Subject-specific studies of csf bulk flow patterns in the spinal canal: implications for the dispersion of solute particles in intrathecal drug delivery Articles uri icon

authors

  • COENEN, WILFRIED ROMAIN STEFAN
  • Gutierrez Montes, C.
  • SINCOMB, S.
  • CRIADO-HIDALGO, E.
  • WEI, K.
  • KING, K.
  • HAUGHTON, V.
  • MARTINEZ BAZAN, JESUS CARLOS
  • SANCHEZ, A. L.
  • LASHERAS, J.C.

publication date

  • July 2019

start page

  • 1242

end page

  • 1249

issue

  • 7

volume

  • 40

International Standard Serial Number (ISSN)

  • 0195-6108

Electronic International Standard Serial Number (EISSN)

  • 1936-959X

abstract

  • Background and purpose: Recent flow dynamics studies have shown that the eccentricity of the spinal cord affects the magnitude and characteristics of the slow bulk motion of CSF in the spinal subarachnoid space, which is an important variable in solute transport along the spinal canal. The goal of this study was to investigate how anatomic differences among subjects affect this bulk flow. Materials and methods: T2-weighted spinal images were obtained in 4 subjects and repeated in 1 subject after repositioning. CSF velocity was calculated from phase-contrast MR images for 7 equally spaced levels along the length of the spine. This information was input into a 2-time-scale asymptotic analysis of the Navier-Stokes and concentration equations to calculate the short- and long-term CSF flow in the spinal subarachnoid space. Bulk flow streamlines were shown for each subject and position and inspected for differences in patterns. Results: The 4 subjects had variable degrees of lordosis and kyphosis. Repositioning in 1 subject changed the degree of cervical lordosis and thoracic kyphosis. The streamlines of bulk flow show the existence of distinct regions where the fluid particles flow in circular patterns. The location and interconnectivity of these recirculating regions varied among individuals and different positions. Conclusions: Lordosis, kyphosis, and spinal cord eccentricity in the healthy human spine result in subject-specific patterns of bulk flow recirculating regions. The extent of the interconnectivity of the streamlines among these recirculating regions is fundamental in determining the long-term transport of solute particles along the spinal canal.

subjects

  • Chemistry
  • Industrial Engineering
  • Materials science and engineering
  • Mechanical Engineering
  • Physics

keywords

  • computational fluid-dynamics; cerebrospinal-fluid; boundary-conditions; simulations; circulation; pulsations; amplitude; motion; phase; model