Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans

Juliana Zimmermann; Clara Boudriot; Christiane Eipert; Gabriel Hoffmann; Rachel Nuttall; Viktor Neumaier; Moritz Bonhoeffer; Sebastian Schneider; Lena Schmitzer; Jan Kufer; Stephan Kaczmarz; Dennis M. Hedderich; Andreas Ranft; Daniel Golkowski; Josef Priller; Claus Zimmer; Rüdiger Ilg; Gerhard Schneider; Christine Preibisch; Christian Sorg; Benedikt Zott

doi:10.1371/journal.pbio.3003138

Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans

Juliana Zimmermann, Clara Boudriot, Christiane Eipert, Gabriel Hoffmann, Rachel Nuttall, Viktor Neumaier, Moritz Bonhoeffer, Sebastian Schneider, Lena Schmitzer, Jan Kufer, Stephan Kaczmarz, Dennis M. Hedderich, Andreas Ranft, Daniel Golkowski, Josef Priller, Claus Zimmer, Rüdiger Ilg, Gerhard Schneider, Christine Preibisch, Christian SorgBenedikt Zott

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Abstract

In the mammalian brain, the directed motion of cerebrospinal fluid (CSF-flux) is instrumental in the distribution and removal of solutes. Changes in total cerebral blood volume (CBV) have been hypothesized to drive CSF-flux. We tested this hypothesis in two multimodal brain imaging experiments in healthy humans, in which we drove large changes in total CBV by neuronal burst-suppression under anesthesia or by transient global vasodilation in a hypercapnic challenge. We indirectly monitored CBV changes with a high temporal resolution based on associated changes in total brain volume by functional MRI (fMRI) and measured cerebral blood flow by arterial spin-labeling. Relating CBV-sensitive signals to fMRI-derived measures of macroscopic CSF flow across the basal cisternae, we demonstrate that increasing total CBV extrudes CSF from the skull and decreasing CBV allows its influx. Moreover, CSF largely stagnates when CBV is stable. Together, our results establish the direct coupling between total CBV changes and CSF-flux.

Original language	English
Article number	e3003138
Journal	PLoS Biology
Volume	23
Issue number	4 April
DOIs	https://doi.org/10.1371/journal.pbio.3003138
State	Published - Apr 2025

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Zimmermann, J., Boudriot, C., Eipert, C., Hoffmann, G., Nuttall, R., Neumaier, V., Bonhoeffer, M., Schneider, S., Schmitzer, L., Kufer, J., Kaczmarz, S., Hedderich, D. M., Ranft, A., Golkowski, D., Priller, J., Zimmer, C., Ilg, R., Schneider, G., Preibisch, C., ... Zott, B. (2025). Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans. PLoS Biology, 23(4 April), Article e3003138. https://doi.org/10.1371/journal.pbio.3003138

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title = "Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans",

abstract = "In the mammalian brain, the directed motion of cerebrospinal fluid (CSF-flux) is instrumental in the distribution and removal of solutes. Changes in total cerebral blood volume (CBV) have been hypothesized to drive CSF-flux. We tested this hypothesis in two multimodal brain imaging experiments in healthy humans, in which we drove large changes in total CBV by neuronal burst-suppression under anesthesia or by transient global vasodilation in a hypercapnic challenge. We indirectly monitored CBV changes with a high temporal resolution based on associated changes in total brain volume by functional MRI (fMRI) and measured cerebral blood flow by arterial spin-labeling. Relating CBV-sensitive signals to fMRI-derived measures of macroscopic CSF flow across the basal cisternae, we demonstrate that increasing total CBV extrudes CSF from the skull and decreasing CBV allows its influx. Moreover, CSF largely stagnates when CBV is stable. Together, our results establish the direct coupling between total CBV changes and CSF-flux.",

author = "Juliana Zimmermann and Clara Boudriot and Christiane Eipert and Gabriel Hoffmann and Rachel Nuttall and Viktor Neumaier and Moritz Bonhoeffer and Sebastian Schneider and Lena Schmitzer and Jan Kufer and Stephan Kaczmarz and Hedderich, {Dennis M.} and Andreas Ranft and Daniel Golkowski and Josef Priller and Claus Zimmer and R{\"u}diger Ilg and Gerhard Schneider and Christine Preibisch and Christian Sorg and Benedikt Zott",

