Introduction: The intervertebral disc is a viscoelastic material, which provides flexibility and acts as a shock absorber for the spine. In previous studies, injury of the disc affects its shock attenuation. During recovery, fluid flows into the intervertebral disc, allowing full recovery of the mechanical properties. However, information on the alterations of the discs shock attenuation, after fatigue loading with recovery, is lacking in the literature. This study evaluated the effects of short(0.5hr) and long(3hr) term fatigue loading. The purpose of this study is to investigate the effect of fatigue loading on the shock attenuation of the intervertebral disc by fatigue loading before and after rest. Material and method: Six month old porcine lumbar 2-unit motion segments were used in this study and divided into short and long term fatigue loading groups(n=9 for each). Impact loading was performed on the samples prior to fatigue loading. For the short term fatigue loading group, impact test was performed after each ten minutes of fatigue loading. For the long term fatigue loading group, impact test was performed after a half hour and each hour of fatigue loading. The change in the disc mechanical properties between first and second fatigue loading cycles, were compared. The intervertebral disc was modeled as a spring damping system. There are three parameters used to describe the performance of disc, including: stiffness, K (kN/mm), damping ratio, ξ, and damping coefficient, C(Ns/m). The input and output force were measured for the impact loading tests. Result: In the first cycle of long term fatigue loading, the values of K, C and ξ reached steady state after one hour. In the second loading cycle, the values of K, C and ξ reached steady state in a half hour. Comparing the first and second cycle of long term fatigue loading, there was significant differences within the first half hour. In the short term fatigue loading group, there was significant differences between 0min and 30min. There was no significant difference in the force attenuation, input and output force parameters, for any time point, when comparing the time points of the first and second loading cycles. Conclusion: The lack of significant difference in the force transmitted during the impact loading tests, for all time points, suggests that the amount of load absorbed by the intervertebral disc was small. This may be due to only having one intervertebral disc in the specimen, compared to 26 in the full human spine. The intervertebral disc will lose water during long term of fatigue loading and cause it lose its function as a shock absorber. In the long term fatigue loading group, the annulus fibrosus was damaged during the first testing cycle, preventing full recovery of the discs mechanical properties. Therefore, fluid flowed out of the disc more readily during the second cycle of fatigue loading. If the disc loses water, then its shock absorption properties will be altered. However, this phenomenon was not abserved in the short term fatigue loading group. Because the annulus fibrosus was not injured. In conclusion, the short term fatigue loading group was able to retain the recovered water, as seen by the recovery of the meachanical properties in the second set of fatigue loading ; however, the annulus fibrosus was damaged in the long term fatigue loading group.