Recent study on the reliability issues, the strained devices show a higher impact ionization rate, i.e., the device degradation is proportional to the current enhancement. For n-MOSFET devices, CESL (contact etching stop layer) strain (uniaxial) is much better in terms of reliability, performance, and process simplicity; SiC on source and drain structure shows high driving current ability. For p-MOSFET device, uniaxial structure with SiGe on source and drain with EDB (embedded diffusion barrier) seems to be promising in terms of its performance and reliability. In this thesis, the hot-carrier stress induced oxide traps and its correlation with enhanced degradation in strained CMOS devices have been reported. First, the ID-RTN (Drain Current Random Telegraph Noise) has been employed to study the stress induced slow traps in uniaxial strained n-MOSFETs and p-MOSFETs. The carrier trapping and detrapping effect in the gate dielectric can be observed. The drain current fluctuation is at low level when carrier is trapped and is at high level when carrier is detrapped. Through statistically extracting and calculating the capture and emission time, we can figure out the trap properties. Secondly, different process-induced strain effect for n-MOSFETs and p-MOSFETs has been observed respectively. By extracting the normalized drain current amplitude from the drain current spectra, experimental results show that the vertical compressive strain generates extra oxide defects and induces more scattering after HC stress in CESL device. This vertical strain in CESL also contributes to a non-negligible amount of extra devices degradation. While, SiGe S/D on p-MOSFET device shows different behavior in that the compressive strain along the channel shows no impact on its reliability. The process induced strain among different strained techniques can be investigated by the ID-RTN measurement. Furthermore, the application to the study of the strained SiC on S/D has also been demonstrated. Results also show that the uniaxial strain in such device exhibits less impact on the device reliability. Therefore, this strained SiC device is similar to the SiGe S/D device in terms of the ID-RTN characteristics.