Mechanophenotyping of 3D multicellular clusters using displacement arrays of rendered tractions.
Susan E LeggettMohak PatelThomas M ValentinLena GamboaAmanda S KhooEvelyn Kendall WilliamsChristian FranckIan Y WongPublished in: Proceedings of the National Academy of Sciences of the United States of America (2020)
Epithelial tissues mechanically deform the surrounding extracellular matrix during embryonic development, wound repair, and tumor invasion. Ex vivo measurements of such multicellular tractions within three-dimensional (3D) biomaterials could elucidate collective dissemination during disease progression and enable preclinical testing of targeted antimigration therapies. However, past 3D traction measurements have been low throughput due to the challenges of imaging and analyzing information-rich 3D material deformations. Here, we demonstrate a method to profile multicellular clusters in a 96-well-plate format based on spatially heterogeneous contractile, protrusive, and circumferential tractions. As a case study, we profile multicellular clusters across varying states of the epithelial-mesenchymal transition, revealing a successive loss of protrusive and circumferential tractions, as well as the formation of localized contractile tractions with elongated cluster morphologies. These cluster phenotypes were biochemically perturbed by using drugs, biasing toward traction signatures of different epithelial or mesenchymal states. This higher-throughput analysis is promising to systematically interrogate and perturb aberrant mechanobiology, which could be utilized with human-patient samples to guide personalized therapies.
Keyphrases
- extracellular matrix
- epithelial mesenchymal transition
- skeletal muscle
- endothelial cells
- high resolution
- stem cells
- gene expression
- bone marrow
- case report
- transforming growth factor
- cancer therapy
- signaling pathway
- healthcare
- genome wide
- drug delivery
- pluripotent stem cells
- cell therapy
- dna methylation
- mesenchymal stem cells
- mass spectrometry
- wound healing
- social media
- photodynamic therapy