Distribution of Femoral Head Subchondral Fracture Site Relates to Contact Pressures, Age, and Acetabular Structure
Kubo Y, Motomura G, Utsunomiya T, et al. American Journal of Roentgenology. Volume 215, Issue 2
Biomechanics of callus in the bone healing process, determined by specimen-specific finite element analysis
Suzuki T, Matsuura Y, Yamazaki T, et al. Bone. Available online 28 December 2019, 115212
Bone strength of the proximal femur in healthy subjects with ossification of the posterior longitudinal ligament
Doi T, Hirai S, Kaneko M, et al, Osteoporosis International (2019). First Online: 09 December 2019
Prediction of the pathological fracture risk during stance and fall-loading configurations for metastases in the proximal femur, using a computed tomography-based finite element method
Shinoda Y, et al. Journal of Orthopaedic Science. Available online 11 September 2019
Potential bone fragility of mid-shaft atypical femoral fracture: Biomechanical analysis by a CT-based nonlinear finite element method
Tano A, et al. Injury. Available online 3 September 2019
Effect of post-osseointegration loading magnitude on the dynamics of peri-implant bone: a finite element analysis and in vivo study
Matsuzaki T, et al. Journal of Prosthodontic Research. Available online 24 July 2019
Biomechanical Study of Implant Treatment For Maxillas With Different Bone Quality
Arahira T. et al. Dental Research and Oral Health. 2 (2019): 003-016.
Influence of novel design alteration of pedicle screw on pull-out strength: A finite element study
Takenaka S, et al. Journal of Orthopaedic Science. Available online 19 March 2019
Prediction of fracture lines of the calcaneus using a three-dimensional finite element model.
Tsubone T, et al. Journal of Orthopaedic Research.
Biomechanics of Thoracolumbar Spine with Vertebral Compression Fractures
Mazlan MH, et al. Advanced Science Letters, Volume 24, Number 11, November 2018, pp. 8770-8773(4)
