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Perivascular space

January 01, 1970

A perivascular space, also known as a Virchow–Robin space, is a fluid-filled space surrounding certain blood vessels in several organs, including the brain,[1] potentially having an immunological function, but more broadly a dispersive role for neural and blood-derived messengers.[2] The brain pia mater is reflected from the surface of the brain onto the surface of blood vessels in the subarachnoid space. In the brain, perivascular cuffs are regions of leukocyte aggregation in the perivascular spaces, usually found in patients with viral encephalitis.

Perivascular space
A perivascular space as seen on CT
Anatomical terms of neuroanatomy
[edit on Wikidata]
CT image showing extensive low attenuation in the right hemispheric white matter due to dilated Type 2 perivascular spaces
Axial fat-suppressed T2-weighted MRI image in the same patient as above demonstrating extensive dilated Type 2 perivascular spaces in the right hemisphere
Perivascular space is depicted in the inset box.

Perivascular spaces vary in dimension according to the type of blood vessel. In the brain where most capillaries have an imperceptible perivascular space, select structures of the brain, such as the circumventricular organs, are notable for having large perivascular spaces surrounding highly permeable capillaries, as observed by microscopy. The median eminence, a brain structure at the base of the hypothalamus, contains capillaries with wide perivascular spaces.[3]

In humans, perivascular spaces surround arteries and veins can usually be seen as areas of dilatation on MRI images. While many normal brains will show a few dilated spaces, an increase in these spaces may correlate with the incidence of several neurodegenerative diseases, making the spaces a topic of research.[4]

Structure edit

Perivascular spaces are gaps containing interstitial fluid that span between blood vessels and their host organ, such as the brain, which they penetrate and serve as extravascular channels through which solutes can pass.[2][5] Like the blood vessels around which they form, perivascular spaces are found in both the brain subarachnoid space and the subpial space.[6]

Perivascular spaces surrounding arteries in the cerebral cortex and the basal ganglia are separated from the subpial space by one or two layers of leptomeninges, respectively, as well as the pia mater.[7] By virtue of the leptomeningeal cell layer, the perivascular spaces belonging to the subarachnoid space are continuous with those of the subpial space. The direct communication between the perivascular spaces of the subarachnoid space and the subpial space is unique to the brain's arteries, as no leptomeningeal layers surround the brain's veins.[7][6] Use of the scanning electron microscope has determined that the spaces surrounding blood vessels in the subarachnoid space are not continuous with the subarachnoid space because of the presence of pia mater cells joined by desmosomes.[8]

Perivascular spaces, especially around fenestrated capillaries, are found in many organs, such as the thymus, liver, kidneys, spleen, bones, and pineal gland.[9][10][11][12] Particularly within the brain circumventricular organs – subfornical organ, area postrema, and median eminence – large perivascular spaces are present around fenestrated capillaries, indicating that the spaces serve a dispersive role for brain- or bloodborne messengers.[2]

Perivascular spaces may be enlarged to a diameter of five millimeters in healthy humans and do not imply disease. When enlarged, they can disrupt the function of the brain regions into which they project.[5] Dilation can occur on one or both sides of the brain.[7]

Dilated perivascular spaces are categorized into three types:[7]

Perivascular spaces are most commonly located in the basal ganglia and white matter of the cerebrum, and along the optic tract.[13] The ideal method used to visualize perivascular spaces is T2-weighted MRI. The MR images of other neurological disorders can be similar to those of the dilated spaces. These disorders are:[7]

Perivascular spaces are distinguished on an MRI by several key features. The spaces appear as distinct round or oval entities with a signal intensity visually equivalent to that of cerebrospinal fluid in the subarachnoid space.[7][14][15] In addition, a perivascular space has no mass effect and is located along the blood vessel around which it forms.[14]

Function edit

One of the most basic roles of the perivascular space is the regulation of fluid movement in the central nervous system and its drainage.[13] The spaces ultimately drain fluid from neuronal cell bodies to the cervical lymph nodes.[5] In particular, the "tide hypothesis" suggests that the cardiac contraction creates and maintains pressure waves to modulate the flow to and from the subarachnoid space and the perivascular space.[16] By acting as a sort of sponge, they are essential for signal transmission and the maintenance of extracellular fluid.[16]

