Cellular microarrays for assessing single-cell phenotypic changes in vascular cell populations

IF 3 4区 医学 Q3 ENGINEERING, BIOMEDICAL Biomedical Microdevices Pub Date : 2023-03-16 DOI:10.1007/s10544-023-00651-5
E. Smith, M. Zagnoni, M. E. Sandison
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Abstract

Microengineering technologies provide bespoke tools for single-cell studies, including microarray approaches. There are many challenges when culturing adherent single cells in confined geometries for extended periods, including the ability of migratory cells to overcome confining cell-repellent surfaces with time. Following studies suggesting clonal expansion of only a few vascular smooth muscle cells (vSMCs) contributes to plaque formation, the investigation of vSMCs at the single-cell level is central to furthering our understanding of atherosclerosis. Herein, we present a medium throughput cellular microarray, for the tracking of single, freshly-isolated vSMCs as they undergo phenotypic modulation in vitro. Our solution facilitates long-term cell confinement (> 3 weeks) utilising novel application of surface functionalisation methods to define individual culture microwells. We demonstrate successful tracking of hundreds of native vSMCs isolated from rat aortic and carotid artery tissue, monitoring their proliferative capacity and uptake of oxidised low-density lipoprotein (oxLDL) by live-cell microscopy. After 7 days in vitro, the majority of viable SMCs remained as single non-proliferating cells (51% aorta, 78% carotid). However, a sub-population of vSMCs demonstrated high proliferative capacity (≥ 10 progeny; 18% aorta, 5% carotid), in line with reports that a limited number of medial SMCs selectively expand to populate atherosclerotic lesions. Furthermore, we show that, when exposed to oxLDL, proliferative cells uptake higher levels of lipoproteins, whilst also expressing greater levels of galectin-3. Our microwell array approach enables long-term characterisation of multiple phenotypic characteristics and the identification of new cellular sub-populations in migratory, proliferative adherent cell types.

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用于评估血管细胞群中单细胞表型变化的细胞微阵列
微工程技术为单细胞研究提供了定制工具,包括微阵列方法。当长时间在受限的几何形状中培养贴壁单细胞时,存在许多挑战,包括随时间迁移细胞克服受限的细胞排斥表面的能力。有研究表明,只有少数血管平滑肌细胞(vSMCs)的克隆扩增有助于斑块的形成,因此在单细胞水平上对vSMCs的研究对于进一步了解动脉粥样硬化至关重要。在这里,我们提出了一种中等通量的细胞微阵列,用于跟踪单个,新鲜分离的vSMCs,因为它们在体外经历表型调节。我们的解决方案利用表面功能化方法的新应用来定义单个培养微孔,促进长期细胞隔离(3周)。我们成功地跟踪了从大鼠主动脉和颈动脉组织中分离的数百个天然vSMCs,通过活细胞显微镜监测它们的增殖能力和氧化低密度脂蛋白(oxLDL)的摄取。体外培养7天后,大多数存活的SMCs仍为单个非增殖细胞(51%主动脉细胞,78%颈动脉细胞)。然而,vSMCs亚群表现出高增殖能力(≥10个后代;18%主动脉,5%颈动脉),这与有限数量的内侧SMCs选择性扩张填充动脉粥样硬化病变的报道一致。此外,我们表明,当暴露于oxLDL时,增殖细胞摄取更高水平的脂蛋白,同时也表达更高水平的半乳糖凝集素-3。我们的微孔阵列方法能够长期表征多种表型特征,并在迁移、增殖贴壁细胞类型中鉴定新的细胞亚群。图形抽象
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来源期刊
Biomedical Microdevices
Biomedical Microdevices 工程技术-工程:生物医学
CiteScore
6.90
自引率
3.60%
发文量
32
审稿时长
6 months
期刊介绍: Biomedical Microdevices: BioMEMS and Biomedical Nanotechnology is an interdisciplinary periodical devoted to all aspects of research in the medical diagnostic and therapeutic applications of Micro-Electro-Mechanical Systems (BioMEMS) and nanotechnology for medicine and biology. General subjects of interest include the design, characterization, testing, modeling and clinical validation of microfabricated systems, and their integration on-chip and in larger functional units. The specific interests of the Journal include systems for neural stimulation and recording, bioseparation technologies such as nanofilters and electrophoretic equipment, miniaturized analytic and DNA identification systems, biosensors, and micro/nanotechnologies for cell and tissue research, tissue engineering, cell transplantation, and the controlled release of drugs and biological molecules. Contributions reporting on fundamental and applied investigations of the material science, biochemistry, and physics of biomedical microdevices and nanotechnology are encouraged. A non-exhaustive list of fields of interest includes: nanoparticle synthesis, characterization, and validation of therapeutic or imaging efficacy in animal models; biocompatibility; biochemical modification of microfabricated devices, with reference to non-specific protein adsorption, and the active immobilization and patterning of proteins on micro/nanofabricated surfaces; the dynamics of fluids in micro-and-nano-fabricated channels; the electromechanical and structural response of micro/nanofabricated systems; the interactions of microdevices with cells and tissues, including biocompatibility and biodegradation studies; variations in the characteristics of the systems as a function of the micro/nanofabrication parameters.
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