Biomechanical evaluation of internal and external hexagon platform switched implant-abutment connections: an in vitro laboratory and three-dimensional finite element analysis

Objectives The aim of this study was to assess the effect of abutment's diameter shifting on reliability and stress distribution within the implant-abutment connection for internal and external hexagon implants. The postulated hypothesis was that platform-switched implants would result in incre...

Full description

Access type:openAccess
Publication Date:2012
Main Author: Freitas Junior, Amilcar Chagas
Other Authors: Rocha, Eduardo P., Bonfante, Estevam A., Almeida, Erika Oliveira de, Anchieta, Rodolfo Bruniera, Martini, Ana P., Assunção, Wirley G., Silva, Nelson R. F. A., Coelho, Paulo G.
Document type: Article
Language:eng
Published: ELSEVIER
Portuguese subjects:
Online Access:https://repositorio.ufrn.br/jspui/handle/123456789/23800
https://doi.org/10.1016/j.dental.2012.05.004
Citation:FREITAS JUNIOR, Amilcar C. et al. Biomechanical Evaluation of Internal and External Hexagon Platform Switched Implant-Abutment Connections: An In Vitro Laboratory and Three-Dimensional Finite Element Analysis. Dental Materials, v. 7, n. 10, p. 1-8, 2012.
Portuguese abstract:Objectives The aim of this study was to assess the effect of abutment's diameter shifting on reliability and stress distribution within the implant-abutment connection for internal and external hexagon implants. The postulated hypothesis was that platform-switched implants would result in increased stress concentration within the implant-abutment connection, leading to the systems’ lower reliability. Methods Eighty-four implants were divided in four groups (n = 21): REG-EH and SWT-EH (regular and switched-platform implants with external connection, respectively); REG-IH and SWT-IH (regular and switched-platform implants with internal connection, respectively). The corresponding abutments were screwed to the implants and standardized maxillary central incisor metal crowns were cemented and subjected to step-stress accelerated life testing. Use-level probability Weibull curves and reliability were calculated. Four finite element models reproducing the characteristics of specimens used in laboratory testing were created. The models were full constrained on the bottom and lateral surface of the cylinder of acrylic resin and one 30° off-axis load (300 N) was applied on the lingual side of the crown (close to the incisal edge) in order to evaluate the stress distribution (svM) within the implant-abutment complex. Results The Beta values for groups SWT-EH (1.31), REG-EH (1.55), SWT-IH (1.83) and REG-IH (1.82) indicated that fatigue accelerated the failure of all groups. The higher levels of σvM within the implant-abutment connection observed for platform-switched implants (groups SWT-EH and SWT-IH) were in agreement with the lower reliability observed for the external hex implants, but not for the internal hex implants. The reliability 90% confidence intervals (50,000 cycles at 300 N) were 0.53(0.33–0.70), 0.93(0.80–0.97), 0.99(0.93–0.99) and 0.99(0.99–1.00), for the SWT-EH, REG-EH, SWT-IH, and REH-IH, respectively. Significance The postulated hypothesis was partially accepted. The higher levels of stress observed within implant-abutment connection when reducing abutment diameter (cross-sectional area) resulted in lower reliability for external hex implants, but not for internal hex implants.