Another function is as an integral part of the blood–brain barrier (BBB).[17] While the BBB is often described as the tight junctions between the endothelial cells, this is an oversimplification that neglects the intricate role that perivascular spaces take in separating the venous blood from the parenchyma of the brain. Often, cell debris and foreign particles, which are impermeable to the BBB will get through the endothelial cells, only to be phagocytosed in the perivascular spaces. This holds true for many T and B cells, as well as monocytes, giving this small fluid filled space an important immunological role.[17]

Perivascular spaces also play an important role in immunoregulation; they not only contain interstitial and cerebrospinal fluid, but they also have a constant flux of macrophages, which is regulated by blood-borne mononuclear cells, but do not pass the basement membrane of the glia limitans.[17] Similarly, as part of its role in signal transmission, perivascular spaces contain vasoactive neuropeptides (VNs), which, aside from regulating blood pressure and heart rate, have an integral role in controlling microglia.[18] VNs serve to prevent inflammation by activating the enzyme adenylate cyclase which then produces cAMP. The production of cAMP aids in the modulation of auto-reactive T cells by regulatory T cells. .[19] The perivascular space is susceptible space for VN compromise and when their function is reduced in the space, immune response is adversely affected and the potential for degradation increases.[18][19] When inflammation by T cells begins, astrocytes begin to undergo apoptosis, due to their CD95 receptor, to open up the glia limitans and let T cells into the parenchyma of the brain.[17] Because this process is aided by the perivascular macrophages, these tend to accumulate during neuroinflammation and cause dilation of the spaces.[18]

Clinical significance edit

The clinical significance of perivascular spaces comes primarily from their tendency to dilate. The importance of dilation is hypothesized to be based on changes in shape rather than size.[13] Enlarged spaces have been observed most commonly in the basal ganglia, specifically on the lenticulostriate arteries. They have also been observed along the paramedial mesencephalothalamic artery and the substantia nigra in the mesencephalon, the brain region below the insula, the dentate nucleus in the cerebellum, and the corpus callosum, as well as the brain region directly above it, the cingulate gyrus.[5] Upon the clinical application of MRI, it was shown in several studies that perivascular space dilation and lacunar strokes are the most commonly observed histological correlates of signaling abnormalities.[13]

Senescence edit

Dilation is most commonly and closely associated with aging. Dilation of perivascular spaces has been shown to correlate best with age, even when accompanying factors including hypertension, dementia, and white matter lesions are considered.[20] In the elderly, such dilation has been correlated with many symptoms and conditions that often affect the arterial walls, including vascular hypertension, arteriosclerosis, reduced cognitive capacity, dementia, and low post-mortem brain weight.[13] In addition to dilation among the elderly, dilation in young, healthy individuals can also be observed. This occurrence is rare and there has been no observed association in such cases with reduced cognitive function or white matter abnormalities.[13] When dilated VRS are observed in the corpus callosum, there is generally no neurological deficit associated. They are often observed in this region as cystic lesions with cerebrospinal-like fluid.[21]

Symptoms of dilation edit

Extreme dilation has been associated with several specific clinical symptoms. In cases of severe dilation in only one hemisphere, symptoms reported include a non-specific fainting attack, hypertension, positional vertigo, headache, early recall disturbances, and hemifacial tics. Symptoms associated with severe bilateral dilation include ear pain (which was reported to have resolved on its own), dementia, and seizures. This data was compiled from case studies of individuals with severe VRS dilation.[13] Considering the anatomical abnormality presented in such cases, these findings were considered surprising in that the symptoms were relatively mild. In most cases, there is in fact no mass effect associated with some VRS dilation. An exception to the mildness of clinical symptoms associated with VRS dilation is when there is extreme dilation in the lower mesencephalon at the junction between the substantia nigra and cerebral peduncle. In such cases, mild to moderate obstructive hydrocephalus was reported in most patients. Associated symptoms ranged from headaches to symptoms more severe than those just discussed in the cases of dilation in the cerebral hemispheres.[13] Other general symptoms associated with VRS dilation include headaches, dizziness, memory impairment, poor concentration, dementia, visual changes, oculomotor abnormality, tremors, seizures, limb weakness, and ataxia.[5]

