Effect of clear aligner type on maxillary full-arch intrusion: 3D analysis using finite element method

Clear aligners are increasingly used to address various malocclusions. This treatment modality is compatible with teeth intrusion due to the whole dentition coverage and exertion of light forces [19, 20, 31]. The thermoplastic material composition offers the advantage of light force generation to aligners, but can also cause aligner deformation, affecting tooth movements and treatment results [31, 32]. In the present study, the trends of tooth movements were taken into account rather than the exact values. The amount of tooth movement and its clinical significance require further assessment.

Poisson’s ratio plays an important role in statics analysis. In this study, the Poisson’s ratios for all materials were considered to be 0.36. This means that the tension on an aligner causes it to lengthen by 0.36 in the direction of tension and contract by 0.36, perpendicular to the tension. Poisson’s ratio did not affect the results of this study, as the values were the same for all aligners.

Based on the results of this study, the amount of intrusion with all aligners except Duran was significantly different between the buccal and the palatal sides of molars (Fig. 3). Greater intrusion was observed at the buccal region which may result in buccal tipping of the molars. The buccal tipping of the molars during intrusion may be explained by the expected moment. Aligners are able to apply force from all directions due to engagement with the occlusal, buccal, and lingual teeth surfaces. This property is referred to as “the watermelon seed effect”. It may be supposed that the resultant force directed through the tooth center of resistance [33, 34]. However, the resultant force mostly does not pass through the center of resistance and creates a moment. This is due to the uneven force distribution caused by the non-symmetrical structure of the tooth crown [35]. To counteract this moment and redirect the force through the center of resistance, it has been proposed to add “pressure areas” to the aligner [35, 36]. Additionally, buccal tipping can be controlled to some extent by adding palatal attachments. Increasing the number of attachments has been suggested to reduce aligner deformation [30].

In this study, the difference between the buccal and palatal intrusion of molars was smaller with Duran aligner compared to other aligners. This may be attributed to the effect of thickness and elastic modulus on elastic deformation [37, 38]. Modulus of elasticity is an important physical characteristic that indicates the magnitude of force of thermoforming materials. The low modulus of elasticity of clear aligners (nearly 40–50 times lower than NiTi archwires) makes them susceptible to deformation even at low forces [35]. Thicker sheets may be suggested to compensate for the low modulus of elasticity. In this study, Duran aligner was the thickest and had the second highest modulus of elasticity. The combination of these two characteristics in Duran aligner appears to have reduced the tendency for buccal tipping of the molars.

Among anterior teeth, the amount of intrusion increased from the central incisor to the canine. This may be explained by the location of the miniscrew and force application. Consistent with the present study, Geramy et al. investigated maxillary full arch intrusion with Duran clear aligners and various miniscrew placements. They found that incisor intrusion was greater than canine intrusion when the miniscrews were distal to the lateral incisor and distal to the first molar, whereas canine intrusion was greater than incisor intrusion when the anterior miniscrew was located distal to the canine, as in this study [39].

In the sagittal plane, lingual movement of incisors and mesial movement of other teeth occurred at the incisal/occlusal points. This is expected in a clinical setting, as the aligners must be stretched to fit the dentition. Therefore, aligners may exert a retracting force on the anterior teeth and a protracting force on the posterior teeth. Patients are often instructed to place the aligners on their front teeth first and then on their posterior teeth, which may cause the entire aligner to move back. Thus, posterior protraction can be more significant [40]. Intraoral elastics may be recommended to reinforce the anchorage.

According to the results, the apices of the incisors moved lingually, similar to their crowns. However, the lingual movement of the central incisor was greater at the incisal tip than at the apex for all aligners. Therefore, incorporation of power ridges may be considered to control the torque. The amount of lingual movement of the lateral incisor was almost similar at the incisal and apical points. Consistent with this finding, Jiang et al. reported greater lingual root movement with increasing intrusion movement. This tendency decreased from the central incisors to the lateral incisors [41]. This may be due to the different positions of central and lateral incisors in the dental arch, and the different crown morphologies.

The apices of the canine, premolars, and molars moved distally, in the opposite direction to the crown movement. This may suggest mesial tipping of the crowns. Similarly, Fan et al. revealed mesial tipping of the second molar irrespective of attachment position due to the counterclockwise moment generated during molar intrusion [30]. The prescription can be modified by adding an additional distal crown tip on the posterior teeth to prevent mesial tipping. In addition, molars mesial movements were greater at the buccal than the palatal aspect. Therefore, one caution during the intrusion by aligners may be the mesial-in rotation of the molars. These observations were also possibly due to the bowing effect reported by Zhu et al. in a micro-sensor study [42]. Fan et al. believe that the bowing effect is unavoidable [30]. However, this phenomenon does not necessarily occur in clinical settings [43‐45].

The clinical efficacy of clear aligners may be influenced by various factors. Elastic deformation is a significant factor in treatment outcomes [32]. Previous studies have also emphasized the impact of thermoforming and the oral environment on the aligners’ properties. Thermoforming resulted in changes in the transparency, thickness, hardness, and water solubility of the aligners [46, 47]. Variations in aligner thickness and hardness have also been observed in studies simulating the oral environment [48, 49], although Bucci et al. showed that the thickness change will not adversely affect clinical performance [47]. Lombardo et al. indicated that the force exerted by aligners is affected by the oral environment [50]. In contrast, Elshazley et al. showed that the effect of saliva on applied force and torque was insignificant [51]. Given the controversy in the literature and the limitations of simulation studies, it seems logical to expect variability in estimated tooth movement in a clinical setting. This should be considered in order to draw conclusions. Thus further studies, including clinical investigations, are warranted to confirm the findings of the current study.

Orthodontic models prototyped with 3D printing technologies including stereolithography (SLA), digital light processing (DLP), and liquid crystal display (LCD) have been shown to be accurate and can be used as a diagnostic tool or for indirect production of clear aligners [52]. LCD printers may offer a promising low budget alternative to professional 3D printers with a clinically acceptable inaccuracy below 0.25 mm [53, 54]. Future studies evaluating the possible teeth movements during total maxillary arch intrusion comparing different 3D manufacturing processes are recommended.