Biomechanical analysis of vertebral wedge deformity in elderly women with quantitative CT-based finite element analysis

• Published in: BMC musculoskeletal disorders Vol. 23; no. 1; p. 575
• Main Authors: Liu, Jing, Cheng, Xiaodong, Wang, Yan, Zhang, Ping, Gao, Lei, Yang, Xingyuan, He, Shaoqiang, Liu, Ying, Zhang, Wei
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 14.06.2022; BioMed Central; BMC
• Subjects: Abnormalities; Age; Aged; Aged women; Aging; Analysis; Biomechanical analysis; Biomechanical Phenomena; Biomechanics; Body mass index; Bone Density; Computed tomography; CT imaging; Female; Finite Element Analysis; Finite element method; Fractures; Geriatrics; Health aspects; Humans; Load; Lumbar Vertebrae - diagnostic imaging; Mathematical models; Medical imaging; Normal distribution; Older people; Osteoporosis; Quantitative CT; Spinal Fractures - diagnostic imaging; Spine; Statistical analysis; Tomography, X-Ray Computed; Vertebrae; Vertebral wedge deformity; China; United States > US; Vertebral wedge deformity; Finite element analysis; Biomechanical analysis; Quantitative CT
• ISSN: 1471-2474; 1471-2474
• DOI: 10.1186/s12891-022-05518-z

To explore the vertebral deformity angle (VD angle) of 1 lumbar vertebral body (L1) in elderly women, investigate the influence of VD on vertebral stiffness (VS) by biomechanical analysis using quantitative computed tomography-based finite element analysis (QCT-FEA). Two hundred seventy eight participants were recruited, and underwent QCT scan. Measured VD angles of L1, and constructed QCT-FEA models of L1 with the minimum (0.59°), median (5.79°) and maximum (11.15°) VD angles, respectively. Loads in two directions were applied on the upper edge of L1 with a force of 700 N, and vertebral stiffness (VS) was defined as the ratio of 700 N and displacement at the superior reference point: (1) perpendicular to the upper edge of L1 (defined as VS-U); (2) perpendicular to the lower edge of L1(defined as VS-L). Age was very weak positively correlated with VD angle, moderate negatively correlated with vBMD, and moderate negatively correlated with VS (P < 0.05). VS-U was significantly different among three VD angles, so was VS-L (P < 0.001). VS-U was higher than VS-L in 5.79° and 11.15° VD angles (P < 0.05), however no difference in 0.59° VD angles (P > 0.10). VD angle of L1 was slightly increased with age and not correlated with vBMD, and VS was moderate negatively correlated with age, showing that the vertebral body was more likely to fracture with aging. VS-U and VS-L were gradually decreased with the increase of VD angle, and VS-L was lower than VS-U with the increase of VD angle, which showed that vertebral body was more prone to fracture when the load was perpendicular to the lower edge of the vertebral body as the VD angle increasing.