Ca<sup>2+</sup>Oscillation in Vascular Smooth Muscle Cells Control Myogenic Spontaneous Vasomotion and Counteract Post-ischemic No-reflow

Li, Jinze; Zhang, Yiyi; Zhang, Dongdong; Wang, Wentao; Xie, Huiqi; Ruan, Jiayu; Jin, Yuxiao; Li, Tingbo; Li, Xuzhao; Zhao, Bingrui; Zhang, Xiaoxuan; Lin, Jiayi; Shi, Hongjun; Jia, Jie-Min

doi:10.1101/2023.12.17.572091

2023

DOI: 10.1101/2023.12.17.572091

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Ca²⁺Oscillation in Vascular Smooth Muscle Cells Control Myogenic Spontaneous Vasomotion and Counteract Post-ischemic No-reflow

Jinze Li,

Yiyi Zhang,

Dongdong Zhang

et al.

Abstract: Ischemic stroke produces the highest adult disability. Despite successful recanalization, no-reflow, or the futile restoration of the cerebral perfusion after ischemia, is a major cause of brain lesion expansion. However, the vascular mechanism underlying this hypoperfusion is largely unknown, and no approach is available to actively promote optimal reperfusion to treat no-reflow. Here, by combining two-photon laser scanning microscopy (2PLSM) and a mouse middle cerebral arteriolar occlusion (MCAO) model, we f… Show more

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High-resolution vasomotion analysis reveals novel arteriole physiological features and progressive modulation of cerebral vascular networks by stroke

Zhang,

Li,

Xie

et al. 2023

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Spontaneous cerebral vasomotion, characterized by ∼0.1 Hz rhythmic contractility, is crucial for brain homeostasis. However, our understanding of vasomotion is limited due to a lack of high-precision analytical methods to determine single vasomotion events at basal levels. Here, we developed a novel strategy that integrates a baseline smoothing algorithm, allowing precise measurements of vasodynamics and concomitant Ca2+dynamics in mouse cerebrovasculature imaged by two-photon microscopy. We identified several previously unrecognized vasomotion properties under different physiological and pathological conditions especially in ischemic stroke which is a frequently occurring and highly harmful brain disease result in brain damage and significant neurological impairments that originates from vessel occlusion. First, venules exhibit motion with a ∼0.1-Hz peak in the power spectrum; energy at this frequency is depleted by anesthetics, signifying a novel aspect of venule physiology related to basal neural activity. Second, compared to previous diameter-based estimations, our radius-based measurements reveal nonisotropic vascular movements, enabling a more precise determination of the latency between smooth muscle cell (SMC) Ca2+activity and vasocontraction. Third, Ca2+dynamics were larger in venular pericytes than in arteriolar SMCs while unrelated to venule vasomotion. Fourth, we characterized single vasomotion event kinetics at scales of less than 4 seconds. Finally, following pathological vasoconstrictions induced by ischemic stroke, vasoactive arterioles transitioned to an inert state and persisted despite recanalization. In summary, we developed a highly accurate technique for analyzing spontaneous vasomotion, and we suggest a potential strategy to reduce stroke damage by promoting vasomotion recovery.

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High-resolution vasomotion analysis reveals novel arteriole physiological features and progressive modulation of cerebral vascular networks by stroke

Zhang,

Li,

Xie

et al. 2023

Preprint

Self Cite

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show abstract

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Ca²⁺Oscillation in Vascular Smooth Muscle Cells Control Myogenic Spontaneous Vasomotion and Counteract Post-ischemic No-reflow

Cited by 1 publication

References 65 publications

High-resolution vasomotion analysis reveals novel arteriole physiological features and progressive modulation of cerebral vascular networks by stroke

High-resolution vasomotion analysis reveals novel arteriole physiological features and progressive modulation of cerebral vascular networks by stroke

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Ca2+Oscillation in Vascular Smooth Muscle Cells Control Myogenic Spontaneous Vasomotion and Counteract Post-ischemic No-reflow

Cited by 1 publication

References 65 publications

High-resolution vasomotion analysis reveals novel arteriole physiological features and progressive modulation of cerebral vascular networks by stroke

High-resolution vasomotion analysis reveals novel arteriole physiological features and progressive modulation of cerebral vascular networks by stroke

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Ca²⁺Oscillation in Vascular Smooth Muscle Cells Control Myogenic Spontaneous Vasomotion and Counteract Post-ischemic No-reflow