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Recent research has shown that defined sets of exogenous factors are sufficient to convert rodent and human somatic cells directly into induced neural stem cells or neural precursor cells(iNSCs/iNPCs).The process of transdifferentiation bypasses the step of a pluripotent state and reduces the risk of tumorigenesis and genetic instability while retaining the self-renewing capacity.This iNSC/iNPC technology has fueled much excitement in regenerative medicine,as these cells can be differentiated into target cells for replacement therapy for neurodegenerative diseases.Patients’ somatic cell-derived iNSCs/iNPCs have also been proposed to serve as disease models with potential value in both fundamental studies and clinical applications.This review focuses on the mechanisms,techniques,and applications of iNSCs/iNPCs from a series of related studies,as well as further efforts in designing novel strategies using iNSC/iNPC technology and its potential applications in neurodegenerative diseases.
Recent research has shown that defined sets of exogenous factors are sufficient to convert rodent and human somatic cells directly into induced neural stem cells or neural precursor cells (iNSCs / iNPCs). The process of transdifferentiation bypasses the step of a pluripotent state and reduces the risk of tumorigenesis and genetic instability while retaining the self-renewing capacity. This iNSC / iNPC technology has fueled much excitement in regenerative medicine, as these cells can be differentiated into target cells for replacement therapy for neurodegenerative diseases. Patients’ somatic cell-derived iNSCs / iNPCs have also been served to serve as disease models with potential value in both fundamental studies and clinical applications. This review focuses on the mechanisms, techniques, and applications of iNSCs / iNPCs from a series of related studies, as well further further novel strategies using iNSC / iNPC technology and its potential applications in neurodegenerative diseases.