Micro-CT Analysis of MTA Apical Plug Placement: Manual Condensation, Indirect Ultrasonic Activation, and Sonic-Activated Rotary Compaction Techniques
Issued Date
2026-01-01
Resource Type
ISSN
00992399
eISSN
18783554
Scopus ID
2-s2.0-105029226792
Pubmed ID
41534606
Journal Title
Journal of Endodontics
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SCOPUS
Bibliographic Citation
Journal of Endodontics (2026)
Suggested Citation
Harndamrong N., Wichai W., Jindachot S., Jantarat J. Micro-CT Analysis of MTA Apical Plug Placement: Manual Condensation, Indirect Ultrasonic Activation, and Sonic-Activated Rotary Compaction Techniques. Journal of Endodontics (2026). doi:10.1016/j.joen.2026.01.004 Retrieved from: https://repository.li.mahidol.ac.th/handle/123456789/114945
Title
Micro-CT Analysis of MTA Apical Plug Placement: Manual Condensation, Indirect Ultrasonic Activation, and Sonic-Activated Rotary Compaction Techniques
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Abstract
Introduction Mineral trioxide aggregate is widely used for apexification in immature permanent teeth owing to sealing ability and biocompatibility; however, placement in teeth with open apices may result in void, potentially compromising the apical seal. This study compared mineral trioxide aggregate (MTA) apical plug quality and procedural time among 3 placement techniques. Methods Thirty extracted human mandibular premolars with simulated open apices (apical diameter, 0.8 mm) were randomly assigned to 3 groups ( n = 10). Four-millimeter MTA apical plugs were placed using manual condensation, indirect ultrasonic activation, or sonic-activated rotary compaction. Micro–computed tomography quantified closed porosity (internal voids) and open porosity (interfacial gaps) as percentages of total apical plug volume. Procedural time was recorded, and data were analyzed statistically. Results Sonic-activated rotary compaction produced the lowest open porosity (0.001% ± 0.001%) and shortest procedural time (160.00 ± 6.50 s) but resulted in the highest closed porosity (0.412% ± 0.076%). Manual condensation demonstrated the highest open porosity (0.122% ± 0.063%) and moderate closed porosity (0.108% ± 0.076%), whereas indirect ultrasonic activation showed intermediate open porosity (0.006% ± 0.002%) and lowest closed porosity (0.079% ± 0.030%). Importantly, closed porosity did not differ significantly between the manual and ultrasonic groups ( P = .523). Indirect ultrasonic activation required the longest procedural time (270.30 ± 7.27 s), followed by manual condensation (229.20 ± 6.34 s), whereas sonic-activated rotary compaction was the most time-efficient. All other intergroup differences were statistically significant ( P < .001). Conclusions Sonic-activated rotary compaction demonstrated the lowest open porosity and greatest time efficiency among 3 techniques, although it produced the highest closed porosity.