Associated disorders edit

Dilation is a typical characteristic of several diseases and disorders. These include diseases from metabolic and genetic disorders such as mannosidosis, myotonic dystrophy, Lowe syndrome, and Coffin–Lowry syndrome. Dilation is also a common characteristic of diseases or disorders of vascular pathologies, including CADASIL (cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy), hereditary infantile hemiparesis, retinal arteriolar tortuosity and leukoencephalopathy, migraines, and vascular dementia. A third group of disorders typically associated with VRS dilation is neuroectodermal syndromes. This includes polycystic brains associated with ectodermal dysplasia, frontonasal dysplasia, and Joubert syndrome. There is a fourth miscellaneous group of disorders typically associated with dilation that includes autism in children, megalencephalopathy, secondary Parkinson's disease, recent-onset multiple sclerosis, and chronic alcoholism. Because dilation can be associated with several diseases but also observed in healthy patients, it is always important in the evaluation of VRS to study the tissue around the dilation via MRI and to consider the entire clinical context.[13]

Current research edit

Causes of dilated VRS edit

Much of the current research concerning Virchow–Robin spaces relates to their known tendency to dilate. Research is presently being performed in order to determine the exact cause of dilation in these perivascular spaces. Current theories include mechanical trauma resulting from cerebrospinal fluid pulsation, elongation of ectactic penetrating blood vessels, and abnormal vascular permeability leading to increased fluid exudation. Further research has implicated shrinkage or atrophy of surrounding brain tissue, perivascular demyelination, coiling of the arteries as they age, altered permeability of the arterial wall and obstruction of lymphatic drainage pathways.[13] In addition, insufficient fluid draining and injury to ischemic perivascular tissue resulting in an ex vacuo effect have been suggested as possible causes for dilated VRS.[5]Dilated VRS might also be linked to vascular damage, blood leakage and microaneurysm formation.[22]

Association of dilated VRS and other diseases edit

Recent and ongoing research has found associations between enlarged VRS and several disorders.

Dementia edit

At one point in time, dilated Virchow–Robin spaces were so commonly noted in autopsies of persons with dementia, they were believed to cause the disease. However, additional research is currently being performed in order to confirm or refute a direct connection between dilation of VRS and dementia.[15]

Analysis of VRS may distinguish dementia caused by arteriosclerotic microvascular disease from dementia caused by neurodegenerative disease. A 2005 study has evidenced that a substantial amount of VRS in the substantia innominata, lentiform nucleus, and the caudate nucleus of the basal ganglia may implicate dementia due to arteriosclerotic microvascular disease, in particular Ischemic Vascular Dementia, as opposed dementia due to neurodegenerative disease, specifically Alzheimer's disease and frontotemporal dementia. Thus, perhaps VRS dilation can be used to distinguish between diagnoses of vascular dementias and degenerative dementias.[23]

Alzheimer's disease edit

Some studies have assessed the spatial distribution and prevalence of VRS in people with Alzheimer's disease versus those without the disease. Researchers have found that while VRS appear to be correlated with natural aging, MR imaging reveals a greater prevalence of VRS in those with Alzheimer's.[24]

Cerebral amyloid angiopathy (CAA), a blood vessel failure often associated with Alzheimer's disease, utilizes dilated VRS to spread inflammation to the parenchyma. Because the VRS often have an extra membrane in gray matter, the ischemic CAA response is often observed in white matter.[25]

It has been hypothesized that the structure of VRS in the cerebral cortex may contribute to the development of Alzheimer's disease. In contrast to VRS of the basal ganglia, VRS in the cerebral cortex are surrounded by only one layer of leptomeninges. As such, VRS in the cerebral cortex may drain β-amyloid in interstitial fluid less effectively than VRS in the basal ganglia. The less-effective drainage may lead to the development of the β-amyloid plaques that characterize Alzheimer's disease. In support of this hypothesis, studies have noted the greater frequency of β-amyloid plaques in the cerebral cortex than in the basal ganglia of Alzheimer's disease patients.[8]

