TY - JOUR
KW - 3D neural tissue engineering
KW - bicontinuous scaffolds
KW - bioactive materials
KW - hierarchical microarchitectures
KW - in vitro tissue models
KW - Neural Stem Cells
AU - Prince D. Okoro
AU - Kevin Dalsania
AU - Shiril B. Iragavarapu
AU - Benjamin Dela Cruz
AU - Aihik Banerjee
AU - Merve Basaranbilek
AU - Martin F. Haase
AU - Bahman Anvari
AU - Iman Noshadi
AB - 3D tissue-engineered models hold great promise for recreating the intricate architecture and dynamic functions of neural tissues. However, replicating the nuanced structural cues of the brain in vitro remains challenging, as existing platforms often fail to capture the precise architectural motifs that regulate biological responses. Here, a bicontinuous interfacially jammed emulsion gel (bijel)-based fabrication strategy that combines solvent transfer-induced phase separation (STrIPS), microfluidics, and bioprinting to develop a Bijel-Integrated PORous Engineered System (BIPORES) for neural tissue engineering is introduced. This multifaceted approach yields scaffolds featuring interconnected micropores and textured surfaces interspersed with a hyperbolic curvature, seamlessly integrated within macroscale fibrous networks. By leveraging STrIPS of a ternary precursor mixture stabilized by amphiphilic nanoparticles, we synthesized poly(ethylene glycol) diacrylate (PEGDA) BIPORES support neural stem cell adhesion within 30 s without additional biological factors—a first for PEGDA scaffolds. Long-term cultures demonstrate extensive migration, robust proliferation, and differentiation into neuronal and astrocytic lineages, forming 3D networks with enhanced synaptic activity. Collagen encapsulation amplifies 3D cell growth, simulating native neuroanatomical compartmentalization. From a biomimicry standpoint, this multiscale fabrication strategy better approximates native neural tissue dynamics with significant implications for disease modeling, drug screening, and regenerative therapies.
BT - Advanced Functional Materials
DO - 10.1002/adfm.202509452
IS - n/a
LA - en
N2 - 3D tissue-engineered models hold great promise for recreating the intricate architecture and dynamic functions of neural tissues. However, replicating the nuanced structural cues of the brain in vitro remains challenging, as existing platforms often fail to capture the precise architectural motifs that regulate biological responses. Here, a bicontinuous interfacially jammed emulsion gel (bijel)-based fabrication strategy that combines solvent transfer-induced phase separation (STrIPS), microfluidics, and bioprinting to develop a Bijel-Integrated PORous Engineered System (BIPORES) for neural tissue engineering is introduced. This multifaceted approach yields scaffolds featuring interconnected micropores and textured surfaces interspersed with a hyperbolic curvature, seamlessly integrated within macroscale fibrous networks. By leveraging STrIPS of a ternary precursor mixture stabilized by amphiphilic nanoparticles, we synthesized poly(ethylene glycol) diacrylate (PEGDA) BIPORES support neural stem cell adhesion within 30 s without additional biological factors—a first for PEGDA scaffolds. Long-term cultures demonstrate extensive migration, robust proliferation, and differentiation into neuronal and astrocytic lineages, forming 3D networks with enhanced synaptic activity. Collagen encapsulation amplifies 3D cell growth, simulating native neuroanatomical compartmentalization. From a biomimicry standpoint, this multiscale fabrication strategy better approximates native neural tissue dynamics with significant implications for disease modeling, drug screening, and regenerative therapies.
EP - e09452
T2 - Advanced Functional Materials
TI - Bicontinuous Microarchitected Scaffolds Provide Topographic Cues That Govern Neuronal Behavior and Maturation
UR - https://onlinelibrary.wiley.com/doi/abs/10.1002/adfm.202509452
VL - n/a
Y2 - 2025-11-18
SN - 1616-3028
ER -