Mapping of CSF transport using high spatiotemporal resolution dynamic contrast‐enhanced MRI in mice: Effect of anesthesia

Stanton, Evan H.; Persson, Niklas Daniel Åke; Gomolka, Ryszard; Lilius, Tuomas; Sigurðsson, Björn; Lee, Hedok; Xavier, Anna L.R.; Benveniste, Helene; Mori, Yutaka

doi:10.1002/mrm.28645

“…Note that prior studies computed enhancement factors based on oscillatory (zero mean) flow ( 64, 65 ), whereas our calculations are based on steady (nonzero mean) flow, which we have previously argued is more effective for dispersive transport ( 19, 63 ). Although Taylor dispersion in pial PVSs is unlikely to account for the entirety of tracer transport observed in experiments, these estimates generally suggest that Intermediate scenario 1 with small precapillary PVSs (Γ precap = 0.07) is the only scenario with sleep/awake variations in volume flow rate large enough to explain tracer transport reported in several experiments ( 5, 51, 52, 61 ).…”

Section: Discussionmentioning

confidence: 85%

A network model of glymphatic flow under different experimentally-motivated parametric scenarios

Tithof

¹

,

Boster

²

,

Bork

³

et al. 2021

Preprint

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Rapidly growing evidence demonstrates that flow of cerebrospinal fluid (CSF) through perivascular spaces (PVSs) – annular tunnels surrounding vasculature in the brain – is a critically-important component of neurophysiology. CSF inflow contributes during physiological conditions to clearance of metabolic waste and in pathological situations to edema formation. However, brain-wide imaging methods cannot resolve PVSs, and high-resolution methods cannot access deep tissue or be applied to human subjects, so theoretical models provide essential insight. We model this CSF pathway as a network of hydraulic resistances, built from published parameters. A few parameters have very wide uncertainties, so we focus on the limits of their feasible ranges by analyzing different parametric scenarios. We identify low-resistance PVSs and high-resistance parenchyma (brain tissue) as the scenario that best explains experimental observations. Our results point to the most important parameters that should be measured in future experiments. Extensions of our modeling may help predict stroke severity or lead to neurological disease treatments and drug delivery methods.

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“…In particular, Xie et al showed K-X to mimic natural sleep with respect to glymphatic activity [ 10 ]. Stanton et al recently confirmed that contrast transport pathways differ between isoflurane and K-X anesthetic regimes [ 71 ]. Specifically, parenchymal penetration is poorer using isoflurane due to rapid efflux of contrast agent into the spinal canal and along cranial nerve sheaths.…”

Section: Discussionmentioning

confidence: 99%

Quantitative analysis of macroscopic solute transport in the murine brain

Ray

¹

,

Pike

²

,

Simon

³

et al. 2021

Fluids Barriers CNS

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Background Understanding molecular transport in the brain is critical to care and prevention of neurological disease and injury. A key question is whether transport occurs primarily by diffusion, or also by convection or dispersion. Dynamic contrast-enhanced (DCE-MRI) experiments have long reported solute transport in the brain that appears to be faster than diffusion alone, but this transport rate has not been quantified to a physically relevant value that can be compared to known diffusive rates of tracers. Methods In this work, DCE-MRI experimental data is analyzed using subject-specific finite-element models to quantify transport in different anatomical regions across the whole mouse brain. The set of regional effective diffusivities ($$D_{eff}$$ D eff ), a transport parameter combining all mechanisms of transport, that best represent the experimental data are determined and compared to apparent diffusivity ($$D_{app}$$ D app ), the known rate of diffusion through brain tissue, to draw conclusions about dominant transport mechanisms in each region. Results In the perivascular regions of major arteries, $$D_{eff}$$ D eff for gadoteridol (550 Da) was over 10,000 times greater than $$D_{app}$$ D app . In the brain tissue, constituting interstitial space and the perivascular space of smaller blood vessels, $$D_{eff}$$ D eff was 10–25 times greater than $$D_{app}$$ D app . Conclusions The analysis concludes that convection is present throughout the brain. Convection is dominant in the perivascular space of major surface and branching arteries (Pe > 1000) and significant to large molecules (> 1 kDa) in the combined interstitial space and perivascular space of smaller vessels (not resolved by DCE-MRI). Importantly, this work supports perivascular convection along penetrating blood vessels.

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“…We hypothesized that these numerous links between the skull marrow and the dura enable not only cell traffic towards the meninges ( 4 ) but also bidirectional crosstalk. We therefore implemented a 2-photon intravital microscopy (IVM) and ex vivo imaging pipeline to visualize CSF distribution after fluorescent tracer injection into the cisterna magna ( 9, 10 ). Intracisternal injection of 70 kD FITC-labeled ovalbumin was combined with intravenous labeling of the blood pool using 70 kD Texas red-labeled dextran.…”

Section: Resultsmentioning

confidence: 99%

Cerebrospinal fluid outflow through skull channels instructs cranial hematopoiesis

Pulous

¹

,

Cruz-Hernández

²

,

Yang

³

et al. 2021

Preprint

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Interactions between the immune and central nervous systems strongly influence brain health. Although the blood-brain barrier restricts this crosstalk, we now know that meningeal gateways through brain border tissues, particularly dural lymphatic vessels that allow cerebrospinal fluid outflow, facilitate intersystem communication. Here we observe that cerebrospinal fluid exits into the skull bone marrow. Fluorescent tracers injected into the cisterna magna of mice travel through hundreds of sub-millimeter skull channels into the calvarial marrow. During meningitis, bacteria usurp this perivascular route to infect the skull's hematopoietic niches and initiate cranial hematopoiesis ahead of remote tibial sites. Because skull channels also directly provide leukocytes to meninges, the privileged sampling of brain-derived danger signals in cerebrospinal fluid by regional marrow has broad implications for neurological disorders.

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Mapping of CSF transport using high spatiotemporal resolution dynamic contrast‐enhanced MRI in mice: Effect of anesthesia

Cited by 56 publications

References 50 publications

A network model of glymphatic flow under different experimentally-motivated parametric scenarios

A network model of glymphatic flow under different experimentally-motivated parametric scenarios

Quantitative analysis of macroscopic solute transport in the murine brain

Cerebrospinal fluid outflow through skull channels instructs cranial hematopoiesis

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