STEMdiff™ Forebrain Neuron Maturation Kit

Maturation kit for generation of functional neurons from human ES and iPS cell-derived neuronal precursor cells

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STEMdiff™ Forebrain Neuron Maturation Kit

Maturation kit for generation of functional neurons from human ES and iPS cell-derived neuronal precursor cells

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Maturation kit for generation of functional neurons from human ES and iPS cell-derived neuronal precursor cells

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Product Advantages

Defined and serum-free

Supports highly efficient generation of functional neurons from hPSC-derived neuronal precursors

Produces a highly pure population (≥ 90% neurons) of mixed excitatory and inhibitory neurons that can be maintained long-term in culture

Optimized for maturation of neuronal precursors generated using STEMdiff™ Forebrain Neuron Differentiation Kit

Supports neuronal activity for physiologically relevant results

Enables reproducible maturation of neuronal precursors derived from multiple human ES and iPS cell lines

What's Included

BrainPhys™ Neuronal Medium, 100 mL
STEMdiff™ Forebrain Neuron Maturation Supplement, 25 mL

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To see all required products for your protocol, please consult the Protocols and Documentation.

STEMdiff™ Neural Rosette Selection Reagent
Enzyme-free reagent for the selective detachment of neural rosettes
STEMdiff™ SMADi Neural Induction Kit
Serum-free medium kit for highly efficient SMAD inhibition-mediated neural induction of human ES and iPS cells
STEMdiff™ Forebrain Neuron Differentiation ...
Differentiation kit for the generation of neuronal precursors from human ES and iPS cell-derived neural progenitor cells
Human iPSC-Derived Neural Progenitor Cells
Frozen human neural progenitor cells differentiated from the human induced pluripotent stem cell line, SCTi003-A
DMEM/F-12 with 15 mM HEPES
Dulbecco's Modified Eagle's Medium/Nutrient Ham's Mixture F-12 (DMEM/F-12) with 15 mM HEPES buffer
Labeling Antibodies
Compatible antibodies for purity assessment of isolated cells

Overview

The STEMdiff™ Forebrain Neuron Maturation Kit is used in conjunction with the STEMdiff™ Forebrain Neuron Differentiation Kit (Catalog #08600) to generate a mixed population of forebrain-type (FOXG1-positive) neurons from neural progenitor cells derived from human pluripotent stem cells. The neurons derived are highly pure (≥ 90% class III β-tubulin-positive neurons; < 10% GFAP-positive astrocytes), functional and can be maintained long-term in culture. Neurons derived using these products are versatile tools for modeling human neurological development and disease, drug screening, toxicity testing, and cell therapy validation.

Specialized Media

Neural Cells, PSC-Derived, Neurons

Human

Cell Culture, Characterization, Differentiation, Functional Assay, Immunocytochemistry, Phenotyping

STEMdiff

Disease Modeling, Drug Discovery and Toxicity Testing, Neuroscience

Serum-Free

More Information

More Information
Safety Statement	CA WARNING: This product can expose you to chemicals including Nickel Compounds which are known to the State of California to cause cancer and birth defects or other reproductive harm. For more information go to

Data Figures

Figure 1. Schematic for the Embryoid Body Protocol

Forebrain-type neurons can be generated from NPCs after 6 days in STEMdiff™ Forebrain Neuron Differentiation Medium. For differentiation of precursors from embryonic and induced pluripotent stem cells, see the PIS. NPCs = neural progenitor cells; PIS = product information sheet

Figure 2. Schematic for the Monolayer Protocol

Forebrain-type neurons can be generated from NPCs after 6 days in STEMdiff™ Forebrain Neuron Differentiation Medium. For differentiation of precursors from embryonic and induced pluripotent stem cells, see the PIS. NPC = neural progenitor cells; PIS = product information sheet

Figure 3. Forebrain-Type Neurons Are Generated After Culture in STEMdiff™ Forebrain Neuron Differentiation and Maturation Kits

NPCs generated from hPSCs in mTeSR 1™ using the STEMdiff™ SMADi Neural Induction Kit EB protocol were differentiated and matured to forebrain-type neurons using the STEMdiff™ Forebrain Neuron Differentiation and Maturation Kits. (A) Forebrain-type neurons were formed after iPS cell-derived NPCs were cultured with the STEMdiff™ Forebrain Neuron Differentiation Kit for 7 days and STEMdiff™ Forebrain Neuron Maturation Kit for 14 days. The resulting cultures contain a highly pure population of (B) class III β-tubulin-positive neurons (green), with (C) fewer than 10% astrocytes (GFAP-positive cells, red). (D) Nuclei are labeled with DAPI (blue). NPCs = neural progenitor cells; hPSC = human pluripotent stem cell; EB = embryoid body; iPS = induced pluripotent stem

