|Year : 2022 | Volume
| Issue : 1 | Page : 14
MHM bracket design on the path of Dr Andrews of true straight wire technique, prototype study design
Mohamed Abdelaal Elkolaly1, Hasan S Hasan2, Manal Y Foda3
1 Department of Orthodontic, Royal Dental Center, Alexandria, Egypt
2 Department of Orthodontic, Khanzad Teaching Center, General Directorate of Hawler-Ministry of Health, Erbil, Iraq
3 Department of Orthodontics, Faculty of Oral and Dental Medicine, Cairo University, Cairo, Egypt
|Date of Submission||19-Sep-2021|
|Date of Decision||24-Oct-2021|
|Date of Acceptance||23-Nov-2021|
|Date of Web Publication||04-May-2022|
Mohamed Abdelaal Elkolaly
Department of Orthodontic, Royal Dental Center, Alexandria
Source of Support: None, Conflict of Interest: None
OBJECTIVE: The authors invented an innovation in the bracket design; that targeted to fulfill the aim of Dr. Andrews for a true straight wire technique.
MATERIALS AND METHODS: The use of the ball and socket design together with the ability to relocate the position of the slot in three dimensions enhances the control and precision of individual teeth.
RESULTS: The revolutionary bracket eliminated any wire bending in the initial, intermediate or finishing stages of fixed orthodontic treatment. This was achieved together with complete 3D control on individual teeth positions to achieve the finest occlusion for individual patients.
CONCLUSIONS: That system allowed for a true straight wire mechanics with no wire bending. The design could be used labially or lingually without the need of indirect bonding techniques. Additionally, any adjustments could be performed intraorally with simple pressure.
Keywords: Andrews, bracket design, prototype, straight wire
|How to cite this article:|
Elkolaly MA, Hasan HS, Foda MY. MHM bracket design on the path of Dr Andrews of true straight wire technique, prototype study design. J Orthodont Sci 2022;11:14
|How to cite this URL:|
Elkolaly MA, Hasan HS, Foda MY. MHM bracket design on the path of Dr Andrews of true straight wire technique, prototype study design. J Orthodont Sci [serial online] 2022 [cited 2022 Aug 19];11:14. Available from: https://www.jorthodsci.org/text.asp?2022/11/1/14/344728
| Introduction|| |
The introduction of straight wire appliance by Dr. Andrews was a revolutionary step in the era of modern orthodontics; aiming to eliminate wire bending needed in the Edgewise appliance. His target was to introduce an easier way for treating patients and facilitated achievement of the best finishing results. Unfortunately, that aim was not fulfilled completely; owing to errors in bracket placement in the conventional manual bonding techniques and individual 3D teeth positioning. Rebonding of the fault bracket or adding finishing bends, esthetic bends or segmentation of the archwires with vertical elastics compensated these errors in the finishing stages. Additional major cause that avoided the achievement of true straight wire treatment was the individual differences between subjects regarding teeth sizes, shapes and crown-root angles. Even if the brackets were bonded in the correct position in every individual, not all subjects will reach satisfactory results without addition of wire bends and/or vertical elastics.
To solve all these problems, introduction of semi-custom and fully custom-made prescriptions were suggested. Appearance of revolutionary prescriptions as MBT of McLaughlin, Bennett and Trevisi was one of these evolutions. They aimed to provide the clinician with a new prescription to reach the best goals of treatment. They created even sub-prescriptions for individual variations as the different options regarding the canines' torque. ORMCO Company with the introduction of DAMON system performed the same regarding varieties of sub-prescriptions to meet the individual variations. Although, nevertheless the clinician needs to be optimistic in selection of the proper prescription for the specific patient or else he will face the need for complex finishing mechanics or acceptance of less-than-ideal results.
The latest advances to solve that problem of “complex finishing mechanics” were introduced with fully custom-made brackets. ORMCO Company introduced INSIGNIA system, which was a fully costumed appliance, especially made for a particular individual. That nearly eliminated the complex finishing procedures, but on the expense of increased fees of the appliance more than three times the standard appliances. Together with the probability of faulty measurements and/or bonding process that still necessitated some finishing adjustment and/or rebonding of certain brackets.
