Brown University, Department of Molecular Pharmacology, Physiology and Biotechnology, Providence, RI 02912, USA.
Expert Opin Biol Ther. 2012 Oct;12(10):1347-60. doi: 10.1517/14712598.2012.707181. Epub 2012 Jul 12.
Developing in vitro models for studying cell biology and cell physiology is of great importance to the fields of biotechnology, cancer research, drug discovery, toxicity testing, as well as the emerging fields of tissue engineering and regenerative medicine. Traditional two-dimensional (2D) methods of mammalian cell culture have several limitations and it is increasingly recognized that cells grown in a three-dimensional (3D) environment more closely represent normal cellular function due to the increased cell-to-cell interactions, and by mimicking the in vivo architecture of natural organs and tissues.
In this review, we discuss the methods to form 3D multi-cellular spheroids, the advantages and limitations of these methods, and assays used to characterize the function of spheroids. The use of spheroids has led to many advances in basic cell sciences, including understanding cancer cell interactions, creating models for drug discovery and cancer metastasis, and they are being investigated as basic units for engineering tissue constructs. As so, this review will focus on contributions made to each of these fields using spheroid models.
Multi-cellular spheroids are rich in biological content and mimic better the in vivo environment than 2D cell culture. New technologies to form and analyze spheroids are rapidly increasing their adoption and expanding their applications.
开发用于研究细胞生物学和细胞生理学的体外模型对于生物技术、癌症研究、药物发现、毒性测试以及组织工程和再生医学等新兴领域非常重要。传统的哺乳动物细胞二维(2D)培养方法存在一些局限性,越来越多的人认识到,由于细胞间相互作用的增加,以及模拟天然器官和组织的体内结构,在三维(3D)环境中生长的细胞更能代表正常的细胞功能。
在这篇综述中,我们讨论了形成 3D 多细胞球体的方法,这些方法的优缺点,以及用于表征球体功能的分析方法。球体的使用在基础细胞科学方面取得了许多进展,包括了解癌细胞相互作用、为药物发现和癌症转移创建模型,并且它们被作为工程组织构建的基本单元进行研究。因此,这篇综述将重点介绍使用球体模型在这些领域中的各个贡献。
多细胞球体富含生物内容,比 2D 细胞培养更能模拟体内环境。形成和分析球体的新技术正在迅速增加它们的应用,并扩大它们的应用范围。
