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[Lower jaw virtual reposition accuracy research].

A N Ryakhovsky1, M A Muradov1, V A Erokhin2

  • 1Central Research Institute of Dentistry and Maxillofacial Surgery, Moscow, Russia.

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|August 9, 2022
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Summary

This study assessed the accuracy of virtual mandibular repositioning by comparing virtual and real jaw positions. Errors in TMJ separation and combined scanning methods were the most significant factors influencing accuracy.

Keywords:
3D virtual planningLJ positionarticular gap

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Area of Science:

  • Dental imaging and biomechanics.
  • Orthodontics and maxillofacial surgery.

Background:

  • Accurate mandibular repositioning is crucial for diagnosing and treating temporomandibular joint (TMJ) disorders.
  • Virtual repositioning techniques offer a non-invasive approach but require validation for clinical reliability.

Purpose of the Study:

  • To evaluate the precision of virtual mandibular repositioning by comparing virtual and actual condyle positions.
  • To identify key factors contributing to errors in virtual repositioning procedures.

Main Methods:

  • An experimental human skull model with a movable mandible was used.
  • Computed tomography (CT) and intraoral scans were combined to create virtual models.
  • Virtual repositioning was performed, and discrepancies between virtual and actual condyle positions were measured.

Main Results:

  • The absolute difference in glenoid fossa space between virtual and actual reconstructions ranged from 0.260±0.1862 mm to 0.542±0.3354 mm.
  • The integral indicator of surface coincidence (q) was 0.296±0.1254 (s.u.).

Conclusions:

  • The accuracy of virtual mandibular repositioning is influenced by errors in repeated scanning, CBCT, and TMJ separation.
  • Errors related to combined teeth arch scans, bite scans, and TMJ separation were identified as the most significant contributors to inaccuracies.