Stroke edit

Because dilated perivascular spaces are so closely correlated with cerebrovascular disease, there is much current research on their use as a diagnostic tool. In a recent study of 31 subjects, abnormal dilation, along with irregular CSF pulsation, were correlated with those subjects having three or more risk factors for strokes. Therefore, perivascular spaces are a possible novel biomarker for hemorrhagic strokes.[26]

CADASIL syndrome (cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy syndrome) is a hereditary stroke condition due to a Notch 3 gene mutation on Chromosome 19. Studies have noted that in comparison to family members lacking the affected haplotype that leads to the condition, an increased number of dilated spaces is observed in individuals with CADASIL. These perivascular spaces are localized primarily in the putamen and temporal subcortical white matter and they appear to correlate with age of the individual with the condition rather than severity of the disease itself.[27]

There has been a high risk of stroke associated with dilated perivascular spaces in the elderly according to the Framingham Stroke Risk Score.[15] In contrast, other studies have concluded that the dilation of these spaces is a normal phenomenon in aging with no association with arterosclerosis. This remains, therefore, an important point of research in the field.[13]

Multiple sclerosis edit

Similar to the research concerning a potential connection between perivascular spaces and Alzheimer's, MRI scans of people recently diagnosed with multiple sclerosis (MS) have been studied. Larger, more prevalent spaces have been observed in those with MS.[28] Additional studies with similar findings have suggested that the inflammatory cells which contribute to the demyelination that characterizes MS also attack the perivascular spaces. Studies using advanced MRI techniques will be necessary to determine if the perivascular spaces can be implicated as a potential marker of the disease.[29]

Autism edit

Dilated perivascular spaces are common among the elderly and uncommon in children. Studies have noted the association between both developmental delay and non-syndromic autism and enlarged or dilated perivascular spaces.[30][31] Non-syndromic autism categorizes autistic patients for which there is no known cause.[30]

History edit

The appearance of perivascular spaces was first noted in 1843 by Durant-Fardel.[7] In 1851, Rudolph Virchow was the first to provide a detailed description of these microscopic spaces between the outer and inner/middle lamina of the brain vessels. Charles-Philippe Robin confirmed these findings in 1859 and was the first to describe the perivascular spaces as channels that existed in normal anatomy. The spaces were called Virchow-Robin spaces and are still also known as such. The immunological significance was discovered by Wilhelm His, Sr. in 1865 based on his observations of the flow of interstitial fluid over the spaces to the lymphatic system.[13]

For many years after Virchow-Robin spaces were first described, it was thought that they were in free communication with the cerebrospinal fluid in the subarachnoid space. It was later shown with the use of electron microscopy that the pia mater serves as separation between the two. Upon the application of MRI, measurements of the differences of signal intensity between the perivascular spaces and cerebrospinal fluid supported these findings.[13] As research technologies continued to expand, so too did information regarding their function, anatomy and clinical significance.