Figure 4. Downstream Differentiation of Neural Progenitor Cells to Neurons Is Possible Using the STEMdiff™ Differentiation and Maturation Kits

(A) NPCs generated from STiPS-R038 hPSCs in mTeSR™1 using the STEMdiff™ SMADi Neural Induction Kit EB protocol were differentiated and matured to cortical neurons using STEMdiff™ Forebrain Neuron Differentiation Kit for 7 days and STEMdiff™ Forebrain Neuron Maturation Kit for 14 days. The resulting cultures contain a highly pure population of (B) class III β-tubulin-positive neurons (green) with less than 10% GFAP-positive astrocytes (not shown). (C) The generated neurons are also positive for FOXG1 expression (red), indicating a forebrain-type identity. (D) Nuclei are labeled with Hoechst (blue). NPCs = neural progenitor cells; hPSC = human pluripotent stem cell

Figure 5. A Mixed Population of Forebrain-Type Cortical Neurons Is Generated Using the STEMdiff™ Differentiation and Maturation Kits

Forebrain-type neurons generated from iPSC-derived NPCs (line AIW002-02) were cultured using the STEMdiff™ Forebrain Neuron Differentiation Kit for 7 days and subsequently matured for the following 6 weeks using STEMdiff™ Forebrain Neuron Maturation Kit. The resulting cultures contain a mixed population of neurons expressing VGLUT1, a glutamatergic marker of excitatory neurons (green), as well as MAP2-positive neurons, indicating mature neurons (magenta). Nuclei are labeled with Hoechst (blue). Data courtesy of Cecilia Rocha, The Neuro's Early Drug Discovery Unit (EDDU), McGill University. iPSC = induced pluripotent stem cell; NPCs = neural progenitor cells

Figure 6. PSC-Derived Astrocytes and Neurons Can Be Co-Cultured to Model Cell-Cell Interactions In Vitro

NPCs generated from the H1 cell line were differentiated to astrocytes using STEMdiff™ Astrocyte Differentiation and Maturation Kits. H9 cell-derived NPCs were differentiated to forebrain-type neurons using STEMdiff™ Forebrain Neuron Differentiation and Maturation Kits. For co-culture, matured astrocytes were seeded onto forebrain neurons that had been in STEMdiff™ Forebrain Neuron Maturation Medium for at least one week. Co-cultures were then switched to STEMdiff™ Forebrain Neuron Maturation Medium the following day and for the remaining co-culture. (A) Neurons cultured alone, following the co-culture feeding schedule, are labeled with DCX (green). (B) DCX-positive neurons (green) and astrocytes (GFAP, red) can be co-cultured for at least 1 - 2 weeks prior to analysis. For a detailed co-culture protocol, please see the Methods Library. NPCs = neural progenitor cells

Figure 7. PSC-Derived Neurons Survive and Mature when Co-Cultured with PSC-Derived Astrocytes

NPCs generated from the STiPS-R038 cell line were differentiated to astrocytes using STEMdiff™ Astrocyte Differentiation and Maturation Kits. STiPS-M001 cell-derived NPCs were differentiated to forebrain-type neurons using STEMdiff™ Forebrain Neuron Differentiation and Maturation Kits. After co-culture for one week, neurons (A) had significantly increased neurite outgrowth as measured on MAP2-positive neurons with the NeuriteTracer plugin for ImageJ (M Pool et al. J Neurosci Methods, 2008) and (B) were more numerous than neurons cultured alone using the same feeding schedule. *, p < 0.05; **, p < 0.01. NPCs = neural progenitor cells

Protocols and Documentation

Find supporting information and directions for use in the Product Information Sheet or explore additional protocols below.

Document Type

Product Name

Catalog #

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Document Type

Product Name

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08605

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All

Language

English

Document Type

Product Name

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08605

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All

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English

Document Type

Product Name

Catalog #

08605

Lot #

All

Language

English

Applications

This product is designed for use in the following research area(s) as part of the highlighted workflow stage(s). Explore these workflows to learn more about the other products we offer to support each research area.

