Objectives. This study was designed to verify whether nitridation treatment
of the cutting surfaces resulted in surface or subsurface changes that pro
duced an increase in the resistance to wear in nickel titanium (NiTi) endod
ontic files.
Study design. Some experimental samples were exposed to ionic implantation
by using 150 keV of nitrogen ions and doses of 1 x 10(17) ions per cm(2). O
ther samples were exposed to thermal nitridation processes performed for 48
0 minutes at 500 degrees C temperature. Control samples were not exposed to
any process. The chemical composition of the surface layers of each sample
was determined by means of x-ray photoelectron spectroscopy. The cutting e
fficiency was tested on an endotraining bloc.
Results. The experimental instruments showed in-depth distributions of chem
ical composition that were different from those seen in the control group;
thermal-nitridated instruments demonstrated a surface ratio of nickel to ti
tanium of 0.5. Implanted samples had a higher N/Ti ratio (1.2); this ratio
may be due to the presence of a layer of titanium nitride. Samples in the e
xperimental groups showed an increase in cutting ability as compared with t
he controls.
Conclusions. Thermal nitridation and nitrogen-ionic implantation treatment
of nickel-titanium files produced a higher wear resistance and an increased
cutting capacity.