I. P. Martyshina scite author profile

I. P. Martyshina

5Publications

5Citation Statements Received

45Citation Statements Given

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Institute of Strength Physics and Materials Science

Publications

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Convergence analysis and validation of a discrete element model of the human lumbar spine

2022

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Degenerative diseases of the spine can lead to or hasten the onset of additional spinal problems that significantly reduce human mobility. The spine consists of vertebral bodies and intervertebral discs. The most degraded are intervertebral discs. The vertebral body consists of a shell (cortical bone tissue) and an internal content (cancellous bone tissue). The intervertebral disc is a complex structural element of the spine, consisting of the nucleus pulposus, annulus fibrosus, and cartilaginous plates. To develop numerical models for the vertebral body and intervertebral disc, first, it is necessary to verify and validate the models for the constituent elements of the lumbar spine. This paper, for the first time, presents discrete elements-based numerical models for the constituent parts of the lumbar spine, and their verification and validation. The models are validated using uniaxial compression experiments available in the literature. The model predictions are in good qualitative and quantitative agreement with the data of those experiments. The loading rate sensitivity analysis revealed that fluid-saturated porous materials are highly sensitive to loading rate: a 1000-fold increase in rate leads to the increase in effective stiffness of 130 % for the intervertebral disc, and a 250-fold increase in rate leads to the increase in effective stiffness of 50 % for the vertebral body. The developed model components can be used to create an L4-L5 segment model, which, in the future, will allow investigating the mechanical behavior of the spine under different types of loading.

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Development of Numerical Models of Materials for Endoprosthesis of the Lumbar Spine

Martyshina¹,

Eremina²,

Smolin³

2022

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Effect of the Strengthening Phase Concentration on the Hardness of Double Ceramic Composites

Martyshina¹,

Eremina²,

Smolin³

2022

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The Influence of Structural Arrangement of Inclusions on Dual Composite Strength

2021

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Effect of inclusion arrangement on strength of dual ceramics composites

Martyshina¹,

Eremina²,

Smolin³

2022

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I. P. Martyshina

Convergence analysis and validation of a discrete element model of the human lumbar spine

Development of Numerical Models of Materials for Endoprosthesis of the Lumbar Spine

Effect of the Strengthening Phase Concentration on the Hardness of Double Ceramic Composites

The Influence of Structural Arrangement of Inclusions on Dual Composite Strength

Effect of inclusion arrangement on strength of dual ceramics composites

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