AIM: To evaluate the cyclic fatigue fracture resistance of engine-driven F2 ProTaper instruments under reciprocating movement. METHODOLOGY: A sample of 30 NiTi ProTaper F2 instruments was used. An artificial canal was made from a stainless steel tube, allowing the instruments to rotate freely. During mechanical testing, different movement kinematics and speeds were used, which resulted in three experimental groups (n = 10). The instruments from the first group (G1) were rotated at a nominal speed of 250 rpm until fracture, whilst the instruments from the second group (G2) were rotated at 400 rpm. In the third instrument group (G3), the files were driven under reciprocating movement. The time of fracture for each instrument was measured, and statistical analysis was performed using parametric methods. RESULTS: Reciprocating movement resulted in a significantly longer cyclic fatigue life (P < 0.05). Moreover, operating rpm was a significant factor affecting cyclic fatigue life (P < 0.05); instruments used at a rotational speed of 400 rpm (approximately 95 s) failed more rapidly than those used at 250 rpm (approximately 25 s). CONCLUSIONS: Movement kinematics is amongst the factors determining the resistance of rotary NiTi instruments to cyclic fracture. Moreover, the reciprocating movement promoted an extended cyclic fatigue life of the F2 ProTaper instrument in comparison with conventional rotation.
AIM: To evaluate the cyclic fatigue fracture resistance of engine-driven F2 ProTaper instruments under reciprocating movement. METHODOLOGY: A sample of 30 NiTi ProTaper F2 instruments was used. An artificial canal was made from a stainless steel tube, allowing the instruments to rotate freely. During mechanical testing, different movement kinematics and speeds were used, which resulted in three experimental groups (n = 10). The instruments from the first group (G1) were rotated at a nominal speed of 250 rpm until fracture, whilst the instruments from the second group (G2) were rotated at 400 rpm. In the third instrument group (G3), the files were driven under reciprocating movement. The time of fracture for each instrument was measured, and statistical analysis was performed using parametric methods. RESULTS: Reciprocating movement resulted in a significantly longer cyclic fatigue life (P < 0.05). Moreover, operating rpm was a significant factor affecting cyclic fatigue life (P < 0.05); instruments used at a rotational speed of 400 rpm (approximately 95 s) failed more rapidly than those used at 250 rpm (approximately 25 s). CONCLUSIONS: Movement kinematics is amongst the factors determining the resistance of rotary NiTi instruments to cyclic fracture. Moreover, the reciprocating movement promoted an extended cyclic fatigue life of the F2 ProTaper instrument in comparison with conventional rotation.
Authors: Chiara Pirani; Oddone Ruggeri; Pier Paolo Cirulli; Gian Andrea Pelliccioni; Maria Giovanna Gandolfi; Carlo Prati Journal: Odontology Date: 2013-04-09 Impact factor: 2.634
Authors: Daniely Amorin Meireles; Mariana Mena Barreto Bastos; André Augusto Franco Marques; Lucas da Fonseca Roberti Garcia; Emílio Carlos Sponchiado Journal: Restor Dent Endod Date: 2013-08-23
Authors: Murilo Priori Alcalde; Marco Antonio Hungaro Duarte; Clovis Monteiro Bramante; Bruno Carvalho de Vasconselos; Mario Tanomaru-Filho; Juliane Maria Guerreiro-Tanomaru; Jader Camilo Pinto; Marcus Vinicius Reis Só; Rodrigo Ricci Vivan Journal: Clin Oral Investig Date: 2017-12-09 Impact factor: 3.573