References edit

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January 01, 1970
perivascular, space, perivascular, space, also, known, virchow, robin, space, fluid, filled, space, surrounding, certain, blood, vessels, several, organs, including, brain, potentially, having, immunological, function, more, broadly, dispersive, role, neural, . A perivascular space also known as a Virchow Robin space is a fluid filled space surrounding certain blood vessels in several organs including the brain 1 potentially having an immunological function but more broadly a dispersive role for neural and blood derived messengers 2 The brain pia mater is reflected from the surface of the brain onto the surface of blood vessels in the subarachnoid space In the brain perivascular cuffs are regions of leukocyte aggregation in the perivascular spaces usually found in patients with viral encephalitis Perivascular spaceA perivascular space as seen on CTAnatomical terms of neuroanatomy edit on Wikidata CT image showing extensive low attenuation in the right hemispheric white matter due to dilated Type 2 perivascular spaces Axial fat suppressed T2 weighted MRI image in the same patient as above demonstrating extensive dilated Type 2 perivascular spaces in the right hemisphere Perivascular space is depicted in the inset box Perivascular spaces vary in dimension according to the type of blood vessel In the brain where most capillaries have an imperceptible perivascular space select structures of the brain such as the circumventricular organs are notable for having large perivascular spaces surrounding highly permeable capillaries as observed by microscopy The median eminence a brain structure at the base of the hypothalamus contains capillaries with wide perivascular spaces 3 In humans perivascular spaces surround arteries and veins can usually be seen as areas of dilatation on MRI images While many normal brains will show a few dilated spaces an increase in these spaces may correlate with the incidence of several neurodegenerative diseases making the spaces a topic of research 4 Contents 1 Structure 2 Function 3 Clinical significance 3 1 Senescence 3 2 Symptoms of dilation 3 3 Associated disorders 4 Current research 4 1 Causes of dilated VRS 4 2 Association of dilated VRS and other diseases 4 2 1 Dementia 4 2 2 Alzheimer s disease 4 2 3 Stroke 4 2 4 Multiple sclerosis 4 2 5 Autism 5 History 6 ReferencesStructure editPerivascular spaces are gaps containing interstitial fluid that span between blood vessels and their host organ such as the brain which they penetrate and serve as extravascular channels through which solutes can pass 2 5 Like the blood vessels around which they form perivascular spaces are found in both the brain subarachnoid space and the subpial space 6 Perivascular spaces surrounding arteries in the cerebral cortex and the basal ganglia are separated from the subpial space by one or two layers of leptomeninges respectively as well as the pia mater 7 By virtue of the leptomeningeal cell layer the perivascular spaces belonging to the subarachnoid space are continuous with those of the subpial space The direct communication between the perivascular spaces of the subarachnoid space and the subpial space is unique to the brain s arteries as no leptomeningeal layers surround the brain s veins 7 6 Use of the scanning electron microscope has determined that the spaces surrounding blood vessels in the subarachnoid space are not continuous with the subarachnoid space because of the presence of pia mater cells joined by desmosomes 8 Perivascular spaces especially around fenestrated capillaries are found in many organs such as the thymus liver kidneys spleen bones and pineal gland 9 10 11 12 Particularly within the brain circumventricular organs subfornical organ area postrema and median eminence large perivascular spaces are present around fenestrated capillaries indicating that the spaces serve a dispersive role for brain or bloodborne messengers 2 Perivascular spaces may be enlarged to a diameter of five millimeters in healthy humans and do not imply disease When enlarged they can disrupt the function of the brain regions into which they project 5 Dilation can occur on one or both sides of the brain 7 Dilated perivascular spaces are categorized into three types 7 Type 1 are located on the lenticulostriate arteries projecting into the basal ganglia Type 2 are located in the cortex following the path of the medullary arteries Type 3 are located in the midbrain Perivascular spaces are most commonly located in the basal ganglia and white matter of the cerebrum and along the optic tract 13 The ideal method used to visualize perivascular spaces is T2 weighted MRI The MR images of other neurological disorders can be similar to those of the dilated spaces These disorders are 7 cystic neoplasms lacunar infarctions cystic periventricular leukomalacia cryptococcosis multiple sclerosis mucopolysaccharidoses neurocysticercosis arachnoid cysts neuroepithelial cysts Perivascular spaces are distinguished on an MRI by several key features The spaces appear as distinct round or oval entities with a signal intensity visually equivalent to that of cerebrospinal fluid in the subarachnoid space 