Structural and torque changes in implant components of different diameters subjected to mechanical fatigue

To evaluate torque maintenance and structural damage in implant components of different diameters subjected to a fatigue challenge. Thirty 10-mm-long, morse taper connection, titanium dental implants and their corresponding one-piece abutments were divided into three groups (n = 10) according to imp...

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Bibliographic Details
Published in:Dental materials 2024-03, Vol.40 (3), p.493-499
Main Authors: dos Santos, Renan Brandenburg, Lenz, Ulysses, Griggs, Jason Alan, Estrela, Carlos, Bueno, Mike dos Reis, Porto, Olavo Cesar Lyra, Della Bona, Alvaro
Format: Article
Language:English
Subjects:
Cone-beam computed tomography
E-Vol DX software
Fatigue
Narrow-diameter implants
Small dental implants
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Summary:To evaluate torque maintenance and structural damage in implant components of different diameters subjected to a fatigue challenge. Thirty 10-mm-long, morse taper connection, titanium dental implants and their corresponding one-piece abutments were divided into three groups (n = 10) according to implant diameter: 4.3 mm (I4.3), 3.5 mm (I3.5), and 2.9 mm (I2.9). The implants were placed into a load-bearing fixture simulating bone tissue (modified G10), and the abutments were screwed into the implants to a final torque of 20 Ncm for the I4.3 and I3.5 and 15 Ncm for I2.9. The torque was secured by a digital torque meter. Cone-beam computed tomography (CBCT) scans were acquired and post-processed (e-Vol DX software) for all implant/abutment sets before and after subjecting them to fatigue in 37 °C distilled water (2 million cycles, constant load and frequency). The removal torque was measured using the same digital torque meter to calculate the difference in torque before and after fatigue. I2.9 showed substantial structural deformation compared with the other implant diameters (I3.5 and I4.3). However, the experimental groups did not show statistical differences for abutment loosening. Implants smaller than 3.5 mm in diameter have a higher probability of structural deformation than standard-diameter implants. The association between tomographic scans and e-Vol DX software showed satisfactory consistency with the direct assessment using the digital torque meter, offering an additional tool to evaluate implant component loosening and structural deformations. •Fatigue seems to be an adequate method to simulate the oral service of dental implants.•Implants smaller than 3.5 mm in diameter have a higher probability of structural deformation than standard-diameter implants.•Post-processed (e-Vol DX) CBCT scans emerges as a non-invasive diagnostic tool for assessing implant component loosening.
ISSN:0109-5641
1879-0097
DOI:10.1016/j.dental.2023.12.014