Precapillary sphincters and pericytes at first-order capillaries as key regulators for brain capillary perfusion

Zambach, Stefan Andreas; Cai, Changsi; Helms, Hans Christian Cederberg; Hald, Bjørn Olav; Dong, Yiqiu; Fordsmann, Jonas Christoffer; Murmu, Reena Prity; Hu, Jingshi; Lønstrup, Micael; Brodin, Birger; Lauritzen, Martin

doi:10.1073/pnas.2023749118

Cited by 67 publications

(67 citation statements)

References 65 publications

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“…injection or incubation of tissue with AlexaFluor 633 hydrazide ( Shen et al, 2012 ), but its role in microvascular regulation remains understudied. Recently, however, it has been used to identify intracortical arterioles in which endothelial caveolae were found to be critical players in neurovascular coupling ( Chow et al, 2020 ), and was found around precapillary sphincters branching off penetrating arterioles that regulate blood flow and pressure into the cortical capillary network ( Grubb et al, 2020 ; Zambach et al, 2021 ).…”

Section: Resultsmentioning

confidence: 99%

“…However, the same group found much more variable timings in neocortex of ketamine-medetomidine anaesthetized or awake mice, with capillaries or arterioles each being faster on some occasions ( Rungta et al, 2021 ), and in both these reports, mid-capillary dilations were very small (though these data conflate responders and non-responders, unlike some other studies, Hall et al, 2014 ; Shaw et al, 2021 ). Precapillary sphincters, where studied, have often shown larger dilations, as a proportion of their diameter, than adjacent arterioles and capillaries ( Grubb et al, 2020 ; Zambach et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

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Gradual Not Sudden Change: Multiple Sites of Functional Transition Across the Microvascular Bed

Shaw

Boyd

Anderle

et al. 2022

Front. Aging Neurosci.

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In understanding the role of the neurovascular unit as both a biomarker and target for disease interventions, it is vital to appreciate how the function of different components of this unit change along the vascular tree. The cells of the neurovascular unit together perform an array of vital functions, protecting the brain from circulating toxins and infection, while providing nutrients and clearing away waste products. To do so, the brain’s microvasculature dilates to direct energy substrates to active neurons, regulates access to circulating immune cells, and promotes angiogenesis in response to decreased blood supply, as well as pulsating to help clear waste products and maintain the oxygen supply. Different parts of the cerebrovascular tree contribute differently to various aspects of these functions, and previously, it has been assumed that there are discrete types of vessel along the vascular network that mediate different functions. Another option, however, is that the multiple transitions in function that occur across the vascular network do so at many locations, such that vascular function changes gradually, rather than in sharp steps between clearly distinct vessel types. Here, by reference to new data as well as by reviewing historical and recent literature, we argue that this latter scenario is likely the case and that vascular function gradually changes across the network without clear transition points between arteriole, precapillary arteriole and capillary. This is because classically localized functions are in fact performed by wide swathes of the vasculature, and different functional markers start and stop being expressed at different points along the vascular tree. Furthermore, vascular branch points show alterations in their mural cell morphology that suggest functional specializations irrespective of their position within the network. Together this work emphasizes the need for studies to consider where transitions of different functions occur, and the importance of defining these locations, in order to better understand the vascular network and how to target it to treat disease.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Gradual Not Sudden Change: Multiple Sites of Functional Transition Across the Microvascular Bed

Shaw

Boyd

Anderle

et al. 2022

Front. Aging Neurosci.

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“…Theoretically, the decrease in MCAv observed in med-highs during hyperventilation despite scarce changes in ABP, could be sustained by the sensitivity of their vessels muscle cells to blood pressure. The preferential effect of NO on precapillary sphincters and pericytes rather than on smooth muscle cells [67] may have contributed to the observed changes in MCAv. The lack of significant correlation between ΔMCAv and ΔPETCO2 occurring in both groups during rebreathing may be due to CO2 ceiling effect.…”

