Better in vitro models with human iPSC-derived cells
Axol Bioscience is the first choice for high-quality, functionally relevant human iPSC-derived cells. Powering advanced, more human-relevant in vitro disease models.
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Find products for your researchAs drug discovery continues to explore more human-relevant approaches to disease modeling, human iPSC technology is gaining momentum. Using this technology, consented blood or skin donations from patients and healthy donors are ‘reprogrammed’ into a stem cell state, from which they can be turned into any cell type including neurons, neuroinflammatory cells, muscle cells and cardiac cells.
iPSC-derived cells can then be grown on their own (‘monocultures) or in mixtures (‘co-cultures’) of different cell types to make advanced in vitro models for research, toxicity studies and drug discovery. These models can be used to test compounds for safety and effectiveness.
High-quality iPSC-derived cells can be used to fuel robust, scalable in vitro human disease models to accelerate and de-risk drug discovery.
Axol Bioscience has spent the past decade developing the manufacturing capabilities to produce high-quality, functional iPSC-derived cells with excellent consistency. Your research can benefit from Axol’s quality-focused approach, with their catalog of robust, highly relevant iPSC-derived neurons and cardiomyocytes developed at their ISO 9001:2015-accredited production facility.
Axol’s leading axoCellsTM cell types include
- Neurons: Cortical excitatory neurons, striatal neurons, cortical inhibitory interneurons, sensory neurons, motor neurons
- Neuroinflammatory cells: Microglia, astrocytes
- Cardiomyocytes: Atrial cardiomyocytes, ventricular cardiomyocytes
- Muscle cells: Myotubes
Axol’s iPSC-derived cells have been specifically developed to fuel advanced in vitro systems for drug discovery and drug safety.
Axol provides functional cells to explore
- Neuroscience: modeling neurodegenerative and neuroinflammatory diseases including ALS, Alzheimer’s disease and Huntington’s Disease
- Pain and sensation: modeling pain and sensory function for drug discovery and neurotoxicity testing
- Cardiovascular: using functional cardiomyocytes to model cardiac diseases (including arrhythmias) and for cardiotoxicity screening