7 14 15 In addition a perivascular space has no mass effect and is located along the blood vessel around which it forms 14 Function editOne of the most basic roles of the perivascular space is the regulation of fluid movement in the central nervous system and its drainage 13 The spaces ultimately drain fluid from neuronal cell bodies to the cervical lymph nodes 5 In particular the tide hypothesis suggests that the cardiac contraction creates and maintains pressure waves to modulate the flow to and from the subarachnoid space and the perivascular space 16 By acting as a sort of sponge they are essential for signal transmission and the maintenance of extracellular fluid 16 Another function is as an integral part of the blood brain barrier BBB 17 While the BBB is often described as the tight junctions between the endothelial cells this is an oversimplification that neglects the intricate role that perivascular spaces take in separating the venous blood from the parenchyma of the brain Often cell debris and foreign particles which are impermeable to the BBB will get through the endothelial cells only to be phagocytosed in the perivascular spaces This holds true for many T and B cells as well as monocytes giving this small fluid filled space an important immunological role 17 Perivascular spaces also play an important role in immunoregulation they not only contain interstitial and cerebrospinal fluid but they also have a constant flux of macrophages which is regulated by blood borne mononuclear cells but do not pass the basement membrane of the glia limitans 17 Similarly as part of its role in signal transmission perivascular spaces contain vasoactive neuropeptides VNs which aside from regulating blood pressure and heart rate have an integral role in controlling microglia 18 VNs serve to prevent inflammation by activating the enzyme adenylate cyclase which then produces cAMP The production of cAMP aids in the modulation of auto reactive T cells by regulatory T cells 19 The perivascular space is susceptible space for VN compromise and when their function is reduced in the space immune response is adversely affected and the potential for degradation increases 18 19 When inflammation by T cells begins astrocytes begin to undergo apoptosis due to their CD95 receptor to open up the glia limitans and let T cells into the parenchyma of the brain 17 Because this process is aided by the perivascular macrophages these tend to accumulate during neuroinflammation and cause dilation of the spaces 18 Clinical significance editThe clinical significance of perivascular spaces comes primarily from their tendency to dilate The importance of dilation is hypothesized to be based on changes in shape rather than size 13 Enlarged spaces have been observed most commonly in the basal ganglia specifically on the lenticulostriate arteries They have also been observed along the paramedial mesencephalothalamic artery and the substantia nigra in the mesencephalon the brain region below the insula the dentate nucleus in the cerebellum and the corpus callosum as well as the brain region directly above it the cingulate gyrus 5 Upon the clinical application of MRI it was shown in several studies that perivascular space dilation and lacunar strokes are the most commonly observed histological correlates of signaling abnormalities 13 Senescence edit Dilation is most commonly and closely associated with aging Dilation of perivascular spaces has been shown to correlate best with age even when accompanying factors including hypertension dementia and white matter lesions are considered 20 In the elderly such dilation has been correlated with many symptoms and conditions that often affect the arterial walls including vascular hypertension arteriosclerosis reduced cognitive capacity dementia and low post mortem brain weight 13 In addition to dilation among the elderly dilation in young healthy individuals can also be observed This occurrence is rare and there has been no observed association in such cases with reduced cognitive function or white matter abnormalities 13 When dilated VRS are observed in the corpus callosum there is generally no neurological deficit associated They are often observed in this region as cystic lesions with cerebrospinal like fluid 21 Symptoms of dilation edit Extreme dilation has been associated with several specific clinical symptoms In cases of severe dilation in only one hemisphere symptoms reported include a non specific fainting attack hypertension positional vertigo headache early recall disturbances and hemifacial tics Symptoms associated with severe bilateral dilation include ear pain which was reported to have resolved on its own dementia and seizures This data was compiled from case studies of individuals with severe VRS dilation 13 Considering the anatomical abnormality presented in such cases these findings were considered surprising in that the symptoms were relatively mild In most cases there is in fact no mass effect associated with some VRS dilation An exception to the mildness of clinical symptoms associated with VRS dilation is when there is extreme dilation in the lower mesencephalon at the junction between the substantia nigra and cerebral peduncle In such