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Generation and Functional Characterization of hiPSC-Derived Cortical and Sensory Neurons

Generation and Functional Characterization of hiPSC-Derived Cortical and Sensory Neurons content piece image

Advances in human-induced pluripotent stem cell (hiPSC) technology enables the generation of donor-derived healthy and diseased cell lines. This has greatly benefitted the study of human disease phenotypes that are difficult to reproduce in animal models.

Therefore, hiPSCs provide an attractive option for use in a number of applications including human disease modeling, drug screening, personalized medicine, cell-based therapy, and toxicity studies. However, hiPSC generation remains labor-intensive, expensive and technically challenging with the validation of correct function and pharmacology requiring a substantial investment in time, expertise and equipment.

Attend the webinars to discover how to: 

  • Reprogram donor cells to iPSCs
  • Edit genes of interest
  • Differentiate iPSCs to relevant subtypes
  • Validate phenotypically relevant function and pharmacology

Session 2: Generation and Functional Characterization of hiPSC-Derived Cortical and Sensory Neurons

During this webinar, we will discuss our hiPSC-derived cortical and sensory neurons, co-culture and their electrophysiological characterization using microelectrode arrays (MEA). The focus is on the development of disease models, co-culture, pharmacology and neurotoxicity screening.

Speakers
Giovanna De Filippi, PhD
Giovanna De Filippi, PhD
Business Development Manager, EMEA Axion Biosystems
Steven Broadbent, PhD
Steven Broadbent, PhD
Senior Scientist (Electrophysiology) and Product Specialist, Axol Bioscience Ltd