Malocclusion Clinical Trial
Official title:
Precision Orthodontics: Customized Versus Conventional Orthodontic Bracket Prescriptions - A Randomized Controlled Clinical Trial
The investigators are evaluating the effectiveness of custom-made 3D-printed ceramic
(tooth-colored) brackets (braces) compared to conventional tooth-colored brackets (braces).
Participants will be expected to come in for regularly scheduled appointments. They will be
treated with tooth-colored braces and will need to come in every 4-6 weeks and will be
randomly assigned to one of three groups. "Randomly" means by chance, like a coin toss.
Neither participants nor the researchers may choose group assignments. Group 1 patients will
have tooth-colored braces placed directly on each tooth by the clinician. Group 2 patients
will have the braces placed on the teeth by using trays to fit them on. Group 3 patients will
have customized 3D printed tooth-colored braces placed on their teeth, using trays to fit
them on. If a participant is selected to be part of group 3, it may take up to two additional
weeks for these 3D brackets to be printed and shipped and so this might delay treatment
onset. Information on gender, age, and medical history of participants will also be obtained
from the electronic health record.
Teeth and orthodontic treatment plans are very unique to the specific patient, yet standard
orthodontic braces are currently "one-size fits all". In the early 20th century, orthodontics
was practiced using non-programmed brackets. First, second and third order bends had to be
incorporated into the wire in order to achieve ideal final tooth positions.
Andrews' Straight Wire Appliance (SWA) in the 1970s, however, revolutionized orthodontic care
by presenting a standard set of brackets with pre-programmed prescriptions built into the
appliance system [5-7]. According to Andrews, "it is far easier to control tooth movement
with bracket placement than bending wires".
Andrews analyzed 120 patient cases which presented with what he described as an ideal
occlusion. He documented common characteristics in regard to angulation, tip, and torque
subjectively deemed to create an ideal occlusion. This allowed him to develop a bracket
prescription to compensate for the disparity in the contour of the facial surfaces of teeth
by increasing thickness of the bracket base. Furthermore, he introduced angulations within
the bracket slot to achieve proper positioning of the roots [5, 8]. This "straight-wire
appliance" (SWA) method became widely accepted in orthodontics, and numerous variations of
pre-adjusted bracket systems have since been introduced. Pre-adjusted brackets, however, fail
to address deviations from average tooth morphology and other treatment nuances. These are
often tackled chairside by placing bends on arch wires [9-12] - bends that the SWA method was
invented to prevent. Additionally, mechanical boundaries and imprecision of bracket placement
can result in limitations to treatment. [13-15] All these inaccuracies may cumulate during
the course of a treatment to increase treatment time, resulting in frustration and
compromised results.
Technological advancements have allowed for some customization of brackets and wires in order
to address limitations of conventional pre-adjusted bracket systems. Digital intra-oral scans
are obtained at the onset of treatment to generate a digital study model of the dentition.
Virtual models are analyzed to determine the ideal position of each tooth required for
achieving stable occlusion. Those digital models also allow for bracket positioning set-up;
indirect-bonding transfer jigs allow virtual positioning to be replicated intra-orally. The
clinician creates a virtual design of the final occlusion and alignment using
computer-assisted technology, with reverse-engineered brackets and archwires used to obtain
the intended result. Bracket slots are customized to accommodate a straight wire that moves
each tooth to the ideal final position as identified by the virtual setup. Virtual bracket
positions are then transferred to the patient by means of indirect-bonding transfer jigs
[16].
Several orthodontic systems implement some of these new technologies, [17] providing the
orthodontist with a treatment package consisting of digital diagnostics, 3-dimensional (3D)
digital planning, and computer-designed customized brackets and arch wires. One such system
is the Insignia (ORMCO Corporation) system [18], which entered the market several years ago.
Theoretically, individualized orthodontic treatment systems offer several advantages for both
the patient and orthodontist, with commonly mentioned benefits including better treatment
results, shorter treatment duration, and less chair time. [19] Manufacturers utilizing
virtual treatment planning and customized, computer-aided fabrication of tooth supported
orthodontic appliances claim to deliver superior quality and efficiency of care compared to
conventional preadjusted bracket systems. To date, few studies have investigated the accuracy
of these systems in achieving their virtually planned tooth positions.
A 2015 retrospective study [20] reported that a Computer-aided design/computer-aided
manufacturing (CAD/CAM) orthodontic bracket system (Insignia ®) produced similar treatment
outcomes compared with direct and indirect bonded appliances. The CAD/CAM group nonetheless
had shorter treatment times than the direct and indirect bonded groups. To our knowledge,
only one prospective randomized clinical trial (RCT) [21] has explored the advantage or
otherwise of partially customized appliances with precise placement over directly or
indirectly bonded stock brackets.
