Background. Cervical radiculomyelopathy can be subdivided into myelopathy and radiculopathy. The main cause of myelopathy is spinal stenosis due to the formation of bone spurs, ossification of posterior longitudinal ligament (OPLL) and other degenerative changes of the spinal column. Radiculopathy on the other hand is mainly due to foraminal stenosis related to spondylosis and disc herniations. Although conservative treatments such as traction, hot/cold compress, electrotherapies are firstly prescribed, surgical intervention is often indicated. Surgery is categorically divided into either as anterior or posterior approach. Anterior approach includes anterior cervical discectomy and fusion (ACDF) and anterior cervical corpectomy with fusion (ACCF). Laminectomy and laminoplasty are the most common posterior decompression surgeries. However, owing to the intraoperative procedure of the laminoplasty, the dissection of the extensor muscles will results in the muscle atrophy. The clinical complications associated with muscle atrophy include the loss of cervical lordosis, decreasing the range of motion (ROM), and increased axial spinal pain. Purpose. Patients usually suffer atrophy of extensor deep muscles causing muscle dysfunction after laminoplasty. However, limited research focused on the impact of deep muscle dysfunctions on cervical alignment change and the cervical stability, respectively. A better understanding of the relationship will allow further inferences made on the importance of physical therapy treatments on post-operative muscle dysfunction. Material and Methods. The in-vitro model system was constructed from eight porcine cadaveric cervical spines (C2-C7) to simulate the biomechanical testing of human cervical muscles. Cables, pulleys, and weights were used to simulate the direction and force of the muscles. This study is divided into two sections: first, the ROM and stability of the constructed cervical model were measured in the presence and absence of muscles in order to compare the results with other published work. Once the applicability of the constructed model has been established, individual muscle dysfunction will be simulated to better understand the corresponding effect on the overall stability of the cervical spine. The second part of the study involved the simulation of an OPLL model and subsequently followed with simulated laminoplasty. To achieve the simulation of OPLL, a polyurethane tube was inserted into the spinal cord space to replicate the increase in the stiffness and kyphosis of the spinal column observed in OPLL patients. Once the biomechanical properties of the simulated OPLL model has been documented, a simulated laminoplasty involving cutting, splitting and fixing of lamina by plate and spacer was carried out. The aim of this part of the study is to better understand the impact of surgical intervention on the superficial and deep muscles of the neck, as well as the associated cervical alignment, ROM and stability change. Results. For the first part of the study, it was found that the ROM and neutral zone (NZ) decreased significantly for all of the muscles were intact in comparison to the one without muscles attachment. Furthermore, the normalised ratio of NZ was found to reach greater decrease than the ROM. Such finding is consistent with published data and validated the applicability of the simulated spine model. In terms of the impact of the individual muscles, it was found that the trapezius and the deep muscles showed the greatest effect on the ROM and stability, i.e. removal of these muscles were associated with the greatest increase in ROM and NZ. For the simulation of the OPLL model, it was found that the ROM decreased by 40% with a change of alignment into kyphosis. After the laminoplasty simulation procedure, a trend of gradual decrease of the cervical lordosis with the decrease of muscle function was observed. When the muscle was at 30% of original muscle function, the cervical lordosis significantly decreased when compared to both the intact and the OPLL group. In contrast, at 70% of original muscle function, the lordotic angle significantly increased when compared with the OPLL group, however, it was found to be still significantly less than the intact group. For the neutral zone results, no significant difference was found between the different muscle function levels and the intact group, however, a significant difference was found between the 30% muscle function group and the OPLL group where the NZ increased significantly in the 30% muscle function group. Conclusion. This study focused mainly on the biomechanical impacts of cervical muscle dysfunctions after laminoplasty. In terms of the alignment change, at least 50% deep muscle function was required to achieve the same alignment status as pre-laminoplasty in the OPLL state, and 70% of original deep muscle function was required to improve the cervical alignment to be better than the pre-operative state. It was noted that even with the 70% muscle function, the cervical alignment failed to return to its healthy state levels. In summary, identified decrease of cervical lordosis and the high levels of muscle function required to re-gain cervical alignment after laminoplasty highlights the importance of early and specific deep muscle retraining post-operatively.