| Literature DB >> 29290586 |
Alex J Hughes1, Hikaru Miyazaki2, Maxwell C Coyle3, Jesse Zhang4, Matthew T Laurie5, Daniel Chu6, Zuzana Vavrušová6, Richard A Schneider6, Ophir D Klein7, Zev J Gartner8.
Abstract
Many tissues fold into complex shapes during development. Controlling this process in vitro would represent an important advance for tissue engineering. We use embryonic tissue explants, finite element modeling, and 3D cell-patterning techniques to show that mechanical compaction of the extracellular matrix during mesenchymal condensation is sufficient to drive tissue folding along programmed trajectories. The process requires cell contractility, generates strains at tissue interfaces, and causes patterns of collagen alignment around and between condensates. Aligned collagen fibers support elevated tensions that promote the folding of interfaces along paths that can be predicted by modeling. We demonstrate the robustness and versatility of this strategy for sculpting tissue interfaces by directing the morphogenesis of a variety of folded tissue forms from patterns of mesenchymal condensates. These studies provide insight into the active mechanical properties of the embryonic mesenchyme and establish engineering strategies for more robustly directing tissue morphogenesis ex vivo.Entities:
Keywords: intestinal villi; mechanobiology; mesenchymal condensation; smart materials; soft matter; soft robotics; synthetic biology; tissue engineering; tissue folding
Mesh:
Year: 2017 PMID: 29290586 PMCID: PMC5826757 DOI: 10.1016/j.devcel.2017.12.004
Source DB: PubMed Journal: Dev Cell ISSN: 1534-5807 Impact factor: 12.270