Cellular reprogramming allows for the de novo generation of human neurons and glial cells from patients with neurological and psychiatric disorders. Crucially, this technology preserves the genome of the donor individ...Cellular reprogramming allows for the de novo generation of human neurons and glial cells from patients with neurological and psychiatric disorders. Crucially, this technology preserves the genome of the donor individual and thus provides a unique opportunity for systematic investigation of genetic influences on neuronal pathophysiology. Although direct reprogramming of adult somatic cells to neurons is now possible, the majority of recent studies have used induced pluripotent stem cells (iPSCs) derived from patient fibroblasts to generate neural progenitors that can be differentiated to specific neural cell types. Investigations of monogenic diseases have established proof-of-principle for many aspects of cellular disease modeling, including targeted differentiation of neuronal populations and rescue of phenotypes in patient iPSC lines. Refinement of protocols to allow for efficient generation of iPSC lines from large patient cohorts may reveal common functional pathology and genetic interactions in diseases with a polygenic basis. We review several recent studies that illustrate the utility of iPSC-based cellular models of neurodevelopmental and neurodegenerative disorders to identify novel phenotypes and therapeutic approaches.展开更多
The quest to find novel therapeutics for mental and neurological disorders has been hindered by the lack of access to l ive human brain samples and relevant experimental models. Conventional 2D human pluripotent st...The quest to find novel therapeutics for mental and neurological disorders has been hindered by the lack of access to l ive human brain samples and relevant experimental models. Conventional 2D human pluripotent stem cell-derived neuronal cultures and animal models do not ful ly recapitulate many endogenous human biochemical processes and disease phenotypes. Currently, the majority of candidate drugs obtained from preclinical testing in conventional systems does not usually translate into success and have a high failure rate in clinical trials. Recent advancements in bioengineering and stem cell technologies have resulted in three-dimensional brain-like tissues, such as oragnoids, which better resemble endogenous tissue and are more physiologically relevant than monolayer cultures. These brain-like tissues can bridge the gap between existing models and the patient, and may revolutionize the field of translational neuroscience. Here, we discuss utilities and challenges of using stem cell-derived human brain tissues in basic research and pharmacotherapy.展开更多
文摘Cellular reprogramming allows for the de novo generation of human neurons and glial cells from patients with neurological and psychiatric disorders. Crucially, this technology preserves the genome of the donor individual and thus provides a unique opportunity for systematic investigation of genetic influences on neuronal pathophysiology. Although direct reprogramming of adult somatic cells to neurons is now possible, the majority of recent studies have used induced pluripotent stem cells (iPSCs) derived from patient fibroblasts to generate neural progenitors that can be differentiated to specific neural cell types. Investigations of monogenic diseases have established proof-of-principle for many aspects of cellular disease modeling, including targeted differentiation of neuronal populations and rescue of phenotypes in patient iPSC lines. Refinement of protocols to allow for efficient generation of iPSC lines from large patient cohorts may reveal common functional pathology and genetic interactions in diseases with a polygenic basis. We review several recent studies that illustrate the utility of iPSC-based cellular models of neurodevelopmental and neurodegenerative disorders to identify novel phenotypes and therapeutic approaches.
文摘The quest to find novel therapeutics for mental and neurological disorders has been hindered by the lack of access to l ive human brain samples and relevant experimental models. Conventional 2D human pluripotent stem cell-derived neuronal cultures and animal models do not ful ly recapitulate many endogenous human biochemical processes and disease phenotypes. Currently, the majority of candidate drugs obtained from preclinical testing in conventional systems does not usually translate into success and have a high failure rate in clinical trials. Recent advancements in bioengineering and stem cell technologies have resulted in three-dimensional brain-like tissues, such as oragnoids, which better resemble endogenous tissue and are more physiologically relevant than monolayer cultures. These brain-like tissues can bridge the gap between existing models and the patient, and may revolutionize the field of translational neuroscience. Here, we discuss utilities and challenges of using stem cell-derived human brain tissues in basic research and pharmacotherapy.
