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Magnetic Stiffening in 3D Cell Culture Matrices.

Wen ChenYing ZhangJyoti KumariHans EngelkampPaul H J Kouwer
Published in: Nano letters (2021)
The mechanical environment of a cell is not constant. This dynamic behavior is exceedingly difficult to capture in (synthetic) in vitro matrices. This paper describes a novel, highly adaptive hybrid hydrogel composed of magnetically sensitive magnetite nanorods and a stress-responsive synthetic matrix. Nanorod rearrangement after application of (small) magnetic fields induces strain in the network, which results in a strong (over 10-fold) stiffening even at minimal (2.5 wt %) nanorod concentrations. Moreover, the stiffening mechanism yields a fast and fully reversible response. In the manuscript, we quantitatively analyze that forces generated by the particles are comparable to cellular forces. We demonstrate the value of magnetic stiffening in a 3D MCF10A epithelial cell experiment, where simply culturing on top of a permanent magnet gives rise to changes in the cell morphology. This work shows that our hydrogels are uniquely suited as 3D cell culture systems with on-demand adaptive mechanical properties.
Keyphrases
  • single cell
  • molecularly imprinted
  • drug delivery
  • cell therapy
  • hyaluronic acid
  • wound healing
  • stem cells
  • bone marrow
  • drug release
  • tissue engineering
  • simultaneous determination