Background: Alzheimer's disease (AD) is characterized by presenting a complex pathology, not fully resolved yet.
This fact, together with the lack of reliable models, has impeded the development of effective therapies. Recently,
several studies have shown that functional glial cell defects have a key role in the pathology of AD. However, this
glial dysfunction, currently, cannot be correctly modeled using the available animal models, so we hypothesized
that cells derived from Alzheimer's patients can serve as a better platform for studying the disease. In this sense,
human pluripotent stem cells (hPSC) allow the generation of different types of neural cells, which can be used for
disease modeling, identification of new targets and drugs development. Methods: We have a collection of hiPSCs
derived from patients with sporadic forms of AD stratified based on APOE genotype. We have differentiated these
cells towards neural cells and mature them to neurons or astrocytes using a serum-free approach, to assess
intrinsic differences between those derived from AD patients or healthy controls. Results: We have implemented a
serum-free approach and generated neural precursors and astrocytes from all the lines tested. We observe
differences at the phenotypic level and a reduced capacity to differentiate towards neural lineage in those lines
derived from APOE4 carriers. Conclusions: Our preliminary data suggest intrinsic differences in the neural
differentiation capacity between cell lines derived from APOE4 or APOE3 carrier subjects. Further experiments
would contribute to elucidate novel pathogenic pathways associated with neurodegeneration and susceptible of
therapeutic modulation, likely contributing to the development of new effective drugs against AD.