Bioactive Materials (Oct 2023)

Microcarriers promote the through interface movement of mouse trophoblast stem cells by regulating stiffness

  • Zili Gao,
  • Jia Guo,
  • Bo Gou,
  • Zhen Gu,
  • Tan Jia,
  • Sinan Ma,
  • Liyuan Jiang,
  • Wenli Liu,
  • Lixun Zhou,
  • Qi Gu

Journal volume & issue
Vol. 28
pp. 196 – 205

Abstract

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Mechanical force is crucial in the whole process of embryonic development. However, the role of trophoblast mechanics during embryo implantation has rarely been studied. In this study, we constructed a model to explore the effect of stiffness changes in mouse trophoblast stem cells (mTSCs) on implantation: microcarrier was prepared by sodium alginate using a droplet microfluidics system, and mTSCs were attached to the microcarrier surface with laminin modifications, called T(micro). Compared with the spheroid, formed by the self-assembly of mTSCs (T(sph)), we could regulate the stiffness of the microcarrier, making the Young's modulus of mTSCs (367.70 ± 79.81 Pa) similar to that of the blastocyst trophoblast ectoderm (432.49 ± 151.90 Pa). Moreover, T(micro) contributes to improve the adhesion rate, expansion area and invasion depth of mTSCs. Further, T(micro) was highly expressed in tissue migration-related genes due to the activation of the Rho-associated coiled-coil containing protein kinase (ROCK) pathway at relatively similar modulus of trophoblast. Overall, our study explores the embryo implantation process with a new perspective, and provides theoretical support for understanding the effect of mechanics on embryo implantation.

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