viernes, 17 de agosto de 2018

Pulsatile flow drivers in brain parenchyma and perivascular spaces: a resistance network model study | Fluids and Barriers of the CNS | Full Text

Pulsatile flow drivers in brain parenchyma and perivascular spaces: a resistance network model study | Fluids and Barriers of the CNS | Full Text

Fluids and Barriers of the CNS



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Pulsatile flow drivers in brain parenchyma and perivascular spaces: a resistance network model study

Fluids and Barriers of the CNS201815:20
  • Received: 13 January 2018
  • Accepted: 3 July 2018
  • Published: 

Abstract

Background

In animal models, dissolved compounds in the subarachnoid space and parenchyma have been found to preferentially transport through the cortex perivascular spaces (PVS) but the transport phenomena involved are unclear.

Methods

In this study two hydraulic network models were used to predict fluid motion produced by blood vessel pulsations and estimate the contribution made to solute transport in PVS and parenchyma. The effect of varying pulse amplitude and timing, PVS dimensions, and tissue hydraulic conductivity on fluid motion was investigated.

Results

Periodic vessel pulses resulted in oscillatory fluid motion in PVS and parenchyma but no net flow over time. For baseline parameters, PVS and parenchyma peak fluid velocity was on the order of 10 μm/s and 1 nm/s, with corresponding Peclet numbers below 103 and 10−1 respectively. Peak fluid velocity in the PVS and parenchyma tended to increase with increasing pulse amplitude and vessel size, and exhibited asymptotic relationships with hydraulic conductivity.

Conclusions

Solute transport in parenchyma was predicted to be diffusion dominated, with a negligible contribution from convection. In the PVS, dispersion due to oscillating flow likely plays a significant role in PVS rapid transport observed in previous in vivo experiments. This dispersive effect could be more significant than convective solute transport from net flow that may exist in PVS and should be studied further.

Keywords

  • Rat cerebral cortex
  • Biotransport
  • Glymphatic theory
  • Extracellular flow
  • Bulk flow
  • Interstitial flow
  • Lumped parameter
  • Porous media
  • Cerebrospinal fluid
  • Fluid mechanics
  • Diffusion

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