Research Area

Workflow Stages

Workflow Stages for Human Pluripotent Stem Cell Research

Reprogramming

Maintenance

Differentiation

Workflow Stages for hPSC-Derived Neural Cell Research

Cell Sourcing

Neural Induction

Expansion

Differentiation and Maturation

Characterization

Resources and Publications

Monkeypox virus spreads from cell-to-cell and leads to neuronal death in human neural organoids Nature Communications 2025 Jun

Abstract

In 2022-23, the world witnessed the largest recorded outbreak of monkeypox virus (MPXV). Neurological manifestations were reported alongside the detection of MPXV DNA and MPXV-specific antibodies in the cerebrospinal fluid of patients. Here, we analyze the susceptibility of neural tissue to MPXV using human neural organoids (hNOs) exposed to a clade IIb isolate. We report susceptibility of several cell types to the virus, including neural progenitor cells and neurons. The virus efficiently replicates in hNOs, as indicated by the exponential increase of infectious viral titers and establishment of viral factories. Our findings reveal focal enrichment of viral antigen alongside accumulation of cell-associated infectious virus, suggesting viral cell-to-cell spread. Using an mNeonGreen-expressing recombinant MPXV, we confirm cell-associated virus transmission. We furthermore show the formation of beads in infected neurites, a phenomenon associated with neurodegenerative disorders. Bead appearance precedes neurite-initiated cell death, as confirmed through live-cell imaging. Accordingly, hNO-transcriptome analysis reveals alterations in cellular homeostasis and upregulation of neurodegeneration-associated transcripts, despite scarcity of inflammatory and antiviral responses. Notably, tecovirimat treatment of MPXV-infected hNOs significantly reduces infectious virus loads. Our findings suggest that viral disruption of neuritic transport drives neuronal degeneration, potentially contributing to MPXV neuropathology and revealing targets for therapeutic intervention. The mechanisms underlying neurological complications of monkeypox virus infection remain unclear. Here, the authors investigate its neurotropic potential and show that neuritic transport of viral particles drives neuronal degeneration.

GRAMD1B is a regulator of lipid homeostasis, autophagic flux and phosphorylated tau D. A. Ingram et al. Nature Communications 2025 Apr

Abstract

Lipid dyshomeostasis and tau pathology are present in frontotemporal lobar degeneration (FTLD) and Alzheimer’s disease (AD). However, the relationship between lipid dyshomeostasis and tau pathology remains unclear. We report that GRAM Domain Containing 1B (GRAMD1B), a nonvesicular cholesterol transporter, is increased in excitatory neurons of human neural organoids (HNOs) with the MAPT R406W mutation. Human FTLD, AD cases, and PS19 tau mice also have increased GRAMD1B expression. We show that overexpression of GRAMD1B increases levels of free cholesterol, lipid droplets, and impairs autophagy flux. Modulating GRAMD1B in iPSC-derived neurons also alters key autophagy-related components such as PI3K, phospho-AKT, and p62, as well as phosphorylated tau, and CDK5R1. Blocking GRAMD1B function decreases free cholesterol and lipid droplets. Knocking down GRAMD1B additionally reduces phosphorylated tau, and CDK5R1 expression. Our findings elucidate the role of GRAMD1B in the nervous system and highlight its relevance to FTLD and AD. Subject terms: Diseases of the nervous system, Ageing

Transcriptomic characterization of maturing neurons from human neural stem cells across developmental time points K. Hosseini et al. IBRO Neuroscience Reports 2025 Apr

Abstract

Neurodevelopmental studies employing animal models encounter challenges due to interspecies differences and ethical concerns. Maturing neurons of human origin, undergoing several developmental stages, present a powerful alternative. In this study, human embryonic stem cell (H9 cell line) was differentiated into neural stem cells and subsequently matured into neurons over 30 days. Ion AmpliSeq™ was used for transcriptomic characterization of human stem cell-derived neurons at multiple time points. Data analysis revealed a progressive increase of markers associated with neuronal development and astrocyte markers, indicating the establishment of a co-culture accommodating both glial and neurons. Transcriptomic and pathway enrichment analysis also revealed a more pronounced GABAergic phenotype in the neurons, signifying their specialization toward this cell type. The findings confirm the robustness of these cells across different passages and demonstrate detailed progression through stages of development. The model is intended for neurodevelopmental applications and can be adapted to investigate how genetic modifications or exposure to chemicals, pharmaceuticals, and other environmental factors influence neurons and glial maturation.

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Safety Statement:

CA WARNING: This product can expose you to chemicals including Nickel Compounds which are known to the State of California to cause cancer and birth defects or other reproductive harm. For more information go to

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STEMdiff™ Forebrain Neuron Maturation Kit

Maturation kit for generation of functional neurons from human ES and iPS cell-derived neuronal precursor cells

STEMdiff™ Forebrain Neuron Maturation Kit

Maturation kit for generation of functional neurons from human ES and iPS cell-derived neuronal precursor cells

Product Advantages

What's Included

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Overview

More Information

Data Figures

Protocols and Documentation

Applications

Resources and Publications

Educational Materials (15)

Publications (5)

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