Abstract
The CT observation of back muscles of an idiopathic scoliosis patient showed increased muscle volume and high CT value on the convex side. Following these muscles by digitizer showed that convex muscle volume increased as the vertebra shifted to convexity. These back muscles were suggested to be transversospinalis muscles. Biomechanical analysis using finite element method (FEM) was done to further investigate this increasing volume of back muscles. A Risser experiment using FEM revealed that initial lordosis configuration model only produces rotation to the convex side by unilateral loading. We, therefore, made the model adding posterior element, regarding contraction of M. transversospinalis. In a normal case, the upper vertebra is rotated over the lower towards the side opposite the muscle contraction. The scoliosis model, however, showed rotation towards the side of muscle contraction. M. transversospinalis can be considered as the agent of this rotation force. In a rib cage model, M. transversospinalis also affected the rib cage deformity.
Citation Formats
Saka, K.
Biomechanical analysis of scoliosis and back muscles using CT evaluation and finite element method.
Japan: N. p.,
1987.
Web.
Saka, K.
Biomechanical analysis of scoliosis and back muscles using CT evaluation and finite element method.
Japan.
Saka, K.
1987.
"Biomechanical analysis of scoliosis and back muscles using CT evaluation and finite element method."
Japan.
@misc{etde_5901875,
title = {Biomechanical analysis of scoliosis and back muscles using CT evaluation and finite element method}
author = {Saka, K}
abstractNote = {The CT observation of back muscles of an idiopathic scoliosis patient showed increased muscle volume and high CT value on the convex side. Following these muscles by digitizer showed that convex muscle volume increased as the vertebra shifted to convexity. These back muscles were suggested to be transversospinalis muscles. Biomechanical analysis using finite element method (FEM) was done to further investigate this increasing volume of back muscles. A Risser experiment using FEM revealed that initial lordosis configuration model only produces rotation to the convex side by unilateral loading. We, therefore, made the model adding posterior element, regarding contraction of M. transversospinalis. In a normal case, the upper vertebra is rotated over the lower towards the side opposite the muscle contraction. The scoliosis model, however, showed rotation towards the side of muscle contraction. M. transversospinalis can be considered as the agent of this rotation force. In a rib cage model, M. transversospinalis also affected the rib cage deformity.}
journal = []
volume = {61:4}
journal type = {AC}
place = {Japan}
year = {1987}
month = {Mar}
}
title = {Biomechanical analysis of scoliosis and back muscles using CT evaluation and finite element method}
author = {Saka, K}
abstractNote = {The CT observation of back muscles of an idiopathic scoliosis patient showed increased muscle volume and high CT value on the convex side. Following these muscles by digitizer showed that convex muscle volume increased as the vertebra shifted to convexity. These back muscles were suggested to be transversospinalis muscles. Biomechanical analysis using finite element method (FEM) was done to further investigate this increasing volume of back muscles. A Risser experiment using FEM revealed that initial lordosis configuration model only produces rotation to the convex side by unilateral loading. We, therefore, made the model adding posterior element, regarding contraction of M. transversospinalis. In a normal case, the upper vertebra is rotated over the lower towards the side opposite the muscle contraction. The scoliosis model, however, showed rotation towards the side of muscle contraction. M. transversospinalis can be considered as the agent of this rotation force. In a rib cage model, M. transversospinalis also affected the rib cage deformity.}
journal = []
volume = {61:4}
journal type = {AC}
place = {Japan}
year = {1987}
month = {Mar}
}