The modular spine block (MSB) is a novel "intravertebral fixator" that is minimally invasively implanted into the vertebrae. It is intended for use in vertebral compression fracture and will partially replace the currently commonly used "vertebroplasty" or "kyphoplasty". A three-dimensional nonlinear finite element analysis (FEA) of the osteoporotic L3 implanted with MSB was constructed. The force distribution was analyzed with 2 types of structural designs and 4 kinds of implantation methods at the adjacent segments. The MSB has little stress shielding effect on the intervertebral ROM and creates no additional loading to the adjacent disks. MSB were implanted in pigs to prove the ability of new bone formation within MSB in a porcine model. These findings suggest that MSBs have a similar positive effect on osseointegration. Meanwhile, it was also assessed whether the osteoporosis created by combined ovariectomy and calcium-restricted diets in the miniature pigs. The results demonstrated it is ineffective in achieving an artificial osteoporotic porcine model based on assessments of bone mineral density. The spinal hybrid elastic (SHE) rod is a novel "intervertebral fixator" that is a semi-rigid pedicle screw-based universal rod using an inner nitinol stick (NS) and outer polycarbonate urethane shell (PS). It is intended for use in spinal degenerative diseases and deformities and will partially replace the currently used "posterior fusion" or "dynamic stabilization systems". A 3-dimensional nonlinear FEA composed of pedicle screws, NS and PS was constructed to investigate the intervertebral biomechanical effects. Four groups had the same SHE rod diameter, but different NS diameter/PS thickness ratios. The SHE rod system provided sufficient spinal support and increased gentle adjacent-segment stress. The optimal NS diameter/PS thickness ratio is 3.5/2.0 mm. The SHE rod system affords nearly half spine support after lower third rod fracture in a worst-case scenario of the thinnest PS of the SHE rod system.