Real-Time Imaging Assessment of Stress-Induced Vascular Inflammation Using Heartbeat-Synchronized Motion Compensation.

IF 7.4 1区医学 Q1 HEMATOLOGY

Arteriosclerosis, Thrombosis, and Vascular Biology Pub Date : 2024-12-01 Epub Date: 2024-10-10 DOI:10.1161/ATVBAHA.124.321566

Minseok A Jang, Joon Woo Song, Ryeong Hyun Kim, Dong Oh Kang, Ungyo Kang, Hyun Jung Kim, Jin Hyuk Kim, Eun Jin Park, Ye Hee Park, Bo-Hyung Lee, Chi Kyung Kim, Kyeongsoon Park, Jin Won Kim, Hongki Yoo

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Abstract

Background: Chronic mental stress accelerates atherosclerosis through complicated neuroimmune pathways, needing for advanced imaging techniques to delineate underlying cellular mechanisms. While histopathology, ex vivo imaging, and snapshots of in vivo images offer promising evidence, they lack the ability to capture real-time visualization of blood cell dynamics within pulsatile arteries in longitudinal studies.

Methods: An electrically tunable lens was implemented in intravital optical microscopy, synchronizing the focal plane with heartbeats to follow artery movements. ApoE^-/- mice underwent 2 weeks of restraint stress before baseline imaging followed by 2 weeks of stress exposure in the longitudinal imaging, while nonstressed mice remained undisturbed. The progression of vascular inflammation was assessed in the carotid arteries through intravital imaging and histological analyses.

Results: A 4-fold reduction of motion artifact, assessed by interframe SD, and an effective temporal resolution of 25.2 Hz were achieved in beating murine carotid arteries. Longitudinal intravital imaging showed chronic stress led to a 6.09-fold (P=0.017) increase in myeloid cell infiltration compared with nonstressed mice. After 3 weeks, we observed that chronic stress intensified vascular inflammation, increasing adhered myeloid cells by 2.45-fold (P=0.031), while no significant changes were noted in nonstressed mice. Microcirculation imaging revealed increased circulating, rolling, and adhered cells in stressed mice's venules. Histological analysis of the carotid arteries confirmed the in vivo findings that stress augmented plaque area, myeloid cell and macrophage accumulation, and necrotic core volume while reducing fibrous cap thickness indicating accelerated plaque formation. We visualized the 3-dimensional structure of the carotid artery and 4-dimensional dynamics of the venules in the cremaster muscle.

Conclusions: Dynamic focusing motion compensation intravital microscopy enabled subcellular resolution in vivo imaging of blood cell dynamics in beating arteries under chronic restraint stress in real time. This novel technique emphasizes the importance of advanced in vivo imaging for understanding cardiovascular disease.

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利用心跳同步运动补偿对压力诱发的血管炎症进行实时成像评估

背景：慢性精神压力会通过复杂的神经免疫途径加速动脉粥样硬化，需要先进的成像技术来描述潜在的细胞机制。虽然组织病理学、体外成像和体内图像快照提供了有希望的证据，但它们缺乏在纵向研究中捕捉搏动动脉内血细胞动态实时可视化的能力：方法：在体内光学显微镜中安装了电动可调透镜，使焦平面与心跳同步，以跟踪动脉运动。载脂蛋白E-/-小鼠在基线成像前接受2周的束缚应激，然后在纵向成像中接受2周的应激暴露，而未受应激的小鼠则保持不受干扰。通过颈内成像和组织学分析评估了颈动脉血管炎症的进展：结果：在跳动的小鼠颈动脉中，通过帧间标度评估，运动伪影减少了 4 倍，有效时间分辨率达到 25.2 Hz。纵向观察成像显示，与非应激小鼠相比，慢性应激导致髓细胞浸润增加了 6.09 倍（P=0.017）。3 周后，我们观察到慢性应激加剧了血管炎症，使粘附的髓样细胞增加了 2.45 倍（P=0.031），而非应激小鼠则无明显变化。微循环成像显示，受压小鼠静脉中的循环细胞、滚动细胞和粘附细胞均有所增加。颈动脉组织学分析证实了体内研究结果，即应激增加了斑块面积、髓样细胞和巨噬细胞聚集以及坏死核心体积，同时降低了纤维帽厚度，这表明斑块形成加快。我们观察了颈动脉的三维结构和绉肌静脉的四维动态：结论：动态聚焦运动补偿体视显微镜实现了亚细胞分辨率的活体成像，可实时观察慢性束缚应力下搏动动脉中血细胞的动态变化。这项新技术强调了先进的体内成像技术对了解心血管疾病的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Arteriosclerosis, Thrombosis, and Vascular Biology 医学-外周血管病

CiteScore

15.60

自引率

2.30%

发文量

337

审稿时长

2-4 weeks

期刊介绍： The journal "Arteriosclerosis, Thrombosis, and Vascular Biology" (ATVB) is a scientific publication that focuses on the fields of vascular biology, atherosclerosis, and thrombosis. It is a peer-reviewed journal that publishes original research articles, reviews, and other scholarly content related to these areas. The journal is published by the American Heart Association (AHA) and the American Stroke Association (ASA). The journal was published bi-monthly until January 1992, after which it transitioned to a monthly publication schedule. The journal is aimed at a professional audience, including academic cardiologists, vascular biologists, physiologists, pharmacologists and hematologists.