Dynamic Surfaces for the Study of Mesenchymal Stem Cell Growth through Adhesion Regulation

Roberts, J.N.; Sahoo, Jugal Kishore; McNamara, Laura E.; Burgess, Karl; Yang, Jingli; Alakpa, Enateri V.; Anderson, Hilary; Hay, Jake J.; Turner, Lesley-Anne; Yarwood, Stephen J.; Zelzer, Mischa; Oreffo, Richard O.C.; Ulijn, Rein V.; Dalby, Matthew J.

doi:10.1021/acsnano.6b01765

Cited by 94 publications

(80 citation statements)

References 58 publications

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“…There have been attempts to recapitulate the dynamic properties of the ECM using materials that react to external stimuli and ultimately alter the phenotype of the cells. Different types of triggering mechanisms have been utilized including light, either in 2D or 3D (hydrogels) culture systems, inducing irreversible or reversible protein‐material interactions, temperature, and enzymes . However, these systems are typically designed to reveal or hide cell binding sites to/from cells and this still falls short of the dynamic nature of complex niches hMSCs reside in in vivo.…”

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confidence: 99%

Bacteria‐Based Materials for Stem Cell Engineering

et al. 2018

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Materials can be engineered to deliver specific biological cues that control stem cell growth and differentiation. However, current materials are still limited for stem cell engineering as stem cells are regulated by a complex biological milieu that requires spatiotemporal control. Here a new approach of using materials that incorporate designed bacteria as units that can be engineered to control human mesenchymal stem cells (hMSCs), in a highly dynamic-temporal manner, is presented. Engineered Lactococcus lactis spontaneously colonizes a variety of material surfaces (e.g., polymers, metals, and ceramics) and is able to maintain growth and induce differentiation of hMSCs in 2D/3D surfaces and hydrogels. Controlled, dynamic, expression of fibronectin fragments supports stem cell growth, whereas inducible-temporal regulation of secreted bone morphogenetic protein-2 drives osteogenesis in an on-demand manner. This approach enables stem cell technologies using material systems that host symbiotic interactions between eukaryotic and prokaryotic cells.

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confidence: 99%

Bacteria‐Based Materials for Stem Cell Engineering

et al. 2018

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“…A hypothesis we can allude to from the literature is that typically MSCs have more, but smaller, adhesions 38 and, in MSCs, the cell membrane is more teathered to adhesions reflecting that MSCs need to respond to environmental cues 37 . Osteoblasts, on the other hand, in common with other connective tissue cells, are required to withstand the loads mechanical strain places on tisses and so teather the membrane to linker complexes such as the ERM proteins (ezrin, radixin and moesin) 37 ; we have previously reported increased expression of ezrin with onset of MSC osteogenesis 39 . Further, ERM depletion leads to inability to chemically induce osteogenesis 40 .…”

Section: Discussionmentioning

confidence: 90%

The use of nanovibration to discover specific and potent bioactive metabolites that stimulate osteogenic differentiation in mesenchymal stem cells

Hodgkinson

Tsimbouri

Llopis-Hernández

et al. 2020

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Figure 2. Metabolic profiles of MSCs in 3D culture for 7 days with osteogenic media or nanovibration. (a) Heatmap (red = up-regulations, blue = down-regulations)and (b) principle component analysis depicting differences in nanovibration and OGM metabolic profiles during MSC differentiation. Metabolic profiles of MSCs induced by nanovibrational stimulation show a greater similarity to unstimulated controls at day 7 of culture and to OGM-stimulated cells at day 14. (c) Metabolic profiles were compared by Ingenuity Pathway Analysis (IPA). The metabolic profiles of nanovibrated cells lead to a stronger predicted activation of ERK1/2 relative to the metabolic profiles of cells induced by OGM. In contrast, the metabolic profiles of OGMstimulated cells lead to a stronger predicted down regulation of JNK, while those of nanovibrated cells predict JNK's activation rather than inhibition. Networks are built from d=1, r=4.

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“…Designing materials that can control cell–material interactions by external stimuli offers versatile potential to reversibly switch between cell‐adhesive and nonadhesive materials in vivo. Cell–material interactions have been shown to be modulated by various stimuli, such as enzymes, electric fields, magnetic fields, and light . For example, enzymes, such as exonuclease and elastase, were utilized to temporally modulate cell adhesion by dynamically presenting bioactive motifs, such as aptamers and RGD in vitro.…”

Section: Methodsmentioning

confidence: 99%

“…Cell–material interactions have been shown to be modulated by various stimuli, such as enzymes, electric fields, magnetic fields, and light . For example, enzymes, such as exonuclease and elastase, were utilized to temporally modulate cell adhesion by dynamically presenting bioactive motifs, such as aptamers and RGD in vitro. Our own study showed that magnetic field tuned the tether mobility of RGD‐bearing magnetic nanoparticles to modulate cell adhesion in vitro .…”

Section: Methodsmentioning

confidence: 99%