Temporal Modulation of Stem Cell Activity Using Magnetoactive Hydrogels

Abdeen, Amr A.; Lee, Junmin; Bharadwaj, N. Ashwin; Ewoldt, Randy H.; Kilian, Kristopher A.

doi:10.1002/adhm.201600349

Cited by 77 publications

(82 citation statements)

References 59 publications

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“…External triggers such as pH [4] and temperature [5] may not be biocompatible for certain cell types, whereas stimuli such as calcium ion concentration, [6] competitive binding partners, [7] or magnetic particle incorporation [8] contain components that may alter cell signaling or require a sustained stimulus. Another challenge is capturing a tunable and relevant range of elastic moduli over which to study cell behavior.…”

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confidence: 99%

Hydrogels with Reversible Mechanics to Probe Dynamic Cell Microenvironments

et al. 2017

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The relationship between ECM mechanics and cell behavior is dynamic, as cells remodel and respond to changes in their local environment. Most in vitro substrates are static and supraphysiologically stiff; thus, platforms with dynamic and reversible mechanical changes are needed. Here, we developed hyaluronic acid-based substrates capable of sequential photodegradation and photoinitiated crosslinking reactions to “soften” and then “stiffen” the hydrogels over a physiologically-relevant range of moduli. Reversible mechanical signaling to adhered cells was demonstrated with human mesenchymal stem cells. In situ hydrogel softening (from ~14 to 3.5 kPa) led to a decrease in cell area and nuclear localization of YAP/TAZ, and subsequent stiffening (from ~3.5 to 28 kPa) increased cell area and nuclear localization of YAP/TAZ. Each photoreaction was cytocompatible and tunable, rendering this platform amenable to studies of dynamic mechanics on cell behavior across many cell types and contexts.

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confidence: 99%

Hydrogels with Reversible Mechanics to Probe Dynamic Cell Microenvironments

et al. 2017

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“…For example, genetically engineered protein-based hydrogels showed the potential to transfer the change in protein conformation to differences of the macroscopic properties of hydrogels [307–309]. Very recently, dynamic hydrogels that were responsible for external magnetic field were demonstrated with stiffness change of several orders of magnitude, which could be applied to modulate stem cell behavior including osteogenesis and secretion of proangiogenic molecules [310]. These novel approaches might find important biomedical applications due to the versatility and tunability of these systems.…”

Section: Temporal Control Of Hydrogelmentioning

confidence: 99%

Spatially and temporally controlled hydrogels for tissue engineering

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Yue

et al. 2017

Materials Science and Engineering: R: Reports

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Summary Recent years have seen tremendous advances in the field of hydrogel-based biomaterials. One of the most prominent revolutions in this field has been the integration of elements or techniques that enable spatial and temporal control over hydrogels’ properties and functions. Here, we critically review the emerging progress of spatiotemporal control over biomaterial properties towards the development of functional engineered tissue constructs. Specifically, we will highlight the main advances in the spatial control of biomaterials, such as surface modification, microfabrication, photo-patterning, and three-dimensional (3D) bioprinting, as well as advances in the temporal control of biomaterials, such as controlled release of molecules, photocleaving of proteins, and controlled hydrogel degradation. We believe that the development and integration of these techniques will drive the engineering of next-generation engineered tissues.

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“…Kilian and co-workers designed a polyacrylamide-based hydrogel with embedded magnetic carbonyl iron particles. [31] Application of a magnetic field caused the alignment of the embedded particles, which led to hydrogel stiffening from 0.1 to ∼90 kPa [ Fig. 2(a)].…”

Section: Magnetic Field-induced Reversible Mechanical Changementioning

confidence: 99%

Dynamic bioengineered hydrogels as scaffolds for advanced stem cell and organoid culture

2017

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Bioengineered hydrogels enable systematic variation of mechanical and biochemical properties, resulting in the identification of optimal in vitro three-dimensional culture conditions for individual cell types. As the scientific community attempts to mimic and study more complex biologic processes, hydrogel design has become multi-faceted. To mimic organ and tissue heterogeneity in terms of spatial arrangement and temporal changes, hydrogels with spatiotemporal control over mechanical and biochemical properties are needed. In this prospective article, we present studies that focus on the development of hydrogels with dynamic mechanical and biochemical properties, highlighting the discoveries made using these scaffolds.

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Temporal Modulation of Stem Cell Activity Using Magnetoactive Hydrogels

Cited by 77 publications

References 59 publications

Hydrogels with Reversible Mechanics to Probe Dynamic Cell Microenvironments

Hydrogels with Reversible Mechanics to Probe Dynamic Cell Microenvironments

Spatially and temporally controlled hydrogels for tissue engineering

Dynamic bioengineered hydrogels as scaffolds for advanced stem cell and organoid culture

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