Centre for Craniofacial and Regenerative Biology, King's College London, London SE1 9RT, United Kingdom; School of Biomedical Engineering and Imaging Sciences, King's College London, London SE1 7EH, United Kingdom.
School of Cardiovascular Medicine and Sciences, King's College London, London SE5 9NU, United Kingdom.
Acta Biomater. 2021 Sep 15;132:114-128. doi: 10.1016/j.actbio.2021.02.031. Epub 2021 Feb 27.
Many cardiovascular diseases (CVD) are driven by pathological remodelling of blood vessels, which can lead to aneurysms, myocardial infarction, ischaemia and strokes. Aberrant remodelling is driven by changes in vascular cell behaviours combined with degradation, modification, or abnormal deposition of extracellular matrix (ECM) proteins. The underlying mechanisms that drive the pathological remodelling of blood vessels are multifaceted and disease specific; however, unravelling them may be key to developing therapies. Reductionist models of blood vessels created in vitro that combine cells with biomaterial scaffolds may serve as useful analogues to study vascular disease progression in a controlled environment. This review presents the main considerations for developing such in vitro models. We discuss how the design of blood vessel models impacts experimental readouts, with a particular focus on the maintenance of normal cellular phenotypes, strategies that mimic normal cell-ECM interactions, and approaches that foster intercellular communication between vascular cell types. We also highlight how choice of biomaterials, cellular arrangements and the inclusion of mechanical stimulation using fluidic devices together impact the ability of blood vessel models to mimic in vivo conditions. In the future, by combining advances in materials science, cell biology, fluidics and modelling, it may be possible to create blood vessel models that are patient-specific and can be used to develop and test therapies. STATEMENT OF SIGNIFICANCE: Simplified models of blood vessels created in vitro are powerful tools for studying cardiovascular diseases and understanding the mechanisms driving their progression. Here, we highlight the key structural and cellular components of effective models and discuss how including mechanical stimuli allows researchers to mimic native vessel behaviour in health and disease. We discuss the primary methods used to form blood vessel models and their limitations and conclude with an outlook on how blood vessel models that incorporate patient-specific cells and flows can be used in the future for personalised disease modelling.
许多心血管疾病(CVD)是由血管的病理性重塑引起的,这可能导致动脉瘤、心肌梗死、缺血和中风。异常重塑是由血管细胞行为的变化以及细胞外基质(ECM)蛋白的降解、修饰或异常沉积共同驱动的。驱动血管病理性重塑的潜在机制是多方面的,且具有疾病特异性;然而,揭示这些机制可能是开发治疗方法的关键。在体外结合细胞与生物材料支架创建的血管简化模型可以作为有用的模拟物,用于在受控环境中研究血管疾病的进展。本综述介绍了开发此类体外模型的主要考虑因素。我们讨论了血管模型的设计如何影响实验结果,特别关注维持正常细胞表型的策略、模拟正常细胞-ECM 相互作用的策略以及促进血管细胞类型之间细胞间通讯的方法。我们还强调了生物材料的选择、细胞排列方式以及使用流体装置进行机械刺激的纳入方式如何共同影响血管模型模拟体内条件的能力。在未来,通过结合材料科学、细胞生物学、流体学和建模方面的进展,可能可以创建具有患者特异性且可用于开发和测试治疗方法的血管模型。
体外创建的简化血管模型是研究心血管疾病和理解驱动其进展的机制的强大工具。在这里,我们强调了有效模型的关键结构和细胞成分,并讨论了如何包括机械刺激,使研究人员能够模拟健康和疾病状态下的天然血管行为。我们讨论了形成血管模型的主要方法及其局限性,并对如何在未来使用包含患者特异性细胞和流动的血管模型进行个性化疾病建模进行了展望。
