Perivascular structures in corrosion casts of the human central nervous system: A confocal laser and scanning electron microscope study

Rodríguez‐Baeza, Alfonso; Torre, Francisco Reina‐De La; Ortega-Sánchez, Marisa; Sahuquillo-Barris, Joan

doi:10.1002/(sici)1097-0185(199810)252:2<176::aid-ar3>3.0.co;2-1

Cited by 58 publications

(30 citation statements)

References 27 publications

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“…One of the main components involved in brain blood flow control and regulation is the smooth muscle cells associated to resistance arterioles in the pial (Girouard and Iadecola, 2006) and intra-cortical arteries (Rodriguez-Baeza et al, 1998;Girouard and Iadecola, 2006). In the human brain, the detailed electron microscopy study of corrosion casts performed by Rodriguez-Baeza et al (1998) suggests the existence of a lower bound value for the diameter of arterioles that can exhibit active vasodilation.…”

Section: Blood Flow Control and Passive Responsesmentioning

confidence: 99%

“…In the human brain, the detailed electron microscopy study of corrosion casts performed by Rodriguez-Baeza et al (1998) suggests the existence of a lower bound value for the diameter of arterioles that can exhibit active vasodilation. In order to investigate the effect of the existence of a minimal diameter in arteries exhibiting active vasodilation, two values of d vaso have been chosen in the present study, the first, 9.9 μm, corresponding to the diameter threshold for capillary vessels and the second, 14.9 μm.…”

Section: Blood Flow Control and Passive Responsesmentioning

confidence: 99%

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Simulation study of brain blood flow regulation by intra-cortical arterioles in an anatomically accurate large human vascular network. Part II: Flow variations induced by global or localized modifications of arteriolar diameters

Lorthois¹,

Cassot²,

Lauwers³

2011

NeuroImage

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OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible. In a companion paper (Lorthois et al., Neuroimage, in press), we perform the first simulations of blood flow in an anatomically accurate large human intra-cortical vascular network (~10000 segments), using a 1D non-linear model taking into account the complex rheological properties of blood flow in microcirculation. This model predicts blood pressure, blood flow and hematocrit distributions, volumes of functional vascular territories, regional flow at voxel and network scales, etc. Using the same approach, we study flow reorganizations induced by global arteriolar vasodilations (an isometabolic global increase in cerebral blood flow). For small to moderate global vasodilations, the relationship between changes in volume and changes in flow is in close agreement with Grubb's law, providing a quantitative tool for studying the variations of its exponent with underlying vascular architecture. A significant correlation between blood flow and vascular structure at the voxel scale, practically unchanged with respect to baseline, is demonstrated. Furthermore, the effects of localized arteriolar vasodilations, representative of a local increase in metabolic demand, are analyzed. In particular, localized vasodilations induce flow changes, including vascular steal, in the neighboring arteriolar trunks at small distances (b 300 μm), while their influence in the neighboring veins is much larger (about 1 mm), which provides an estimate of the vascular point spread function. More generally, for the first time, the hemodynamic component of various functional neuroimaging techniques has been isolated from metabolic and neuronal components, and a direct relationship with several known characteristics of the BOLD signal has been demonstrated. IntroductionThere is increasing recognition that, by its structural implication in neuro-vascular coupling, underlying vascular architecture is a key player in hemodynamically based functional imaging techniques (including fMRI and PET) (Harrison et al., 2002;d'Esposito et al., 2003;Logothetis and Wandell, 2004;Lauwers et al., 2008;Weber et al., 2008). In particular, the spatial resolution and specificity of such techniques are bound to the density of blood capillary vasculature and blood flow regulating structures (Harel et al., 2006). This is especially important in the context of high field fMRI Harel et al., 2006), because, despite a dramatic increase in the theoretical spatial resolution obtained by using higher magnetic fields, associated with other hardware advancements, "the spatial extent of the hemodynamic response ultimately will impose a fundamental limitation on the spatial resolution of fMRI modalities" ).However, little is known about the fundamentals of the relationship between vascular structure and hemodynamic changes induced by brain activation. A growing body of evidence indicates that neurons, glia, and cerebral blood vessels, actin...

