Continuous positive airway pressure increases CSF flow and glymphatic transport
Burhan Ozturk, Sunil Koundal, Ehab Al Bizri, Xinan Chen, Zachary Gursky, Feng Dai, Andrew Lim, Paul Heerdt, Jonathan Kipnis, Allen Tannenbaum, Hedok Lee, Helene Benveniste
Burhan Ozturk, Sunil Koundal, Ehab Al Bizri, Xinan Chen, Zachary Gursky, Feng Dai, Andrew Lim, Paul Heerdt, Jonathan Kipnis, Allen Tannenbaum, Hedok Lee, Helene Benveniste
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Research Article Neuroscience

Continuous positive airway pressure increases CSF flow and glymphatic transport

Abstract

Respiration can positively influence cerebrospinal fluid (CSF) flow in the brain, yet its effects on central nervous system (CNS) fluid homeostasis, including waste clearance function via glymphatic and meningeal lymphatic systems, remain unclear. Here, we investigated the effect of supporting respiratory function via continuous positive airway pressure (CPAP) on glymphatic-lymphatic function in spontaneously breathing anesthetized rodents. To do this, we used a systems approach combining engineering, MRI, computational fluid dynamics analysis, and physiological testing. We first designed a nasal CPAP device for use in the rat and demonstrated that it functioned similarly to clinical devices, as evidenced by its ability to open the upper airway, augment end-expiratory lung volume, and improve arterial oxygenation. We further showed that CPAP increased CSF flow speed at the skull base and augmented glymphatic transport regionally. The CPAP-induced augmented CSF flow speed was associated with an increase in intracranial pressure (ICP), including the ICP waveform pulse amplitude. We suggest that the augmented pulse amplitude with CPAP underlies the increase in CSF bulk flow and glymphatic transport. Our results provide insights into the functional crosstalk at the pulmonary-CSF interface and suggest that CPAP might have therapeutic benefit for sustaining glymphatic-lymphatic function.

Authors

Burhan Ozturk, Sunil Koundal, Ehab Al Bizri, Xinan Chen, Zachary Gursky, Feng Dai, Andrew Lim, Paul Heerdt, Jonathan Kipnis, Allen Tannenbaum, Hedok Lee, Helene Benveniste

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Figure 2

CPAP increases CSF flow speed and glymphatic transport locally.

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CPAP increases CSF flow speed and glymphatic transport locally. (A and B...
(A and B) Spatially normalized population-averaged whole-brain speed maps of rats (n = 8) breathing with nose cone shown in 2 orthogonal-plane views. (C and D) Corresponding speed maps of the CPAP group (n = 8) showing fast speed trajectories along the circle of Willis area when compared with the nose cone group (black boxes in B and D). The red-colored boxes in A and C indicate the midbrain area where glymphatic transport also appears different across groups. Scale bars = 2 mm. (E and F) Statistical maps (color coded for P values) overlaid onto a CSF compartment binary map highlighting voxel areas with higher CSF speed for the 2 conditions: NC > CPAP (E) and CPAP > NC (F). The black boxes highlight the circle of Willis. NC, nose cone. (G and H) Representative examples of velocity flux vectors (color coded for magnitude) shown from the ventral surface of the brain from a rat breathing via nose cone or with CPAP. (I and J) Statistical maps (color coded for P values) for tissue solute speed and flux (representing glymphatic transport) highlighting local areas with higher glymphatic transport and solute speed for the 2 conditions: NC > CPAP (I) and CPAP > NC (J). (K and L) Statistical maps (color coded for P values) for glymphatic transport overlaid onto an anatomical brain map highlighting voxel areas in the dorsal hippocampus with increased glymphatic speed/flux for the condition CPAP > NC (L). Scale bars = 3 mm. The voxel-wise statistical analysis was performed using an independent 2-sample t test in the framework of general linear modeling.