Fabrication of three-dimensional hydrogel scaffolds for modeling shunt failure by tissue obstruction in hydrocephalus

Harris, Carolyn A.; Pearson, Kelsie; Hadley, Kristen; Zhu, Shanshan; Browd, Samuel R.; Hanak, Brian W.; Shain, William

doi:10.1186/s12987-015-0023-9

Cited by 19 publications

(32 citation statements)

References 49 publications

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“…Recent long-term in vivo data collected in our lab indicate that inflammatory astrocytes are ubiquitous on all shunts; they make up more than 21% of cells bound to obstructed shunts, and of the occluded masses blocking ventricular catheter holes, a vast majority of the cells are astrocytes, and their number and reactivity peak on failed shunts. Our data corroborate other reports suggesting that inflammatory astrocyte activation on shunts is correlated to a change in flow rate through the shunt holes and indirectly, the shear rate through these holes 10 , 15 – 17 . Astrocytes have an increased attachment propensity in vitro with increasing flow-induced shear stress.…”

Section: Introductionsupporting

confidence: 92%

A high-resolution real-time quantification of astrocyte cytokine secretion under shear stress for investigating hydrocephalus shunt failure

2021

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It has been hypothesized that physiological shear forces acting on medical devices implanted in the brain significantly accelerate the rate to device failure in patients with chronically indwelling neuroprosthetics. In hydrocephalus shunt devices, shear forces arise from cerebrospinal fluid flow. The shunt’s unacceptably high failure rate is mostly due to obstruction with adherent inflammatory cells. Astrocytes are the dominant cell type bound directly to obstructing shunts, rapidly manipulating their activation via shear stress-dependent cytokine secretion. Here we developed a total internal reflection fluorescence microscopy combined with a microfluidic shear device chip (MSDC) for quantitative analysis and direct spatial-temporal mapping of secreted cytokines at the single-cell level under physiological shear stress to identify the root cause for shunt failure. Real-time secretion imaging at 1-min time intervals enabled successful detection of a significant increase of astrocyte IL-6 cytokine secretion under shear stress greater than 0.5 dyne/cm2, validating our hypothesis and highlighting the importance of reducing shear stress activation of cells.

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Section: Introductionsupporting

confidence: 92%

A high-resolution real-time quantification of astrocyte cytokine secretion under shear stress for investigating hydrocephalus shunt failure

2021

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“…This fluid buildup can be caused by an imbalance between the production and absorption of the CSF within the brain with the root variable etiology, including precursors such as hemorrhage, congenital malformations, and tumors (1),(2), (5) . Treatment typically involves the insertion of a shunt system, including a shunt catheter into the brain's ventricular space to drain excess CSF (6) . Shunt failure is one of the highest among all neurological devices with 40-50% requiring revision within the first two years and 80% within 10 years (7), (8) .…”

Section: Introductionmentioning

confidence: 99%

“…Shunt failure is one of the highest among all neurological devices with 40-50% requiring revision within the first two years and 80% within 10 years (7), (8) . Obstruction of the ventricular catheter accounts for 70% of shunt failures, which makes it the most prevalent failure modality compared to infection, over-drainage, and loculated ventricles (6) . The dominant cell types involved in the blocking of these holes are astrocytes and cells of the monocyte-macrophage lineage, suspected to be due to inflammatory stimuli (6),( 9), (10) .…”

Section: Introductionmentioning

confidence: 99%

“…An inflammatory response occurs within the ventricles following the infiltration of blood, which stimulates the activation of astrocytes and microglia (10), (19) . This astrocyte and microglia activation is maintained for up to 28 days post shunt insertion (20) .…”

Section: Introductionmentioning

confidence: 99%

“…Glial activation is a result of various cytokines and growth factors produced by the activated microglia and leads to the rapid proliferation of astrocytes (20)- (22) . In response to this activation, an astrocyte layer is created to cover the denuded areas, from loss of ependymal cells, which was shown to increase cellular migration and attachment to the shunt surface (19), (23) . Blood within the CSF has been shown, in vivo , to cause an increase in shunt obstruction causing failure making up 34.8% of shunt revisions (24) .…”

Section: Introductionmentioning

confidence: 99%

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Response of Astrocytes to Blood Exposure due to Shunt Insertion in vitro

Zaranek

Arshad

Zheng

et al. 2021

Preprint

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The breakdown of the ventricular zone (VZ) with the presence of blood in cerebrospinal fluid (CSF) has been shown to increase shunt catheter obstruction in the treatment of hydrocephalus, but the mechanisms by which this occurs are generally unknown. Using a custom-built incubation chamber, we immunofluorescently assayed cell attachment and morphology on shunt catheters with and without blood after 14 days. Samples exposed to blood showed significantly increased cell attachment (average total cell count 392.0±317.1 versus control of 94.7±44.5, P<0.0001). Analysis of the glial fibrillary acidic protein (GFAP) expression showed similar trends (854.4±450.7 versus control of 174.3±116.5, P<0.0001). An in vitro model was developed to represent the exposure of astrocytes to blood following an increase in BBB permeability. Exposure of astrocytes to blood increases the number of cells and their spread on the shunt.

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Response of astrocytes to blood exposure due to shunt insertion in vitro

et al. 2021

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The breakdown of the ventricular zone with the presence of blood in cerebrospinal fluid has been shown to increase shunt catheter obstruction in the treatment of hydrocephalus, but the mechanisms by which this occurs are generally unknown. Using a custom‐built incubation chamber, we immunofluorescently assayed cell attachment and morphology on shunt catheters with and without blood after 14 days. Samples exposed to blood showed significantly increased cell attachment (average total cell count 392.0 ± 317.1 vs. control of 94.7 ± 44.5, p < 0.0001). Analysis of the glial fibrillary acidic protein expression showed similar trends (854.4 ± 450.7 vs. control of 174.3 ± 116.5, p < 0.0001). An in vitro model was developed to represent the exposure of astrocytes to blood following an increase in blood–brain barrier permeability. Exposure of astrocytes to blood increases the number of cells and their spread on the shunt.

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Fabrication of three-dimensional hydrogel scaffolds for modeling shunt failure by tissue obstruction in hydrocephalus

Cited by 19 publications

References 49 publications

A high-resolution real-time quantification of astrocyte cytokine secretion under shear stress for investigating hydrocephalus shunt failure

A high-resolution real-time quantification of astrocyte cytokine secretion under shear stress for investigating hydrocephalus shunt failure

Response of Astrocytes to Blood Exposure due to Shunt Insertion in vitro

Response of astrocytes to blood exposure due to shunt insertion in vitro

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