bims-ecemfi Biomed News
on ECM and fibroblasts
Issue of 2024–10–27
two papers selected by
Badri Narayanan Narasimhan, University of California, San Diego



  1. Adv Sci (Weinh). 2024 Oct 23. e2406932
      Cell shape and function are intimately linked, in a way that is mediated by the forces exerted between cells and their environment. The relationship between cell shape and forces has been extensively studied for cells seeded on flat 2D substrates, but not for cells in more physiological 3D settings. Here, a technique called 3D micropatterned traction force microscopy (3D-µTFM) to confine cells in 3D wells of defined shape, while simultaneously measuring the forces transmitted between cells and their microenvironment is demonstrated. This technique is based on the 3D micropatterning of polyacrylamide wells and on the calculation of 3D traction force from their deformation. With 3D-µTFM, it is shown that MCF10A breast epithelial cells exert defined, reproducible patterns of forces on their microenvironment, which can be both contractile and extensile. Cells switch from a global contractile to extensile behavior as their volume is reduced are further shown. The technique enables the quantitative study of cell mechanobiology with full access to 3D cellular forces while having accurate control over cell morphology and the mechanical conditions of the microenvironment.
    Keywords:  cell volumes; cytoskeleton; micro‐wells; traction forces
    DOI:  https://doi.org/10.1002/advs.202406932
  2. J Biomed Mater Res A. 2024 Oct 21.
      Biomaterial-induced macrophage-derived multinucleated cells (MNCs) are often observed at or near material implantation sites, yet their subtypes and roles in tissue repair and wound healing remain unclear. This study compares material-induced MNCs to cytokine-induced MNCs using both in vitro and in vivo models. 3D-embedded Raw264.7 cells and rat bone marrow-derived monocytes (BMDMs), with or without cytokines such as IL-4 and RANKL, were characterized for their MNC morphologies and subtypes via in situ immunocytochemistry and flow cytometry. Macrophage polarization and osteoclastic differentiation were assessed through NO production, arginase activity, and tartrate-resistant acid phosphatase levels. 3D matrix-induced MNCs expressed the same phenotypic heterogeneity as the IL-4 and RANK-treated ones. 3D matrix-induced MNCs displayed the same phenotypic heterogeneity as those treated with IL-4 and RANKL. A high viscoelastic matrix (1006.48 ± 92.29 Pa) induced larger populations of proinflammatory and osteoclast-like MNCs, whereas a low viscoelastic matrix (38.61 ± 7.56 Pa) supported active differentiation and gene expression across pro-, anti-inflammatory, and osteoclast-like macrophages. Matrix viscoelasticity also influenced the effects of IL-4 and RANKL on macrophage-derived MNC polarization. In an in vivo subcutaneous implantation model, medium to high viscoelastic matrices exhibited higher populations of CD86+ and RANK+ MNCs, while low viscoelastic matrices showed higher populations of CD206+ MNCs. These findings suggest that matrix viscoelasticity modulates macrophage differentiation and MNC phenotype, with low viscoelastic matrices potentially favoring anti-inflammatory MNCs and macrophage differentiation suitable for subcutaneous implantation.
    Keywords:  Col‐Tgel; biomaterial‐induced multinucleated cells; multinucleated cells polarization; viscoelasticity
    DOI:  https://doi.org/10.1002/jbm.a.37814