The objective of this work has been to compare the hydrogen embrittlement (H.E.) susceptibility of two superaustenitic stainless steels (AL-6X and AL-6XN), and to study the effect of nitrogen content in the steels. Standard tensile specimens were prepared from these steels, and tensile testings under different stress conditions and strain rates were carried out in air and in hydrogen charging environment. Moreover, the microstructure and fractography of the specimens were studied using optical microscopes and scanning electron microscopes. Results from the slow strain rate tensile testing show that the sensitivity to H.E. of AL-6XN was higher than that of AL-6X.In constant load rupture testing, AL-6XN has a higher ductility loss. There were many parallel brittle cracks on the specimen surface and step-like markings were found on the brittle region of the fracture surface. The mechanism of hydrogen embrittlement of this N-containing superaustenitic stainless steel can be suggested as follow: Hydrogen absorbed in the steel induced local plasticity, and nitrogen on the other hand enhanced the planar slip of dislocations, thus allowing hydrogen to be transported via dislocations to the crack tip efficiently, giving rise to brittle fracture.