Light-sheet photonic force optical coherence elastography for high-throughput quantitative 3D micromechanical imaging

Microscale mechanical properties of the extracellular matrix (ECM) and dynamic cell-ECM interactions play an important role in physiological processes and disease. However, it remains a challenge for current mechanical characterization methods to combine quantitative 3D imaging of ECM mechanics with cellular-scale resolution and dynamic monitoring of cell mediated changes to pericellular viscoelasticity. Here, we present light-sheet photonic force optical coherence elastography (LS-pfOCE) to address these challenges by leveraging a light-sheet for parallelized, non-invasive, and localized mechanical loading. We demonstrate the capabilities of LS-pfOCE by imaging the micromechanical heterogeneity of fibrous 3D collagen matrices and perform a live-cell study to image micromechanical heterogeneity induced by NIH-3T3 cells seeded in 3D fibrin constructs. We also show that LS-pfOCE is able to quantify temporal variations in pericellular viscoelasticity in response to altered cellular activity. By providing access to the spatiotemporal variations in the micromechanical properties of 3D complex biopolymer constructs and engineered cellular systems, LS-pfOCE has the potential to drive new discoveries in the rapidly growing field of mechanobiology.