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Section: Blood Flow Control and Passive Responsesmentioning

confidence: 99%

Section: Blood Flow Control and Passive Responsesmentioning

confidence: 99%

Simulation study of brain blood flow regulation by intra-cortical arterioles in an anatomically accurate large human vascular network. Part II: Flow variations induced by global or localized modifications of arteriolar diameters

Lorthois¹,

Cassot²,

Lauwers³

2011

NeuroImage

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“…Nevertheless, functional recruitment of red blood cells to the capillary bed has been observed in scanning laser-Doppler flowmetry experiments in the cerebellar cortex of rats upon stimulation of climbing and parallel fibers (Akgoren and Lauritzen, 1999), and functional capillary recruitment has been deduced indirectly from comparing the ratio between CBF and cerebral metabolic rate for glucose (CMRGlu) upon stimulation and at rest in human parietal cortex (Kuwabara et al, 1992). Moreover, accumulating experimental evidence from microscopic investigations shows that capillaries are indeed endowed with the "machinery" needed to control their diameter (Rodriguez-Baeza et al, 1998;Harrison et al, 2002) and that this machinery responds to stimulation (Peppiatt et al, 2006, in retina).…”

Section: Activity-evoked Changes In Blood-volume and Flowmentioning

confidence: 99%

Coupling between neuronal activity and microcirculation: Implications for functional brain imaging

Vanzetta

Grinvald

2008

HFSP Journal

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In the neocortex, neurons with similar response properties are often clustered together in column-like structures, giving rise to what has become known as functional architecture-the mapping of various stimulus feature dimensions onto the cortical sheet. At least partially, we owe this finding to the availability of several functional brain imaging techniques, both post-mortem and in-vivo, which have become available over the last two generations, revolutionizing neuroscience by yielding information about the spatial organization of active neurons in the brain. Here, we focus on how our understanding of such functional architecture is linked to the development of those functional imaging methodologies, especially to those that image neuronal activity indirectly, through metabolic or haemodynamic signals, rather than directly through measurement of electrical activity. Some of those approaches allow exploring functional architecture at higher spatial resolution than others. In particular, optical imaging of intrinsic signals reaches the striking detail of È50 m, and, together with other methodologies, it has allowed characterizing the metabolic and haemodynamic responses induced by sensory-evoked neuronal activity. Here, we review those findings about the spatio-temporal characteristics of neurovascular coupling and discuss their implications for functional brain imaging, including position emission tomography, and non-invasive neuroimaging techniques, such as funtional magnetic resonance imaging, applicable also to the human brain.

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“…[45][46][47] Recently, noninvasive imaging of neural progenitor cells during angiogenesis was demonstrated in a bilateral carotid artery occlusion murine model by using gene transcript-targeted MR imaging contrast agents. In this ischemic brain injury model, SPIO nanoparticles, modified with micro DNA targeting actin and nestin messenger ribonucleic acid (the latter uniquely expressed by pericytes), were administered to mice after bilateral carotid artery occlusion to image vessel formation by the detection of cerebral pericytes.…”

Section: Noninvasive Detection Of Neural Progenitor Cells In Living Bmentioning

confidence: 99%

New Applications of Nanotechnology for Neuroimaging

Suffredini

East

Levy

2013

AJNR Am J Neuroradiol

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SUMMARY:Advances in nanotechnology have the potential to dramatically enhance the detection of neurologic diseases with targeted contrast agents and to facilitate the delivery of focused therapies to the central nervous system. We present the physicochemical rationale for their use, applications in animal models, and ongoing clinical trials using these approaches. We highlight advances in the use of nanoparticles applied to brain tumor imaging, tumor angiogenesis, neurodegeneration, grafted stem cells, and neuroprogenitor cells.ABBREVIATIONS: amyloid beta ϭ A␤; NO ϭ nitric oxide; NOS ϭ nitric oxide synthase; PBCA ϭ poly(n-butyl cyanoacrylate); QDots ϭ quantum dots; SPIO ϭ

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Perivascular structures in corrosion casts of the human central nervous system: A confocal laser and scanning electron microscope study

Cited by 58 publications

References 27 publications

Simulation study of brain blood flow regulation by intra-cortical arterioles in an anatomically accurate large human vascular network. Part II: Flow variations induced by global or localized modifications of arteriolar diameters

Simulation study of brain blood flow regulation by intra-cortical arterioles in an anatomically accurate large human vascular network. Part II: Flow variations induced by global or localized modifications of arteriolar diameters

Coupling between neuronal activity and microcirculation: Implications for functional brain imaging

New Applications of Nanotechnology for Neuroimaging

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