The above-referenced RCT [21] concluded that "compared to the non-customized system, the
customized orthodontic system was not associated with any significant reduction in treatment
duration, and the treatment outcomes were comparable with both systems. Treatment duration
and quality were affected by the orthodontist and the severity of malocclusion at the start
of treatment rather than by the orthodontic system used. Treatment with a customized
appliance, such as the one used in this trial, required significantly more planning time from
the orthodontist and was associated with a higher number of visits due to loose brackets."
This study, however, introduced significant variability between the two test groups by using
two different bonding techniques. As a result, their conclusions could be flawed. Beyond
this, the customized brackets they used did not include customization of the bracket base to
conform to tooth anatomy. This is important because bracket base-tooth surface discrepancies
can lead to inaccuracies in the final in-out position of the tooth.
Due to recent breakthroughs in the area of 3D printing in dentistry - precisely, additive
manufacturing (AM) - and the limitations of previous studies (lack of
randomization/appropriate control for potential confounders), the need arises to evaluate if
3D-printed ceramic brackets offer any superiority to traditional ceramic braces.
Minimizing errors and improving accuracy are important factors not only for patient
satisfaction, but also for preventing adverse effects such as root resorption that occur when
unwanted tooth movements occur [22]. Different strategies have been designed for this
purpose, foremost among which has been to enhance treatment outcomes by precisely planning
tooth movements and positioning brackets with greater accuracy. Since the early stages of
multi-bracket appliance development, it was clear that precise bracket placement is key to
the success of the straight-wire concept [10]. One author stated that it is impossible to
solve the problem of adapting a bracket to a patient's specific tooth and to individualize
treatment goals without individualizing at least one bracket component and that new additive
manufacturing (AM) options can provide the catalyst for future developments in this field
[23]. Treatment with computer-designed customized brackets has the potential to personalize
orthodontic care, but the benefits remain to be validated. The present randomized controlled
trial aims to compare orthodontic treatment effectiveness in a customized versus
non-customized ceramic orthodontic system.
2. Innovation The 3D ceramic bracket being investigated is the only available customized
ceramic bracket. This will be a first for the orthodontic speciality. This will also be the
first and only customized bracket system that includes customization of the bracket base.
This helps in the control of first order orthodontic movements and allows brackets to be
bonded on any labial surface of the tooth while maintaining an ideal prescription. As 3D
printing is not limited by the mold-ejection in CIM (ceramic injection molding) [24] the
bracket system being tested here has the potential to achieve a more accurate slot dimension.
This is important because a critical factor affecting the expression of a bracket
prescription is the accuracy of the bracket slot. Various orthodontic textbooks have defined
expectations for bracket slot accuracy. In Contemporary Orthodontics, Proffitt et al. [25]
stated that the precision of orthodontic bracket manufacturing should render slot dimension
accuracy of at least 1 mil to ensure accurate expression of a chosen prescription. Oversized
slots (due to manufacturing limitations) defeat the premise of prescription orthodontic
brackets as the larger slot size does not allow for complete prescription expression [26].
3.1 Design This will be a parallel-arm randomized controlled clinical trial that involves 3
treatment groups
3.1.1 Treatment groups Treatment group 1: Patients in this group will be treated with
directly-bonded traditional (stock) .018 ceramic brackets Treatment group 2: Patients will be
treated with the same brackets from treatment group 1 but using the indirect bonding (IDB)
technique Treatment group 3: Patients will be treated using indirectly bonded fully
customized 3D-printed ceramic brackets. All participating clinicians will be trained in
digital orthodontics, and the IDB technique through hands-on sessions by orthodontists who
are experienced in the use of IDB and digital set up.
Direct bonding is the traditional way of placing orthodontic brackets, in which orthodontists
clinically eyeball the tooth and place the bracket where they deem most appropriate.
Traditionally, indirect bonding, starts with creating a mold of all the teeth as an exact
replica of the mouth of the patient. From there, in the lab, the orthodontist positions each
bracket precisely where it should go on each tooth and then creates a custom tray that allows
transfer of the brackets from the lab model to the patient's teeth. By taking the time to
place the brackets in a proper position on the lab model, orthodontists eliminate the
inaccurate process of placing orthodontic brackets directly on the teeth. It theoretically
also takes less chairside time and is more comfortable for the patient. It is however more
technique sensitive. In this study, indirect bonding setup will be done virtually using
commonly-available orthodontic software. The trays/jigs will then be 3-D printed.
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