Label-Free Morphological Phenotyping of In Vitro 3D Microtumors.

By combining novel micro-scale manipulation cantilevers with commercially available, widely used 3D light microscopy, we were able to develop a new method of 3D elastography specialized for the analysis of 3D microtumors. Existing mechanical characterization methods are available for the study of single cells, using forces in the range of sub pN to a few hundred nN, or of larger tissues, with forces greater than 1 mN. Our method supports the mechanical analysis of micro- to meso-scale 3D tissues, such as multicellular spheroids (200-300 μm diameter), by applying forces in the range of sub-hundred nN to sub-mN, while also maintaining a spatial resolution of elasticity measurement as small as 20-30 μm. We use a differential interference contrast (DIC)/confocal microscope to obtain a 4D (x, y, z, and indentation steps) image sequence, which is then analyzed using our custom 3D pattern-tracking MATLAB program. With this method, we have been able to show structural and spatial heterogeneity among single cells and surrounding regions in tumor spheroids, and between different cell types in tumor-fibroblast co-cultured spheroids. Our method has the potential to both bridge the gap between in vitro monolayer culture systems and in vivo animal studies and add a mechanical component to existing biological assays.