As scientists overcome the technical challenges in reprogramming stem cells to produce biologically precise models of human neurons, these emerging model systems will accelerate research on understanding neuronal activity, brain development, and neurological diseases, and will drive the discovery of new patient-specific, reprogramming-based therapies. Recent technological advances, current challenges, and future clinical applications are discussed in an article published recently.
Anjana Nityanandam (pictured top) and Kristin K. Baldwin (pictured bottom), The Scripps Research Institute, La Jolla, CA, describe the limitations of currently available reprogramming-based methods to reproduce accurate models of neurological diseases. The authors review the latest advances in reprogramming-based technologies, particularly those related to human induced pluripotent stem cells (hiPSCs), and approaches to produce specific subtypes of neurons with high specificity and efficiency. Among the goals of future research discussed in this article are the development of methods to generate and combine multiple neural subtypes to create three-dimensional models of entire brain regions in the laboratory, to generate tissue structures that mimic the developing brain, to optimize gene editing techniques for correcting disease mutations, and to accelerate aging of hiPSC-derived neurons for use in the discovery of novel therapies targeting age-related neurologic diseases.
"Neurologists and stem cell biologists alike should look to this excellent, truly comprehensive review as a tour de force of critical examination" says Editor-in-Chief Graham C. Parker, PhD, The Carman and Ann Adams Department of Pediatrics, Wayne State University School of Medicine, Detroit, MI.
Illustration: The Scripps Research Institute.
Mary Ann Liebert, Inc. Publishers News Release (05/19/15)
Abstract (Stem Cells & Development; Vol. 24, Issue 11, 1265-1283 (06/01/15))