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Cytoskeletal stiffening in synthetic hydrogels.

Paula de AlmeidaMaarten JaspersSarah VaessenOya TagitGiuseppe PortaleAlan E RowanPaul H J Kouwer
Published in: Nature communications (2019)
Although common in biology, controlled stiffening of hydrogels in vitro is difficult to achieve; the required stimuli are commonly large and/or the stiffening amplitudes small. Here, we describe the hierarchical mechanics of ultra-responsive hybrid hydrogels composed of two synthetic networks, one semi-flexible and stress-responsive, the other flexible and thermoresponsive. Heating collapses the flexible network, which generates internal stress that causes the hybrid gel to stiffen up to 50 times its original modulus; an effect that is instantaneous and fully reversible. The average generated forces amount to ~1 pN per network fibre, which are similar to values found for stiffening resulting from myosin molecular motors in actin. The excellent control, reversible nature and large response gives access to many biological and bio-like applications, including tissue engineering with truly dynamic mechanics and life-like matter.
Keyphrases
  • tissue engineering
  • hyaluronic acid
  • drug delivery
  • cancer therapy
  • wound healing
  • drug release
  • stress induced
  • extracellular matrix
  • high resolution
  • solid state
  • mass spectrometry
  • cell migration