Neurobiology

Neurobiology experiments built on cell biology technologies

Publication-backed tools and reagents designed to support every stage of your neurobiology experiments. From establishing physiologically relevant cell models to detecting and analyzing cellular changes, our solutions help you generate reliable, reproducible results with confidence. To make it easier to find the right resources for your experiments, we've organized our neurobiology portfolio around the key stages of the research workflow: culture, modification, detection, and analysis. Explore each workflow step below to discover the tools, reagents, and resources that can help accelerate your research and bring you from cell culture to meaningful conclusions.

Culture  |  Modify  |  Detect  |  Analyze
 

Advancing discovery across neurobiology research

Webinar

Discover approaches for modeling neural activity using stem cell-derived cultures and physiologically relevant systems.

Research spotlight

Examine the role of astrocyte immune priming in enhancing microglial amyloid-β clearance through APOE4 mechanisms in this recent Nature Communications publication.

Technical guidance

Explore trusted protocols established by our experienced scientists to help you get started and enable successful neurobiology experiments.


Culture—establish stable systems to build the biological foundation


Neurobiology culture solutions including media, supplements and substrates that support consistent cell identity, baseline stability, and physiologically relevant behavior over time in neural cell models, including primary rodent neurons, human neural cells, iPSCs, and 2D and 3D cultures.

Neurobiology cell culture resources

Explore neurobiology cell culture solutions for primary neurons, neural stem cells, iPSCs, and 2D/3D neural models, including optimized media, supplements, reagents, and protocols to support differentiation, maintenance, and maturation workflows.


Modify—introduce biological changes through defined experimental variables


Implementable tools that support clear cause–effect relationships and controlled experimental challenges, all while preserving often fragile culture conditions.

Research spotlight: Recreating early neuroblastoma development in hESCs

Researchers modelled neuroblastoma-associated chromosomal aberrations in human embryonic stem cells, using the Neon NxT Electroporation System to engineer MYCN-inducible stem cell lines and investigate how developmental mutations drive tumour initiation.

Protocol: Lipid-mediated transfection of human astrocytes

Optimize plasmid DNA and siRNA delivery into primary human astrocytes with this lipid-mediated transfection protocol featuring Lipofectamine LTX and RNAiMAX reagents. Includes guidance for cell preparation, matrix coating, and transfection conditions to help maximize efficiency while reducing cytotoxicity.

Protocol: Transfection of NSCs with Lipofectamine Stem Transfection Reagent in StemPro Medium

Streamline transfection of human neural stem cells using Lipofectamine Stem Transfection Reagent in StemPro NSC Serum-Free Medium. This protocol offers optimized conditions for DNA, mRNA, and CRISPR/Cas9 RNP delivery while supporting high transfection efficiency, cell viability, and stem cell maintenance.


Detect—capture and quantify biological signals to generate high-quality data


Solutions that support clear functional and phenotypic readouts and sensitivity without added noise allowing for detection of subtle culture differences.

Research spotlight: Scientists uncover how mitophagy protects against manganese-induced neuroinflammation

Researchers demonstrated that impaired mitophagy drives mitochondrial dysfunction and inflammatory STING signaling in models of manganese-induced parkinsonism. Using Invitrogen MitoSOX Red, MitoTracker Green, and Invitrogen antibodies against PINK1, Parkin, and phospho-Parkin along with other tools, the team characterized mitochondrial oxidative stress and mitophagy defects and showed that restoring mitochondrial quality control reduced neuroinflammatory injury.

Protocol: Measuring neuronal cell health through viability and neurite outgrowth

Learn how to assess neuronal cell health using fluorescence-based assays for viability, cytotoxicity, neurite outgrowth, oxidative stress, and mitochondrial function to support neurobiology research and drug discovery workflows.

Blog: Practical considerations for choosing a cell-based assay for microplate readers

Discover key considerations for selecting cell-based assays for microplate readers, including assay type, detection method, sensitivity, throughput, and workflow compatibility to support reliable and reproducible results.


Analyze—transform complex data into meaningful insights to drive evidence-based decisions


Reagents, microscopes, instruments and software that allow you to capture, analyze, and quantify cellular data with ease—turning complex neurobiology data into scientific understanding.

Multiplex neuroscience panels

Get a deeper and more thorough understanding of the progression of neuroinflammation and neurodegenerative diseases by identifying and quantitating multiple biomarkers in blood and cerebrospinal fluid (CSF) simultaneously.

Poster: Antibodies for neuroscience research

Easily find the markers you need for your neuroscience research with cell-type specific antibody recommendations and common markers for neurons, astrocytes, microglia, and oligodendrocytes.

Protocol: Optimized protein extraction reagent for neuronal tissue and primary cells

Learn an optimized method for extracting proteins from neuronal tissues and cells, including guidance on lysis conditions, sample preparation, and preservation of protein integrity for downstream neurobiology applications.

For Research Use Only. Not for use in diagnostic procedures.