Korean J Orthod.  2025 Mar;55(2):85-94. 10.4041/kjod24.082.

Predictability of maxillary dentoalveolar expansion with clear aligners in patients with mixed dentition

Affiliations
  • 1Surgical, Medical and Dental Department of Morphological Sciences related to Transplant, Oncology and Regenerative Medicine, University of Modena and Reggio Emilia, Modena, Italy
  • 2Private Practice, Saluzzo, Italy
  • 3Department of Orthodontics, CIR Dental School, University of Turin, Torino, Italy
  • 4Department of Orthodontics, School of Health Sciences, Aristotle University of Thessaloniki, Thessaloniki, Greece
  • 5Department of Medical Sciences, University of Torino, Torino, Italy
  • 6Private Practice, Torino, Italy

Abstract


Objective
This prospective study evaluated the effectiveness of clear aligner treatment (CAT) in achieving dentoalveolar upper arch expansion in patients with mixed dentition and transverse maxillary deficiency.
Methods
Forty patients with mixed dentition and a transverse discrepancy of ≤ 5 mm were treated using clear aligners. Pre- and post-treatment digital dental models were measured using specific landmarks and compared with the programmed expansion in the virtual treatment plan. Statistical analyses included the inter-class correlation coefficient to evaluate inter-rater reliability. A paired t test was employed to compare pre- and post-treatment values and to examine the significance of the changes. Multiple regression analysis was conducted to estimate the relationship between the prescribed and observed measurements, stratified by inter-dental measurements (deciduous canines, first deciduous molars, and permanent molars, at cusp and gingival levels).
Results
Excellent measurement reproducibility was observed. The accuracy of dentoalveolar maxillary arch expansion varied among different tooth regions. The inter-canine accuracy was 87.7% at the cusp level and 82.7% at the gingival level. The inter-first deciduous molars exhibited accuracies of 84.9% (cusp level) and 80.5% (gingival level). The inter-first molars showed accuracies of 77.8% (cusp level) and 67.9% (gingival level). Significant differences were observed between the planned and obtained measurements for specific tooth regions.
Conclusions
CAT demonstrated reliable predictability in achieving dentoalveolar expansion of the maxillary arch in patients with mixed dentition. A higher accuracy was observed in the anterior region than in the posterior region. These findings suggest that CAT could be an effective option for treating transverse maxillary deficiencies in patients with mixed dentition with moderate inter-arch transverse discrepancies, considering tooth-specific predictability differences.

Keyword

Expansion; Aligners; Predictability; Digital models

Figure

  • Figure 1 Inter-deciduous canine, inter-deciduous first molar, and inter-first molar maxillary widths measured at the cusp (solid lines) and gingival (dashed lines) levels. CC, inter-deciduous canine distance measured at cusp level; CG, inter-deciduous canine distance measured at the gingival level; PC, inter-first deciduous molar distance measured at cusp level; PG, inter-first deciduous molar distance measured at the gingival level; MC, inter-first molar distance measured at cusp level; MG, inter-first molar distance measured at the gingival level.

  • Figure 2 Mean accuracy, expressed as a percentage, of expansion measurements for inter-deciduous canine, inter-deciduous first molar, and inter-first molar maxillary widths, measured at the cusp (solid lines) and gingival (dashed lines) levels. Accuracy was calculated as: Percentage of accuracy = 100% – ([(predicted - achieved)/predicted] × 100%). The results are displayed for CC (inter-deciduous canine, cusp level), CG (inter-deciduous canine, gingival level), PC (inter-first deciduous molar, cusp level), PG (inter-first deciduous molar, gingival level), MC (inter-first molar, cusp level), and MG (inter-first molar, gingival level).


Reference

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