Currently, the research trials were directed toward a fully machined custom-made bracket with less financial and more accurate properties. From this point, the authors managed to design a revolutionary bracket design to be incorporated into the new fixed orthodontic appliances. That was designed to avoid the prominent faults of prescription design, bracket position and rebonding steps. The concept was to return to the classical design of straight wire concept by designing a standard type of appliance for every patient to decrease the financial load on the clinicians. The MHM bracket was designed to fully accept modifications according to the individual case inside the oral cavity. This in turn will overcome any error occurred into the bonding process and any individual tooth variations. Through these incredible modifications, a true straight wire concept will be introduced with full 3D control on first, second and third-order movements. Furthermore, it will be compensated into this standard bracket within the patient's mouth that eliminates any need for complex machining and decreased the total cost on the clinician.
| Materials and Designing|| |
The slot mechanism
The bracket design consisted of a slot to receive the wire, with a passive sliding door to hold it in place in a passive self-ligation phenomenon [Figure 1]. The slot was designed to present 0.018” by 0.025” measurements. Those measurements allow for full engagement archwire to be used. While in the same time allowed for lower gauge wires use to avoid heavy forces on the periodontium. The slot was manufactured from Stainless-Steel alloy, with the corners flared and rounded to facilitated sliding mechanics. The surface was laser polished to allow for the least possibility for binding or friction with the used wires [Figure 1]., The sliding door has an eyelet on top to facilitate opening and closure by dental explorer [Figure 2].
The slot mechanism has posteriorly-located tie wings to allow for precise wire tying at the finishing stages for optimum tooth control. If the clinician was trying to force a heavy archwire into the slot, the elastic ties will demonstrate tension. That protected the bracket from frequent debonding and in the same time avoided unnecessary heavy forces. Heavy forces are unfavorable and lead to massive biological and mechanical drawbacks. An example of biological deleterious effect of heavy forces was root resorption. For the mechanical disadvantages, heavy forces lead to Roller-Coaster Effect and bowing of arch wires together with bite deepening anteriorly and bite opening in the premolars area [Figure 3].
The ball mechanism
The metallurgy of the balls was of Stainless-Steel alloy. If we examined the types of joints in the engineering fields, we easily figured that the ball and socket joint was the only design to allow almost 360° movements in all three planes of space X-Y-Z., The body of the bracket was designed to exhibit ball and socket joint phenomena. The internal ball was attached to the slot mechanism. Together with the external socket attached to the base mechanism [Figure 4]. The internal ball is able to rotate 3D within the confinements of the external socket to allow for tipping, torqueing, rotational and combined effects of the previous movements. The ball and socket are fixed together by locking pins. Those pins could be removed to allow the ball to rotate freely within the confinements of the socket, and then the pins were to be attached again. Both the ball and the socket had graded marks vertically and horizontally. Each mark presented 5 degrees change in position on the X and the Y axes. That allowed for precise knowledge of the changes happened before reattaching the locking pins again to secure the mechanism [Figure 5].
|Figure 4: The way of attachment between the slot mechanism, the ball-and-socket mechanism and the base mechanism|
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|Figure 5: The ball-socket mechanism showing red and blue grading marks together with the two locking pins|
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The base mechanism
The base system was produced from Stainless-Steel alloy. The base mechanism was composed basically of two sheets. The first sheet was attached the socket with 4 anchor pins projecting from the socket base. Those anchor pins have design of Press-Snap-Button to allow for secure holding [Figure 6]. The second sheet was attached to the tooth structure by the meshwork and has vertical and horizontal hole-rows to receive the anchor pins [Figure 7]. Other sheets of 0.05 mm thickness each could be added between the two basic sheets to allow for in-out movements [Figure 8]. The basal sheet that was attached to the tooth had an open box configuration to receive the added sheets within and avoid any dislodgement of the ball mechanism by sheer or masticatory forces.
|Figure 6: The anchor pins with Press-Snap-Button design fitting four crossing rows of receiver holes|
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|Figure 7: The meshwork of the tooth-sided basal sheet to be bonded onto enamel|
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|Figure 8: Added sheets of 0.5 mm could be included between the two main basal sheets to facilitate inward-outward movements|
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- The bracket has been provided with a prescription as any other system according to the clinician preferences. If any further adjustments were to be included, the following steps should be followed.
- First order movements:
- Alignment (in-out) movements: Using the base mechanism: If the clinician was to adjust the alignment of a particular tooth, all he had to do was to detach the bracket basal sheet from the tooth basal sheet and add another sheet in-between. Each added sheet was 0.5 mm in thickness and this pushed that particular tooth inward by 0.05 mm.