note = "Publisher Copyright: Copyright: {\textcopyright} 2025 Zimmermann et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.",

year = "2025",

month = apr,

doi = "10.1371/journal.pbio.3003138",

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Zimmermann, J, Boudriot, C, Eipert, C, Hoffmann, G, Nuttall, R, Neumaier, V, Bonhoeffer, M, Schneider, S, Schmitzer, L, Kufer, J, Kaczmarz, S, Hedderich, DM, Ranft, A, Golkowski, D, Priller, J , Zimmer, C, Ilg, R, Schneider, G , Preibisch, C, Sorg, C & Zott, B 2025, 'Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans', PLoS Biology, vol. 23, no. 4 April, e3003138. https://doi.org/10.1371/journal.pbio.3003138

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T1 - Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans

AU - Zimmermann, Juliana

AU - Boudriot, Clara

AU - Eipert, Christiane

AU - Hoffmann, Gabriel

AU - Nuttall, Rachel

AU - Neumaier, Viktor

AU - Bonhoeffer, Moritz

AU - Schneider, Sebastian

AU - Schmitzer, Lena

AU - Kufer, Jan

AU - Kaczmarz, Stephan

AU - Hedderich, Dennis M.

AU - Ranft, Andreas

AU - Golkowski, Daniel

AU - Priller, Josef

AU - Zimmer, Claus

AU - Ilg, Rüdiger

AU - Schneider, Gerhard

AU - Preibisch, Christine

AU - Sorg, Christian

AU - Zott, Benedikt

N1 - Publisher Copyright: Copyright: © 2025 Zimmermann et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

PY - 2025/4

Y1 - 2025/4

N2 - In the mammalian brain, the directed motion of cerebrospinal fluid (CSF-flux) is instrumental in the distribution and removal of solutes. Changes in total cerebral blood volume (CBV) have been hypothesized to drive CSF-flux. We tested this hypothesis in two multimodal brain imaging experiments in healthy humans, in which we drove large changes in total CBV by neuronal burst-suppression under anesthesia or by transient global vasodilation in a hypercapnic challenge. We indirectly monitored CBV changes with a high temporal resolution based on associated changes in total brain volume by functional MRI (fMRI) and measured cerebral blood flow by arterial spin-labeling. Relating CBV-sensitive signals to fMRI-derived measures of macroscopic CSF flow across the basal cisternae, we demonstrate that increasing total CBV extrudes CSF from the skull and decreasing CBV allows its influx. Moreover, CSF largely stagnates when CBV is stable. Together, our results establish the direct coupling between total CBV changes and CSF-flux.

AB - In the mammalian brain, the directed motion of cerebrospinal fluid (CSF-flux) is instrumental in the distribution and removal of solutes. Changes in total cerebral blood volume (CBV) have been hypothesized to drive CSF-flux. We tested this hypothesis in two multimodal brain imaging experiments in healthy humans, in which we drove large changes in total CBV by neuronal burst-suppression under anesthesia or by transient global vasodilation in a hypercapnic challenge. We indirectly monitored CBV changes with a high temporal resolution based on associated changes in total brain volume by functional MRI (fMRI) and measured cerebral blood flow by arterial spin-labeling. Relating CBV-sensitive signals to fMRI-derived measures of macroscopic CSF flow across the basal cisternae, we demonstrate that increasing total CBV extrudes CSF from the skull and decreasing CBV allows its influx. Moreover, CSF largely stagnates when CBV is stable. Together, our results establish the direct coupling between total CBV changes and CSF-flux.

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DO - 10.1371/journal.pbio.3003138

M3 - Article

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SN - 1544-9173

VL - 23

JO - PLoS Biology

JF - PLoS Biology

IS - 4 April

M1 - e3003138

ER -

Total cerebral blood volume changes drive macroscopic cerebrospinal fluid flux in humans

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