Faculty of Physics and Earth Science, Peter Debye Institute of Soft Matter Physics, Biological Physics Division, Leipzig University, Leipzig, Germany.
Semin Cell Dev Biol. 2023 Sep 30;147:58-69. doi: 10.1016/j.semcdb.2023.01.012. Epub 2023 Jan 31.
Scientific knowledge in the field of cell biology and mechanobiology heavily leans on cell-based in vitro experiments and models that favor the examination and comprehension of certain biological processes and occurrences across a variety of environments. Cell culture assays are an invaluable instrument for a vast spectrum of biomedical and biophysical investigations. The quality of experimental models in terms of simplicity, reproducibility, and combinability with other methods, and in particular the scale at which they depict cell fate in native tissues, is critical to advancing the knowledge of the comprehension of cell-cell and cell-matrix interactions in tissues and organs. Typically, in vitro models are centered on the experimental tinkering of mammalian cells, most often cultured as monolayers on planar, two-dimensional (2D) materials. Notwithstanding the significant advances and numerous findings that have been accomplished with flat biology models, their usefulness for generating further new biological understanding is constrained because the simple 2D setting does not reproduce the physiological response of cells in natural living tissues. In addition, the co-culture systems in a 2D stetting weakly mirror their natural environment of tissues and organs. Significant advances in 3D cell biology and matrix engineering have resulted in the creation and establishment of a new type of cell culture shapes that more accurately represents the in vivo microenvironment and allows cells and their interactions to be analyzed in a biomimetic approach. Contemporary biomedical and biophysical science has novel advances in technology that permit the design of more challenging and resilient in vitro models for tissue engineering, with a particular focus on scaffold- or hydrogel-based formats, organotypic cultures, and organs-on-chips, which cover the purposes of co-cultures. Even these complex systems must be kept as simplified as possible in order to grasp a particular section of physiology too very precisely. In particular, it is highly appreciated that they bridge the space between conventional animal research and human (patho)physiology. In this review, the recent progress in 3D biomimetic culturation is presented with a special focus on co-cultures, with an emphasis on the technological building blocks and endothelium-based co-culture models in cancer research that are available for the development of more physiologically relevant in vitro models of human tissues under normal and diseased conditions. Through applications and samples of various physiological and disease models, it is possible to identify the frontiers and future engagement issues that will have to be tackled to integrate synthetic biomimetic culture systems far more successfully into biomedical and biophysical investigations.
细胞生物学和机械生物学领域的科学知识严重依赖基于细胞的体外实验和模型,这些实验和模型有利于研究和理解各种环境中的某些生物学过程和事件。细胞培养分析是广泛的生物医学和生物物理研究的宝贵工具。实验模型的质量在简单性、可重复性以及与其他方法的组合性方面,特别是在描绘天然组织中细胞命运的规模方面,对于推进对细胞-细胞和细胞-基质相互作用的理解至关重要。通常,体外模型以对哺乳动物细胞的实验性 tinkering 为中心,这些细胞通常在二维 (2D) 材料的平面单层上培养。尽管平面生物学模型取得了重大进展和许多发现,但由于简单的 2D 环境不能再现细胞在天然活组织中的生理反应,它们在产生进一步新的生物学理解方面的用途受到限制。此外,2D 环境中的共培养系统对组织和器官的天然环境的模拟效果很弱。3D 细胞生物学和基质工程的重大进展导致了新型细胞培养形状的创建和建立,这些形状更准确地代表了体内微环境,并允许以仿生方法分析细胞及其相互作用。当代生物医学和生物物理学有新的技术进步,允许为组织工程设计更具挑战性和更有弹性的体外模型,特别侧重于支架或水凝胶格式、器官型培养和芯片上器官,涵盖了共培养的目的。即使是这些复杂的系统也必须尽可能简化,以便非常精确地掌握特定部分的生理学。特别是,它们在传统动物研究和人类(病理)生理学之间架起了桥梁,这一点非常值得赞赏。在这篇综述中,特别强调了技术构建块和基于内皮的共培养模型,重点介绍了 3D 仿生培养的最新进展,这些进展可用于开发更具生理相关性的正常和患病条件下人类组织的体外模型。通过各种生理和疾病模型的应用和样本,可以确定将合成仿生培养系统更成功地整合到生物医学和生物物理研究中必须解决的前沿问题和未来参与问题。