cases mild to moderate obstructive hydrocephalus was reported in most patients Associated symptoms ranged from headaches to symptoms more severe than those just discussed in the cases of dilation in the cerebral hemispheres 13 Other general symptoms associated with VRS dilation include headaches dizziness memory impairment poor concentration dementia visual changes oculomotor abnormality tremors seizures limb weakness and ataxia 5 Associated disorders edit Dilation is a typical characteristic of several diseases and disorders These include diseases from metabolic and genetic disorders such as mannosidosis myotonic dystrophy Lowe syndrome and Coffin Lowry syndrome Dilation is also a common characteristic of diseases or disorders of vascular pathologies including CADASIL cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy hereditary infantile hemiparesis retinal arteriolar tortuosity and leukoencephalopathy migraines and vascular dementia A third group of disorders typically associated with VRS dilation is neuroectodermal syndromes This includes polycystic brains associated with ectodermal dysplasia frontonasal dysplasia and Joubert syndrome There is a fourth miscellaneous group of disorders typically associated with dilation that includes autism in children megalencephalopathy secondary Parkinson s disease recent onset multiple sclerosis and chronic alcoholism Because dilation can be associated with several diseases but also observed in healthy patients it is always important in the evaluation of VRS to study the tissue around the dilation via MRI and to consider the entire clinical context 13 Current research editCauses of dilated VRS edit Much of the current research concerning Virchow Robin spaces relates to their known tendency to dilate Research is presently being performed in order to determine the exact cause of dilation in these perivascular spaces Current theories include mechanical trauma resulting from cerebrospinal fluid pulsation elongation of ectactic penetrating blood vessels and abnormal vascular permeability leading to increased fluid exudation Further research has implicated shrinkage or atrophy of surrounding brain tissue perivascular demyelination coiling of the arteries as they age altered permeability of the arterial wall and obstruction of lymphatic drainage pathways 13 In addition insufficient fluid draining and injury to ischemic perivascular tissue resulting in an ex vacuo effect have been suggested as possible causes for dilated VRS 5 Dilated VRS might also be linked to vascular damage blood leakage and microaneurysm formation 22 Association of dilated VRS and other diseases edit Recent and ongoing research has found associations between enlarged VRS and several disorders Dementia edit At one point in time dilated Virchow Robin spaces were so commonly noted in autopsies of persons with dementia they were believed to cause the disease However additional research is currently being performed in order to confirm or refute a direct connection between dilation of VRS and dementia 15 Analysis of VRS may distinguish dementia caused by arteriosclerotic microvascular disease from dementia caused by neurodegenerative disease A 2005 study has evidenced that a substantial amount of VRS in the substantia innominata lentiform nucleus and the caudate nucleus of the basal ganglia may implicate dementia due to arteriosclerotic microvascular disease in particular Ischemic Vascular Dementia as opposed dementia due to neurodegenerative disease specifically Alzheimer s disease and frontotemporal dementia Thus perhaps VRS dilation can be used to distinguish between diagnoses of vascular dementias and degenerative dementias 23 Alzheimer s disease edit Some studies have assessed the spatial distribution and prevalence of VRS in people with Alzheimer s disease versus those without the disease Researchers have found that while VRS appear to be correlated with natural aging MR imaging reveals a greater prevalence of VRS in those with Alzheimer s 24 Cerebral amyloid angiopathy CAA a blood vessel failure often associated with Alzheimer s disease utilizes dilated VRS to spread inflammation to the parenchyma Because the VRS often have an extra membrane in gray matter the ischemic CAA response is often observed in white matter 25 It has been hypothesized that the structure of VRS in the cerebral cortex may contribute to the development of Alzheimer s disease In contrast to VRS of the basal ganglia VRS in the cerebral cortex are surrounded by only one layer of leptomeninges As such VRS in the cerebral cortex may drain b amyloid in interstitial fluid less effectively than VRS in the basal ganglia The less effective drainage may lead to the development of the b amyloid plaques that characterize Alzheimer s disease In support of this hypothesis studies have noted the greater frequency of b amyloid plaques in the cerebral cortex than in the basal ganglia of Alzheimer s disease patients 8 Stroke edit Because dilated perivascular spaces are so closely correlated with cerebrovascular disease there is much current research on their use as a diagnostic tool In a recent study of 31 subjects abnormal dilation along with irregular CSF pulsation were correlated with those