- Rotational movements: Using the ball mechanism: When a change in rotational movement was required, the clinician had to remove the horizontal locking pin and rotate the inner ball around the vertical pin as required, then reattach the horizontal locking pin again.
- Second order movements:
- Levelling (up-down) movements: Using the base mechanism: When levelling was needed, the orthodontist was to detach the base system and move one from the other vertically using the anchor pins as a guide. Each pin slide in a new hole is 0.5 mm vertical adjustment.
- Tipping (root M-D angulation) movements: Using the ball mechanism: Detaching the two locking pins from the ball system, allowed the operator to rotate the slot to adjust the root angulation mesio-distally before reattaching the pins again. The ball has grades that indicated 5 degrees change of tipping for each mark.
- Third order movements: Torquing (root B-L inclination): Using the ball mechanism: Rotating the ball system vertically after removing the locking pins allowed for inclination adjustments. Each mark on the ball indicates a 5 degree change in that direction.
- Combination of movements:
- If a particular tooth was required for a complex 3D adjustment, the professional personnel was to combine the use of ball system adjustments vertically, horizontally and torsionally, together with sliding the basal sheet system sagittally and coronally to have 100% control over the required 3D movement.
- For example, moving the ball vertically changed the torque but also changed the levelling of the tooth. Hence to cancel that effect, the downward sliding of the base system cancelled any unwanted levelling changes.
Suggested sequence of arch wires
This revolutionary system was designed to resolve most of the conventional problems in the previous bracket designs. The authors recommended a light force technique, with only NiTi (Nickle-Titanium) wires to keep all the forces below the level of the deleterious effects; starting by 12 NiTi arch wires and increasing sequentially. With addition of any recommended corrections of the slots 3D every visit, the range of pressure remained within biological limit.
In the opinion of the authors, a non-extraction case could be finished with only 0.016 × 0.022 NiTi arch wires. And all the extra movements compensated by simple brackets adjustments. For the extraction cases, the clinician could reach 0.018 × 0.025” arch wires to gain maximum control.
| Discussion|| |
Since the era of straight wire appliance introduced by Dr. Andrews, many systems of brackets introduced to facilitate easier treatment with maintenance of quality of the results. Variations in the prescriptions consumed many efforts in the research fields.
Besides, indirect bonding techniques were introduced to allow for precise bracket positioning., Also, Kesling wax setups performed for indirect bonding allowed for changes in the default prescriptions to meet individual variations. The introduction of semi and fully costumed brackets was a further step toward precise finishing and easy treatment of the cases.,
The previous trials had common problems; such as the increased cost of manufacturing for semi or fully customized brackets and lab steps with an additional factor of technician qualification to provide a perfect set for the indirect bonding techniques.,, Together with the ordinary inaccuracies performed in bracket placement even by the cleverest clinicians.,,
Rebonding is one of the furious steps during treatment as it wastes the clinician and the assistants' time. Moreover, the strength of bonding decreases every time than the previous session.,, With the need to return to a smaller wire and repeat steps already performed that is frustrating to the clinician and the patient.
By applying this new design, the bracket could be accustomed by the clinician directly according to the case. That was performed with minimal expenses in the machining price and no rebonding needed except in extreme errors in bonding. Moreover, the design could be used labially or lingually without any need for indirect bonding process. The use of only-NiTi wires guard against any misuse of heavy arch wires, which avoided any heavy forces together with associated deleterious effects such as force induced root resorption.
The authors anticipated throughout that design would make the treatment easier, faster and more stable for the clinician and the patients.
| Conclusion|| |
- The current design targeted to introduce a revolutionary bracket system that allowed for a true straight wire mechanics with no wire bending.
- It can be used with NiTi-only wires.
- The design could be used labially or lingually without the need of indirect bonding techniques.
- Any adjustments could be performed intraorally with simple finger pressure (i.e., the bracket could be accustomed by the clinician directly according to the case).
The authors wish to thank Eng. Mustafa Mahdi, Eng. Dr. Firas, Eng. Sandra, DT. Husain, for their assistance in all periods of study.
Ethical policy and Institutional Review board statement
Not needed in this study.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| References|| |
Agrawal K, Kangne S, Ambekar A, Joshi Y, Marure PK, Khanapure C. Evolution of pre-adjusted edgewise appliance in orthodontics. J Dent Res 2018;1:72-8.
