Degeneration of intervertebral disc (IVD) and especially that of nucleus pulposus (NP) has been incurable at present. NP cell proliferates slowly and can not regenerate after being damaged. To better understand potential mechanisms of the degeneration, particularly the NP cell's role, we used TYPE II collagen and Hydrogel, respectively, to build up 3D cell cultures that provide a more in vivo-like platform for disc cells to grow on. In this study, the NP cells were cultured in 3D cell culture. We expected to observe phenotypic changes in NP cells . Subsequently, we used the customized chamber to ultrasonically stimulate the NP cell 3D cell cultures, hoping to confirm whether the cells in the 3D culture have special response to ultrasound is not found in the past 2D culture. Lastly, we simulated real disc damage models by creating damages in the 3D cultures. We successfully planted the NP cell into a 3D cell model. At the same time, we also found that the NP cell is spherical in the 3D structure, rather than flat in the 2D structure. In histology, the shape of NP cell is also spherical, so we believe that when NP cell grows in a 3D structure, it can maintain its original cellularity. After immunofluorescence , We found that p-PKC  will enter cilia(k40), and the percentage will increase under ultrasound stimulation, but it will not be significantly different until 24hr after stimulation. In damage experiments, we have observed that NP cells will undergo morphological changes, which is regulated by the ASIC3 channel. In addition, we also found that ultrasound can disarrange cell orientations around the damage through TRP channel. These experimental results indicate that we have developed an in vitro injury model for further study.