Silk Hydrogel Substrate Stress Relaxation Primes Mesenchymal Stem Cell Behavior in 2D

abstract

Tissue-mimetic silk hydrogels are being explored for diverse healthcare applications, including stem cell delivery. However, the impact of stress relaxation of silk hydrogels on human mesenchymal stem cell (MSC) biology is poorly defined. The aim of this study was to fabricate silk hydrogels with tuned mechanical properties that allowed the regulation of MSC biology in two dimensions. The silk content and stiffness of both elastic and viscoelastic silk hydrogels were kept constant to permit direct comparisons. Gene expression of IL-1 beta, IL-6, LIF, BMP-6, BMP-7, and protein tyrosine phosphatase receptor type C were substantially higher in MSCs cultured on elastic hydrogels than those on viscoelastic hydrogels, whereas this pattern was reversed for insulin, HNF-1A, and SOX-2. Protein expression was also mechanosensitive and the elastic cultures showed strong activation of IL-1 beta signaling in response to hydrogel mechanics. An elastic substrate also induced higher consumption of glucose and aspartate, coupled with a higher secretion of lactate, than was observed in MSCs grown on viscoelastic substrate. However, both silk hydrogels changed the magnitude of consumption of glucose, pyruvate, glutamine, and aspartate, and also metabolite secretion, resulting in an overall lower metabolic activity than that found in control cells. Together, these findings describe how stress relaxation impacts the overall biology of MSCs cultured on silk hydrogels.

keywords

FIBROIN HYDROGELS

subject category

Nanoscience & Nanotechnology; Materials Science, Multidisciplinary

authors

Phuagkhaopong, S; Mendes, L; Muller, K; Wobus, M; Bornhauser, M; Carswell, HVO; Duarte, IF; Seib, FP

our authors

acknowledgements

S.P. received fellowship support from the Development and Promotion of Science and Technology Talents Project under the Royal Government of Thailand Scholarship. F. P.S. acknowledges Engineering and Physical Sciences Research Council funding EP/N03127X/1 and Impact Accelerator Account EP/R51178X/1.

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