subjects having three or more risk factors for strokes Therefore perivascular spaces are a possible novel biomarker for hemorrhagic strokes 26 CADASIL syndrome cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy syndrome is a hereditary stroke condition due to a Notch 3 gene mutation on Chromosome 19 Studies have noted that in comparison to family members lacking the affected haplotype that leads to the condition an increased number of dilated spaces is observed in individuals with CADASIL These perivascular spaces are localized primarily in the putamen and temporal subcortical white matter and they appear to correlate with age of the individual with the condition rather than severity of the disease itself 27 There has been a high risk of stroke associated with dilated perivascular spaces in the elderly according to the Framingham Stroke Risk Score 15 In contrast other studies have concluded that the dilation of these spaces is a normal phenomenon in aging with no association with arterosclerosis This remains therefore an important point of research in the field 13 Multiple sclerosis edit Similar to the research concerning a potential connection between perivascular spaces and Alzheimer s MRI scans of people recently diagnosed with multiple sclerosis MS have been studied Larger more prevalent spaces have been observed in those with MS 28 Additional studies with similar findings have suggested that the inflammatory cells which contribute to the demyelination that characterizes MS also attack the perivascular spaces Studies using advanced MRI techniques will be necessary to determine if the perivascular spaces can be implicated as a potential marker of the disease 29 Autism edit Dilated perivascular spaces are common among the elderly and uncommon in children Studies have noted the association between both developmental delay and non syndromic autism and enlarged or dilated perivascular spaces 30 31 Non syndromic autism categorizes autistic patients for which there is no known cause 30 History editThe appearance of perivascular spaces was first noted in 1843 by Durant Fardel 7 In 1851 Rudolph Virchow was the first to provide a detailed description of these microscopic spaces between the outer and inner middle lamina of the brain vessels Charles Philippe Robin confirmed these findings in 1859 and was the first to describe the perivascular spaces as channels that existed in normal anatomy The spaces were called Virchow Robin spaces and are still also known as such The immunological significance was discovered by Wilhelm His Sr in 1865 based on his observations of the flow of interstitial fluid over the spaces to the lymphatic system 13 For many years after Virchow Robin spaces were first described it was thought that they were in free communication with the cerebrospinal fluid in the subarachnoid space It was later shown with the use of electron microscopy that the pia mater serves as separation between the two Upon the application of MRI measurements of the differences of signal intensity between the perivascular spaces and cerebrospinal fluid supported these findings 13 As research technologies continued to expand so too did information regarding their function anatomy and clinical significance References edit Norrving Bo 2016 Lacunar Syndromes Lacunar Infarcts and Cerebral Small vessel Disease Stroke Elsevier pp 449 465 e4 doi 10 1016 b978 0 323 29544 4 00027 x ISBN 978 0 323 29544 4 Perivascular spaces are fluid filled spaces that follow a typical course of a vessel penetrating transversing the brain through gray or white matter 89 a b c Gross PM Weindl A 1987 Peering through the windows of the brain Review Journal of Cerebral Blood Flow and Metabolism 7 6 663 72 doi 10 1038 jcbfm 1987 120 PMID 2891718 Shaver SW Pang JJ Wainman DS Wall KM Gross PM 1992 Morphology and function of capillary networks in subregions of the rat tuber cinereum Cell and Tissue Research 267 3 437 48 doi 10 1007 bf00319366 PMID 1571958 S2CID 27789146 Esiri MM Gay D 1990 Immunological and neuropathological significance of the Virchow Robin space Journal of the Neurological Sciences 100 1 2 3 8 doi 10 1016 0022 510X 90 90004 7 PMID 2089138 S2CID 39929713 a b c d e f Fayeye Oluwafikay Pettorini Benedetta Ludovica Foster Katharine Rodrigues Desiderio 2010 Mesencephalic enlarged Virchow Robin spaces in a 6 year old boy a case based update Child s Nervous System 26 9 1155 1160 doi 10 1007 s00381 010 1164 4 PMID 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Munnich Arnold Samson Yves Mouren Marie Christine Chabane Nadia 2009 MRI Findings in 77 Children with Non Syndromic Autistic Disorder PLOS ONE 4 2 e4415 Bibcode 2009PLoSO 4 4415B doi 10 1371 journal pone 0004415 PMC 2635956 PMID 19204795 Zeegers Mijke Van Der Grond Jeroen Durston Sarah Jan Nievelstein Rutger Witkamp Theo Van Daalen Emma Buitelaar Jan Van Engeland Herman 2006 Radiological findings in autistic and developmentally delayed children Brain and Development 28 8 495 9 doi 10 1016 j braindev 2006 02 006 PMID 16616445 S2CID 41735789 Retrieved from https en wikipedia org w index php title Perivascular space amp oldid 1214978058, wikipedia, wiki, book, books, library,

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