Force spectroscopy of single cells using atomic force microscopy

Physical forces and mechanical properties have critical roles in cellular function, physiology and disease. Over the past decade, atomic force microscopy (AFM) techniques have enabled substantial advances in our understanding of the tight relationship between force, mechanics and function in living cells and contributed to the growth of mechanobiology. In this Primer, we provide a comprehensive overview of the use of AFM-based force spectroscopy (AFM-FS) to study the strength and dynamics of cell adhesion from the cellular to the single-molecule level, spatially map cell surface receptors and quantify how cells dynamically regulate their mechanical and adhesive properties. We first introduce the importance of force and mechanics in cell biology and the general principles of AFM-FS methods. We describe procedures for sample and AFM probe preparations, the various AFM-FS modalities currently available and their respective advantages and limitations. We also provide details and recommendations for best usage practices, and discuss data analysis, statistics and reproducibility. We then exemplify the potential of AFM-FS in cellular and molecular biology with a series of recent successful applications focusing on viruses, bacteria, yeasts and mammalian cells. Finally, we speculate on the grand challenges in the area for the next decade. Atomic force microscopy-based force spectroscopy can probe the strength and dynamics of cell adhesion to understand how physical forces influence cellular function, physiology and disease. Here, Dufrene and colleagues discuss the ability of this technology to work as an ultra-sensitive force sensor to study the adhesion and elasticity of complex biological systems including viruses, bacteria, yeasts and mammalian cells.