Spectral Diffusion Analysis of Intravoxel Incoherent Motion MRI in Cerebral Small Vessel Disease

Wong, Sau May; Backes, Walter H.; Drenthen, Gerhard S.; Zhang, C. Eleana; Voorter, Paulien H.M.; Staals, Julie; Oostenbrugge, Robert J. van; Jansen, Jacobus F. A.

doi:10.1002/jmri.26920

Cited by 30 publications

(70 citation statements)

References 40 publications

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“…Another study utilized the intravoxel incoherent motion (IVIM) method to investigate the intermediate diffusion component using a nonnegative least-squares method to evaluate glymphatic system function. Using this method, values for both parenchymal diffusivity and microvascular perfusion were detected and perivascular fluid motion was evaluated in relation to the glymphatic system ( 43 ). Diffusion study can also be applied not only to the brain parenchyma but also to the CSF space.…”

Section: Imaging Evaluation Of the Glymphatic System/neurofluid Dynammentioning

confidence: 99%

“…One study showed the relationship between the volume fraction of the intermediate diffusion component with white matter hyperintensities and enlarged perivascular spaces. This correlation could indicate aberrant amounts of ISF in degenerated tissue or perivascular edema preceding tissue degeneration in cases with small vessel disease ( 43 ).…”

Section: Neurological Diseases Suspected To Be Associated With Glymphmentioning

confidence: 99%

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Neurofluid Dynamics and the Glymphatic System: A Neuroimaging Perspective

Taoka

Naganawa

2020

Korean J Radiol

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The glymphatic system hypothesis is a concept describing the clearance of waste products from the brain. The term “glymphatic system” combines the glial and lymphatic systems and is typically described as follows. The perivascular space functions as a conduit that drains cerebrospinal fluid (CSF) into the brain parenchyma. CSF guided to the perivascular space around the arteries enters the interstitium of brain tissue via aquaporin-4 water channels to clear waste proteins into the perivascular space around the veins before being drained from the brain. In this review, we introduce the glymphatic system hypothesis and its association with fluid dynamics, sleep, and disease. We also discuss imaging methods to evaluate the glymphatic system.

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Section: Imaging Evaluation Of the Glymphatic System/neurofluid Dynammentioning

confidence: 99%

Section: Neurological Diseases Suspected To Be Associated With Glymphmentioning

confidence: 99%

Neurofluid Dynamics and the Glymphatic System: A Neuroimaging Perspective

Taoka

Naganawa

2020

Korean J Radiol

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“…movement of interstitial fluid, 140 , 142 BBB leakage, 137 , 143 and vessel tortuosity. 144 Since rarefaction is often linked with one or more of these vascular alterations, the IVIM perfusion measures ( f , D* and fD* ) are rather indicative of microvascular integrity than mere CBF.…”

Section: Mri Methods To Measure Microvascular Rarefactionmentioning

confidence: 99%

Assessment of microvascular rarefaction in human brain disorders using physiological magnetic resonance imaging

Dinther

Voorter

Jansen

et al. 2022

J Cereb Blood Flow Metab

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Cerebral microvascular rarefaction, the reduction in number of functional or structural small blood vessels in the brain, is thought to play an important role in the early stages of microvascular related brain disorders. A better understanding of its underlying pathophysiological mechanisms, and methods to measure microvascular density in the human brain are needed to develop biomarkers for early diagnosis and to identify targets for disease modifying treatments. Therefore, we provide an overview of the assumed main pathophysiological processes underlying cerebral microvascular rarefaction and the evidence for rarefaction in several microvascular related brain disorders. A number of advanced physiological MRI techniques can be used to measure the pathological alterations associated with microvascular rarefaction. Although more research is needed to explore and validate these MRI techniques in microvascular rarefaction in brain disorders, they provide a set of promising future tools to assess various features relevant for rarefaction, such as cerebral blood flow and volume, vessel density and radius and blood-brain barrier leakage.

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“…Intravoxel incoherent motion MRI, which acquires diffusion-weighted images for multiple b values and fits multiple exponentials that typically correspond to capillary perfusion and Brownian motion, has also been extended to assess for glymphatic function (23). The presence of a diffusion component intermediate to parenchymal diffusivity and microvascular perfusion in regions surrounding enlarged perivascular spaces (EPVS) and white matter hyperintensities has been detected, which may relate to regional glymphatic dysfunction (Fig 2A) (24). PVS flows have also been assessed using diffusion tensor imaging techniques.…”

Section: Other Imaging Methods Of Glymphatic Functionmentioning

confidence: 99%

Current Concepts in Intracranial Interstitial Fluid Transport and the Glymphatic System: Part II—Imaging Techniques and Clinical Applications

Klostranec¹,

Vucevic²,

Bhatia³

et al. 2021

Radiology

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A s reviewed in part I (1), the glymphatic system is a network unique to the central nervous system that allows for the dynamic exchange of cerebrospinal fluid (CSF) and interstitial fluid (ISF) and has an essential role in normal homeostasis and clearance of interstitial solutes. The different compartments include the intracranial interstitial extracellular space (iECS), the paravascular space (PVS), defined here as between the endothelial basement membranes and the glial limitans of parenchymal perforating vessels that are continuous with the basal lamina of capillaries, and the CSF spaces with their transdural and transvenous efflux pathways. The anatomy and physiology of these multiple components present several challenges when designing techniques to clinically image glymphatic function, including length scales of the interstitium being orders of magnitude smaller than the spatial resolution of CT or MRI, the inability of conventional CT or MRI contrast agents to cross an intact blood-brain barrier (BBB) to access the PVS, and the slow transport velocities involved. In the following review, our attention turns to evaluation of the glymphatic system with imaging techniques, many of which are in the development phase but likely to advance to clinical use soon (Table). We also discuss the role of glymphatic function in the pathology of several common neurologic diseases, which supports the

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Spectral Diffusion Analysis of Intravoxel Incoherent Motion MRI in Cerebral Small Vessel Disease

Cited by 30 publications

References 40 publications

Neurofluid Dynamics and the Glymphatic System: A Neuroimaging Perspective

Neurofluid Dynamics and the Glymphatic System: A Neuroimaging Perspective

Assessment of microvascular rarefaction in human brain disorders using physiological magnetic resonance imaging

Current Concepts in Intracranial Interstitial Fluid Transport and the Glymphatic System: Part II—Imaging Techniques and Clinical Applications

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