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BrainPhysâ„¢ Without Phenol Red

Serum-free neurophysiological basal medium for improved neuronal function

BrainPhysâ„¢ Without Phenol Red

Serum-free neurophysiological basal medium for improved neuronal function

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Serum-free neurophysiological basal medium for improved neuronal function
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Product Advantages


  • More representative of the brain’s extracellular environment

  • Improved neuronal function and a higher proportion of synaptically active neurons

  • Perform functional assays without changing media and shocking cells

  • Supports long-term culture of ES/iPS cell- and CNS-derived neurons

  • Rigorous raw material screening and quality control ensure minimal lot-to-lot variability

Overview

Promote, rather than inhibit, neuronal activity and maturity in your cultured primary or human pluripotent stem cell (hPSC)-derived neurons in a phenol red-free environment.

Based on the formulation by Bardy and Gage (Bardy C et al. PNAS, 2015), BrainPhysâ„¢ serum-free neuronal basal medium is optimized to yield a higher proportion of synaptically active neurons by mimicking the central nervous system extracellular environment. Use BrainPhysâ„¢ Without Phenol Red to culture primary neurons, differentiate and mature hPSC-derived neurons, record microelectrode array-based neuronal activity, live-fluorescent image neurons, and transdifferentiate somatic cells to neurons without hormonal signaling.

To ensure cell survival in long-term serum-free culture, BrainPhysâ„¢ Without Phenol Red must be combined with an appropriate serum-replacement supplement, such as NeuroCultâ„¢ SM1 Neuronal Supplement (Catalog #05711) and/or N2 Supplement-A (Catalog #07152).
Subtype
Basal Media, Specialized Media
Cell Type
Neural Cells, PSC-Derived, Neurons, Pluripotent Stem Cells
Species
Human, Mouse, Rat
Application
Cell Culture, Differentiation, Maintenance
Brand
BrainPhys
Area of Interest
Disease Modeling, Drug Discovery and Toxicity Testing, Neuroscience, Stem Cell Biology
Formulation Category
Serum-Free

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 #
Lot #
Language
Document Type
Product Name
Catalog #
05791
Lot #
All
Language
English
Document Type
Product Name
Catalog #
05791
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.

Resources and Publications

Publications (4)

Microglia determine an immune-challenged environment and facilitate ibuprofen action in human retinal organoids Journal of Neuroinflammation 2025 Apr

Abstract

Prenatal immune challenges pose significant risks to human embryonic brain and eye development. However, our knowledge about the safe usage of anti-inflammatory drugs during pregnancy is still limited. While human induced pluripotent stem cells (hIPSC)-derived brain organoid models have started to explore functional consequences upon viral stimulation, these models commonly lack microglia, which are susceptible to and promote inflammation. Furthermore, microglia are actively involved in neuronal development. Here, we generate hIPSC-derived microglia precursor cells and assemble them into retinal organoids. Once the outer plexiform layer forms, these hIPSC-derived microglia (iMG) fully integrate into the retinal organoids. Since the ganglion cell survival declines by this time in 3D-retinal organoids, we adapted the model into 2D and identify that the improved ganglion cell number significantly decreases only with iMG presence. In parallel, we applied the immunostimulant POLY(I:C) to mimic a fetal viral infection. While POLY(I:C) exposure alters the iMG phenotype, it does not hinder their interaction with ganglion cells. Furthermore, iMG significantly enhance the supernatant’s inflammatory secretome and increase retinal cell proliferation. Simultaneous exposure with the non-steroidal anti-inflammatory drug (NSAID) ibuprofen dampens POLY(I:C)-mediated changes of the iMG phenotype and ameliorates cell proliferation. Remarkably, while POLY(I:C) disrupts neuronal calcium dynamics independent of iMG, ibuprofen rescues this effect only if iMG are present. Mechanistically, ibuprofen targets the enzymes cyclooxygenase 1 and 2 (COX1/PTGS1 and COX2/PTGS2) simultaneously, from which iMG mainly express COX1. Selective COX1 blockage fails to restore the calcium peak amplitude upon POLY(I:C) stimulation, suggesting ibuprofen’s beneficial effect depends on the presence and interplay of COX1 and COX2. These findings underscore the importance of microglia in the context of prenatal immune challenges and provide insight into the mechanisms by which ibuprofen exerts its protective effects during embryonic development.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12974-025-03366-x.
Complex activity and short-term plasticity of human cerebral organoids reciprocally connected with axons Nature Communications 2024 Apr

Abstract

An inter-regional cortical tract is one of the most fundamental architectural motifs that integrates neural circuits to orchestrate and generate complex functions of the human brain. To understand the mechanistic significance of inter-regional projections on development of neural circuits, we investigated an in vitro neural tissue model for inter-regional connections, in which two cerebral organoids are connected with a bundle of reciprocally extended axons. The connected organoids produced more complex and intense oscillatory activity than conventional or directly fused cerebral organoids, suggesting the inter-organoid axonal connections enhance and support the complex network activity. In addition, optogenetic stimulation of the inter-organoid axon bundles could entrain the activity of the organoids and induce robust short-term plasticity of the macroscopic circuit. These results demonstrated that the projection axons could serve as a structural hub that boosts functionality of the organoid-circuits. This model could contribute to further investigation on development and functions of macroscopic neuronal circuits in vitro. Connecting cerebral organoids with an axon bundle models inter-regional projections and enhances neural activity. Optogenetic stimulation induces short-term plasticity, offering insights into macroscopic circuit development and functionality.
Mutations in ACTL6B Cause Neurodevelopmental Deficits and Epilepsy and Lead to Loss of Dendrites in Human Neurons. S. Bell et al. American journal of human genetics 2019

Abstract

We identified individuals with variations in ACTL6B, a component of the chromatin remodeling machinery including the BAF complex. Ten individuals harbored bi-allelic mutations and presented with global developmental delay, epileptic encephalopathy, and spasticity, and ten individuals with de novo heterozygous mutations displayed intellectual disability, ambulation deficits, severe language impairment, hypotonia, Rett-like stereotypies, and minor facial dysmorphisms (wide mouth, diastema, bulbous nose). Nine of these ten unrelated individuals had the identical de novo c.1027G{\textgreater}A (p.Gly343Arg) mutation. Human-derived neurons were generated that recaptured ACTL6B expression patterns in development from progenitor cell to post-mitotic neuron, validating the use of this model. Engineered knock-out of ACTL6B in wild-type human neurons resulted in profound deficits in dendrite development, a result recapitulated in two individuals with different bi-allelic mutations, and reversed on clonal genetic repair or exogenous expression of ACTL6B. Whole-transcriptome analyses and whole-genomic profiling of the BAF complex in wild-type and bi-allelic mutant ACTL6B neural progenitor cells and neurons revealed increased genomic binding of the BAF complex in ACTL6B mutants, with corresponding transcriptional changes in several genes including TPPP and FSCN1, suggesting that altered regulation of some cytoskeletal genes contribute to altered dendrite development. Assessment of bi-alleic and heterozygous ACTL6B mutations on an ACTL6B knock-out human background demonstrated that bi-allelic mutations mimic engineered deletion deficits while heterozygous mutations do not, suggesting that the former are loss of function and the latter are gain of function. These results reveal a role for ACTL6B in neurodevelopment and implicate another component of chromatin remodeling machinery in brain disease.