The mechanical retrieval of fractured instruments from root canals has been largely reported in the literature, and many devices and methods have been proposed to accomplish that 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19 and 20. However, those methods present
some limitations related to canal morphology, reduction of root strength, and operator ability 6, 7, 16, 19, 21, 22, 23, 24, 25, 26 and 27. Consequently, a less complex retrieval method that causes minimum damage to the dental structures is necessary. A recent study proposed the electrochemical-induced dissolution of the fractured instrument as a means to recover the original canal path without damaging the root structures (28). According to the method described by Ormiga et al (28), two electrodes must be immersed in the electrolyte, one acting as a cathode and the other as an anode. PD98059 order Contact between the fractured file and the electrode used as an anode is necessary when the dissolution of the fractured file is the objective of the process. The electrolyte might have a composition that varies according to the metal to be dissolved; it is essential that the metal has susceptibility SCH 900776 for dissolution in this electrolyte. Therefore, once the cathode is composed by an inert metal, the transfer of electrons from the metal to be dissolved to the cathode tends to occur even without the imposition of a difference of potential between
the 2 electrodes. However, this process would be too slow to be used during the endodontic treatment. Consequently, Metalloexopeptidase a difference of potential must be applied to accelerate the transfer of electrons and the release of metallic ions to the solution. This process corresponds to the progressive dissolution of the fragment inside the root canal, where the current values generated are directly related to the amount of dissolved
material. Ormiga et al (28) observed a progressive consumption of K3 NiTi endodontic files with increasing polarization time in a sodium fluoride solution. Consequently, it was concluded that the concept of fractured file retrieval by an electrochemical process is feasible. Those authors also stated that there might be a relation between the current values and the exposed area of the fragment to the solution. Therefore, the purpose of this study was to test the method ability to dissolve fragments of K3 NiTi endodontic instruments. The diameter of the surface of the fragment exposed to the medium was evaluated as an interfering factor on the current levels used to promote the dissolution. Embedded fragments of 30.06 NiTi K3 rotary files (SDS Kerr, Glendora, CA) were obtained according to the method proposed by Siciliano (29). The files were inserted from the tip in internal orifices created in small polyvinyl chloride (PVC) cylinders. The diameter of the orifice was 8.0 mm, and the depth was 29.0 mm.