Section: Correlational Analysesmentioning

confidence: 96%

Hypnotizability-Related Cerebral Blood Flow

Rashid¹,

Santarcangelo²,

Roatta³

2022

Preprint

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Hypnotizability is a cognitive trait associated with differences in the brachial artery flow-mediated dilatation of individuals with high hypnotizability (highs) and low hypnotizability scores (lows). The study investigated possible hypnotizability-related cerebrovascular differences. Among 24 healthy volunteers the Stanford Hypnotic Susceptibility Scale Form A, identified 13 medium-to-lows (med-lows), 11 medium-to-highs (med-highs), 1 medium hypnotizable. Hypnotizability did not influence the significant changes produced by the trail making task (TMT), mental arithmetic task (MAT), hyperventilation (HVT) and rebreathing (RBT) on Heart rate (HR), arterial blood pressure (ABP) and partial pressure of end-tidal CO2 (PETCO2) and oxygenation (TOI); but moderated the correlations between the changes occurring during tasks with respect to basal conditions (Δ) in ABP and PETCO2 with MCAv. In HVT, med-lows exhibited a significant correlation between ΔMCAv and ΔPETCO2, med-highs showed a significant correlation between ΔABP and ΔMCAv; a significant correlation between ΔTHI and ΔTOI was observed in medium lows. Cerebrovascular reactivity (CVR) and conductance (ΔCVCi) were significantly correlated with ΔMCAv in med-lows during HVT and RBT. Findings represent the first assessment of hypnotizability-related differences in the mechanisms controlling the middle cerebral artery flow velocity, cerebrovascular reactivity and conductance in response to hyperventilation and rebreathing.

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“…However, once again, it is at the capillary level that the astrocyte foot processes have the greatest influence [ 4 , 8 ]. The question of whether the capillaries themselves are responsible for the autonomous increase or decrease in the size of the vascular bed draws attention to the function of the pericytes that reside here [ 24 , 25 , 26 , 27 , 28 ]. It has long been reported that pericytes contain actin filaments, which have a contractile effect.…”

Section: Functional Hyperemia At the Capillary Levelmentioning

confidence: 99%

“…Regulation of the CBF is mainly mediated by vascular smooth muscle contraction and relaxation at the level of the upstream arterioles. However, it has been pointed out that pericytes may be involved in the dilatation and contraction of microvessels even at the capillary level [ 24 , 25 , 26 , 27 , 28 ]. In addition to pericyte regulation, the capillary bed size may also be actively regulated by an increase or decrease in water content in the Virchow–Robin space [ 29 , 30 , 31 ], the space between the astrocytic end feet and the outer surfaces of the microvessels.…”

Section: Introductionmentioning

confidence: 99%

Metabolic Contribution and Cerebral Blood Flow Regulation by Astrocytes in the Neurovascular Unit

Takahashi

2022

Cells

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The neurovascular unit (NVU) is a conceptual framework that has been proposed to better explain the relationships between the neural cells and blood vessels in the human brain, focused mainly on the brain gray matter. The major components of the NVU are the neurons, astrocytes (astroglia), microvessels, pericytes, and microglia. In addition, we believe that oligodendrocytes should also be included as an indispensable component of the NVU in the white matter. Of all these components, astrocytes in particular have attracted the interest of researchers because of their unique anatomical location; these cells are interposed between the neurons and the microvessels of the brain. Their location suggests that astrocytes might regulate the cerebral blood flow (CBF) in response to neuronal activity, so as to ensure an adequate supply of glucose and oxygen to meet the metabolic demands of the neurons. In fact, the adult human brain, which accounts for only 2% of the entire body weight, consumes approximately 20–25% of the total amount of glucose and oxygen consumed by the whole body. The brain needs a continuous supply of these essential energy sources through the CBF, because there are practically no stores of glucose or oxygen in the brain; both acute and chronic cessation of CBF can adversely affect brain functions. In addition, another important putative function of the NVU is the elimination of heat and waste materials produced by neuronal activity. Recent evidence suggests that astrocytes play pivotal roles not only in supplying glucose, but also fatty acids and amino acids to neurons. Loss of astrocytic support can be expected to lead to malfunction of the NVU as a whole, which underlies numerous neurological disorders. In this review, we shall focus on historical and recent findings with regard to the metabolic contributions of astrocytes in the NVU.

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Precapillary sphincters and pericytes at first-order capillaries as key regulators for brain capillary perfusion

Cited by 67 publications

References 65 publications

Gradual Not Sudden Change: Multiple Sites of Functional Transition Across the Microvascular Bed

Gradual Not Sudden Change: Multiple Sites of Functional Transition Across the Microvascular Bed

Hypnotizability-Related Cerebral Blood Flow

Metabolic Contribution and Cerebral Blood Flow Regulation by Astrocytes in the Neurovascular Unit

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