OBJECT: The authors have previously investigated the mechanical properties of the white and gray matter in the bovine cervical spinal cord, demonstrating that the gray matter is more rigid, although more fragile, than the white matter. In the present study they conducted additional tensile tests on the bovine cervical spinal cord by changing strain levels and strain rates applied to the white and gray matter. METHODS: Based on their testing, the authors found the following: 1) Stress within the spinal cord relaxes over time. 2) Intracord stress is related to the strain rates or levels. The finite element method was used to compute the stress distribution within the spinal cord under three compressive loading conditions. Results from the computations showed a different stress distribution in the white and gray matter, where the distribution of stress varied with strain rate, compression volume, and the position of compression. CONCLUSIONS: These differences in mechanical properties between the white and gray matter constitute different mechanisms contributing to the development of tissue damage and clinical symptoms.
OBJECT: The authors have previously investigated the mechanical properties of the white and gray matter in the bovine cervical spinal cord, demonstrating that the gray matter is more rigid, although more fragile, than the white matter. In the present study they conducted additional tensile tests on the bovine cervical spinal cord by changing strain levels and strain rates applied to the white and gray matter. METHODS: Based on their testing, the authors found the following: 1) Stress within the spinal cord relaxes over time. 2) Intracord stress is related to the strain rates or levels. The finite element method was used to compute the stress distribution within the spinal cord under three compressive loading conditions. Results from the computations showed a different stress distribution in the white and gray matter, where the distribution of stress varied with strain rate, compression volume, and the position of compression. CONCLUSIONS: These differences in mechanical properties between the white and gray matter constitute different mechanisms contributing to the development of tissue damage and clinical symptoms.
Authors: Benjamin S Hopkins; Kenneth A Weber; Kartik Kesavabhotla; Monica Paliwal; Donald R Cantrell; Zachary A Smith Journal: World Neurosurg Date: 2019-03-25 Impact factor: 2.104
Authors: Nicole L Ramo; Snehal S Shetye; Femke Streijger; Jae H T Lee; Kevin L Troyer; Brian K Kwon; Peter Cripton; Christian M Puttlitz Journal: Acta Biomater Date: 2017-12-26 Impact factor: 8.947
Authors: M Funaba; T Kanchiku; Y Imajo; H Suzuki; Y Yoshida; N Nishida; K Fujimoto; T Taguchi Journal: Spinal Cord Date: 2015-11-17 Impact factor: 2.772