Zawawi KH, Malki GA. Radiographic comparison of apical root resorption after orthodontic treatment between bidimensional and Roth straight-wire techniques. J Orthod Sci 2014;3:106-10.
Daga PN, Karandikar GR, Patni V, Karandikar AG, Doshi S. A comparative evaluation of accuracy of mclaughlin bennet trevisi prescription of six commercially available orthodontic metal brackets: An in vitro
study. J Indian Orthod Soc 2017;51:264-71. [Full text]
Vajaria R, BeGole E, Kusnoto B, Galang MT, Obrez A. Evaluation of incisor position and dental transverse dimensional changes using the Damon system. Angle Orthod 2011;81:647-52.
Gracco A, Tracey S. The insignia system of customized orthodontics. J Clin Orthod 2011;45:442-51; quiz 467-8.
Prashant PS, Nandan H, Gopalakrishnan M. Friction in orthodontics. J Pharm Bioallied Sci 2015;7(Suppl 2):S334-8.
Simone F, Rizzello G, Seelecke S, Motzki P. A soft five-fingered hand actuated by shape memory alloy wires: Design, manufacturing, and evaluation. Front Robot AI 2020;7:608841.
Dindaroğlu F, Doğan S. Root resorption in orthodontics. Turk J Orthod 2016;29:103-8.
Kulshrestha RS, Tandon R, Chandra P. Canine retraction: A systematic review of different methods used. J Orthod Sci 2015;4:1-8.
Nojima LI, Araújo AS, Alves Júnior M. Indirect orthodontic bonding--A modified technique for improved efficiency and precision. Dental Press J Orthod 2015;20:109-17.
Nawrocka A, Lukomska-Szymanska M. The indirect bonding technique in orthodontics-A narrative literature review. Materials (Basel, Switzerland) 2020;13:986.
Hou D, Capote R, Bayirli B, Chan DCN, Huang G. The effect of digital diagnostic setups on orthodontic treatment planning. Am J Orthod Dentofacial Orthop 2020;157:542-9.
Fan D, Li Y, Wang X, Zhu T, Wang Q, Cai H, et al
. Progressive 3D printing technology and its application in medical materials. Front Pharmacol 2020;11:122.
Jacobs CA, Lin AY. A new classification of three-dimensional printing technologies: Systematic review of three-dimensional printing for patient-specific craniomaxillofacial surgery. Plast Reconstr Surg 2017;139:1211-20.
Romano R, Geron S, Echarri P. Customized Brackets and Archwires, Lingual and Esthetic Orthodontics. 1st
ed. London: Quintessence Publishing; 2011. p. 154-6.
Dalessandri D, Lazzaroni E, Migliorati M, Piancino MG, Tonni I, Bonetti S. Self-ligating fully customized lingual appliance and chair-time reduction: A typodont study followed by a randomized clinical trial. Eur J Orthod 2013;35:758-65.
Hasan HS, Abdallah AA, Khan I, Alosman HS, Kolemen A, Alhayani B. Novel unilateral dental expander appliance (UDEX): A compound innovative materials. Comput Mater Continua 2021;68:3499-511.
Guenthner TA, Larson BE. Indirect bonding: A technique for precision and efficiency. Semin Orthod 2007;13:58-63.
Hocevar RA, Vincent HF. Indirect versus direct bonding: Bond strength and failure location. Am J Orthod Dentofacial Orthop 1988;94:367-71.
Kalange JT. Prescription-based precision full arch indirect bonding. Semin Orthod 2007;13:19-42.
Castilla AE, Crowe JJ, Moses JR, Wang M, Ferracane JL, Covell DA Jr. Measurement and comparison of bracket transfer accuracy of five indirect bonding techniques. Angle Orthod 2014;84:607-14.
Hasan HS, Kolemen A, Elkolaly M, Marya A, Gujjar S, Venugopal A. TADs for the derotation of 90° rotated maxillary bicuspids. Case Rep Dent 2021;2021:4285330.
Al Azzawi AM, Kadhim HA, Al Mayali AM, Elkolaly M, Hasan HS. Bond strength efficiency of a high fluoride and calcium release self-adhesive resin cement: A comparative in vitro
study. J Int Oral Health 2021;13:372-7.
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