatings, as well as the ratchetingtype mechanisms incorporated in many screws, may be superfluous.
REFERENCES
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3. Asanza, S.; Cisneros, G.J.; and Nieberg, L.G.: Comparison of Hyrax and bonded expansion appliances, Angle Orthod. 67:1522, 1997.
4. Cozzani, M.; Rosa, M.; Cozzani, P.; and Siciliani, G.: De ciduous dentitionanchored rapid maxillary expansion in crossbite and noncrossbite mixed dentition patients: Reaction of the permanent first molar, Prog. Orthod. 4:1522, 2003.
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6. Proffit, W.R.; Fields, H.W. Jr.; and Sarver, D.M.: Orthodontic treatment planning: Limitations, controversies, and special problems, in Contemporary Orthodontics, 4th ed., Mosby Elsevier, St. Louis, 2007, p. 286.
7. Isaacson, R.J.; Wood, J.L.; and Ingram, A.H.: Forces produced by rapid maxillary expansion, Part I: Design of the force measuring system, Angle Orthod. 34:256260, 1964.
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9. Zimring, J.F. and Isaacson, R.J.: Forces produced by rapid maxillary expansion, Part III: Forces present during retention, Angle Orthod. 35:178186, 1965.
10. Halazonetis, D.J.; Katsavrias, E.; and Spyropoulos, M.N.: Changes in cheek pressure following rapid maxillary expansion, Eur. J. Orthod. 16:295300, 1994.
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14. Baker, K.L.; Nieberg, L.G.; Weimer, A.D.; and Hanna, M.: Frictional changes in force values caused by saliva substitution, Am. J. Orthod. 91:316320, 1987.
15. Andreasen, G.F. and Quevedo, F.R.: Evaluation of friction forces in the 0.022 × 0.028 edgewise bracket in vitro, J. Biomech. 3:151160, 1970.
16. Stannard, J.G.; Gau, J.M.; and Hanna, M.A.: Comparative friction of orthodontic wires under dry and wet conditions, Am. J. Orthod. 89:485491, 1986.
17. Tselepis, M.; Brockhurst, P.; and West, V.C.: The dynamic frictional resistance between orthodontic brackets and arch wires, Am. J. Orthod. 106:131138, 1994.
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