Tunable Conductive Hydrogel Scaffolds for Neural Cell Differentiation

Tringides, Christina M.; Boulingre, Marjolaine; Khalil, Andrew S.; Lungjangwa, Tenzin; Jaenisch, Rudolf; Freedman, Benjamin R.

doi:10.1002/adhm.202202221

Cited by 20 publications

(19 citation statements)

References 57 publications

(77 reference statements)

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“…Furthermore, harvested materials such as Matrigel suffer from large batch-to-batch variability (69). More recently, synthetic materials, including polyethylene glycol (PEG), polyacrylamide, and peptide amphiphile hydrogels, as well as semi-synthetic materials like alginate, have been used because they are well-defined and highly tunable systems, enabling carefully defined interrogation into how specific matrix properties influence cell fate (16,21,(70)(71)(72)(73)(74)(75). Previous work using viscoelastic alginate hydrogels revealed that hNPCs exhibit greater transcriptional differences in response to changes in stress relaxation rate compared to changes in hydrogel stiffness and cell-adhesive ligand concentration; however, the range of stiffness profiled was significantly higher than the stiffness of our HELP hydrogels used in the present manuscript, and no nonstress-relaxing alginate was included as a potential control (16).…”

Section: Discussionmentioning

confidence: 99%

Tunable hydrogel viscoelasticity modulates human neural maturation

Roth,

Huang,

Navarro

et al. 2023

Sci. Adv.

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Human-induced pluripotent stem cells (hiPSCs) have emerged as a promising in vitro model system for studying neurodevelopment. However, current models remain limited in their ability to incorporate tunable biomechanical signaling cues imparted by the extracellular matrix (ECM). The native brain ECM is viscoelastic and stress-relaxing, exhibiting a time-dependent response to an applied force. To recapitulate the remodelability of the neural ECM, we developed a family of protein-engineered hydrogels that exhibit tunable stress relaxation rates. hiPSC-derived neural progenitor cells (NPCs) encapsulated within these gels underwent relaxation rate-dependent maturation. Specifically, NPCs within hydrogels with faster stress relaxation rates extended longer, more complex neuritic projections, exhibited decreased metabolic activity, and expressed higher levels of genes associated with neural maturation. By inhibiting actin polymerization, we observed decreased neuritic projections and a concomitant decrease in neural maturation gene expression. Together, these results suggest that microenvironmental viscoelasticity is sufficient to bias human NPC maturation.

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Section: Discussionmentioning

confidence: 99%

Tunable hydrogel viscoelasticity modulates human neural maturation

Roth,

Huang,

Navarro

et al. 2023

Sci. Adv.

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“…wave, wrinkle, island-bridge, origami, textile, and crack), which allows for conformability, high electron/hole mobility, low impedance/resistance, high throughput, and satisfactory sensing performance. [24][25][26][27][28] For biomolecule detection, as biomolecules could not directly produce detectable signals, biosensors generally need an extra biotransducer to selectively recognize molecules and subsequently produce electrical or optical signals. Hence, it is necessary to summarize efficient biotransduction strategies for better soft biosensors.…”

Section: Yuanyuan Tianmentioning

confidence: 99%

Emerging biotransduction strategies on soft interfaces for biosensing

Tian

Cai

et al. 2023

Nanoscale

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“…In particular, it is viscoelasticity that is able to better mimic mechanical features of natural ECM, allowing larger neurite network construction. [ 119 ] Moreover, to induce the neuronal differentiation of BMSCs, Chen and colleagues fabricated AHA‐MA/Col hybrid hydrogel microfibers composed of collagens and aldehyde‐methacrylate dual‐ functionalized HA, which possessed orthogonal nano‐alignment and viscoelasticity owing to Schiff base formation of reversible imine crosslinks and microfluidic technique. They revealed the co‐effects of nano‐alignment and viscoelasticity on neurogenesis and demonstrated that such cooperation not only improved PC12 cells morphogenesis but also allowed neuronal differentiation of BMSCs, including up‐regulation of neurogenic genes expression, such as MAP‐2, nestin, NF‐L, NF‐M, and NSE, and neuronal specific protein Tuj‐1.…”

Section: Applications Of Energy‐dissipative Hydrogels In Tissue Regen...mentioning

confidence: 99%

Energy‐Dissipative Hydrogels: A Promising Material for Tissue Regeneration^†

Lin

Zhang

et al. 2023

Chin. J. Chem.

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Comprehensive SummaryHydrogels are promising candidates for mimicking native extracellular matrix (ECM) and are therefore widely adopted as scaffolds in tissue engineering. However, conventional hydrogels composed of static networks are prone to permanent structural damages and lack the ability to provide the time‐dependent mechanical cues, which are essential for cell development, ECM remodeling, and tissue regeneration. The recent substantial development in the structurally dynamic hydrogels with energy‐dissipative ability has demonstrated the unique capability of such viscoelastic hydrogels to withstand extreme biomechanical loads and regulate cellular behaviors not present in classical hydrogels. This review starts with the general design principles for energy‐dissipative hydrogels, followed by recent advancements in fabrication approaches for energy‐dissipative hydrogels. We then highlight some applications of energy‐dissipative hydrogels in tissue engineering, including bone and cartilage regeneration, vessel regeneration, nerve regeneration, and wound healing. Finally, we discuss about the key current challenges and future development of energy‐dissipative hydrogels for biomedical applications.

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Tunable Conductive Hydrogel Scaffolds for Neural Cell Differentiation

Cited by 20 publications

References 57 publications

Tunable hydrogel viscoelasticity modulates human neural maturation

Tunable hydrogel viscoelasticity modulates human neural maturation

Emerging biotransduction strategies on soft interfaces for biosensing

Energy‐Dissipative Hydrogels: A Promising Material for Tissue Regeneration^†

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Tunable Conductive Hydrogel Scaffolds for Neural Cell Differentiation

Cited by 20 publications

References 57 publications

Tunable hydrogel viscoelasticity modulates human neural maturation

Tunable hydrogel viscoelasticity modulates human neural maturation

Emerging biotransduction strategies on soft interfaces for biosensing

Energy‐Dissipative Hydrogels: A Promising Material for Tissue Regeneration†

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Product

Resources

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Energy‐Dissipative Hydrogels: A Promising Material for Tissue Regeneration^†