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Navigating Brain Organoid Maturation: From Benchmarking Frameworks to Multimodal Bioengineering Strategies

Jingxiu Huang, Yingli Zhu, Jiong Tang, Yang Liu, Ming Lu, Rongxin Zhang, Alfred Xuyang Sun

2025Biomolecules11 citationsDOIOpen Access PDF

Abstract

Brain organoid technology has revolutionized in vitro modeling of human neurodevelopment and disease, providing unprecedented insights into cortical patterning, neural circuit assembly, and pathogenic mechanisms of neurological disorders. Critically, human brain organoids uniquely recapitulate human-specific developmental processes-such as the expansion of outer radial glia and neuromelanin-that are absent in rodent models, making them indispensable for studying human brain evolution and dysfunction. However, a major bottleneck persists: Extended culture periods (≥6 months) are empirically required to achieve late-stage maturation markers like synaptic refinement, functional network plasticity, and gliogenesis. Yet prolonged conventional 3D culture exacerbates metabolic stress, hypoxia-induced necrosis, and microenvironmental instability, leading to asynchronous tissue maturation-electrophysiologically active superficial layers juxtaposed with degenerating cores. This immaturity/heterogeneity severely limits their utility in modeling adult-onset disorders (e.g., Alzheimer's disease) and high-fidelity drug screening, as organoids fail to recapitulate postnatal transcriptional signatures or neurovascular interactions without bioengineering interventions. We summarize emerging strategies to decouple maturation milestones from rigid temporal frameworks, emphasizing the synergistic integration of chronological optimization (e.g., vascularized co-cultures) and active bioengineering accelerators (e.g., electrical stimulation and microfluidics). By bridging biological timelines with scalable engineering, this review charts a roadmap to generate translationally relevant, functionally mature brain organoids.

Topics & Concepts

OrganoidNeuroscienceBiologyHuman brainConnectomicsInduced pluripotent stem cellTimelineComputational biologyEmbryonic stem cellConnectomeFunctional connectivityHistoryGeneArchaeologyBiochemistryPluripotent Stem Cells Research3D Printing in Biomedical ResearchNeuroscience and Neural Engineering
Navigating Brain Organoid Maturation: From Benchmarking Frameworks to Multimodal Bioengineering Strategies | Litcius