Podcasts about uc san diego stem cell program

Uma visão detalhada de um estudo conduzido pelo laboratório Alysson Muotri no Programa de Células-Tronco da UC San Diego, que encontrou o desenvolvimento de sinalização de redes complexas em organoides corticais humanos que parecem recapitular o desenvolvimento do cérebro fetal, oferecendo um modelo in vitro para estudar o desenvolvimento funcional de redes neuronais humanas. Series: "O Canal de Células-Tronco" [Spanish Language] [Show ID: 35153]

A detailed overview of a study conducted by Alysson Muotri's lab at the UC San Diego Stem Cell Program which found complex network signaling developing in human cortical organoids that appear to recapitulate fetal brain development, offering an in-vitro model to study functional development of human neuronal networks. Series: "Stem Cell Channel" [Science] [Show ID: 34267]

A detailed overview of a study conducted by Alysson Muotri's lab at the UC San Diego Stem Cell Program which found complex network signaling developing in human cortical organoids that appear to recapitulate fetal brain development, offering an in-vitro model to study functional development of human neuronal networks. Series: "Stem Cell Channel" [Science] [Show ID: 34267]

A detailed overview of a study conducted by Alysson Muotri's lab at the UC San Diego Stem Cell Program which found complex network signaling developing in human cortical organoids that appear to recapitulate fetal brain development, offering an in-vitro model to study functional development of human neuronal networks. Series: "Stem Cell Channel" [Science] [Show ID: 34267]

A detailed overview of a study conducted by Alysson Muotri's lab at the UC San Diego Stem Cell Program which found complex network signaling developing in human cortical organoids that appear to recapitulate fetal brain development, offering an in-vitro model to study functional development of human neuronal networks. Series: "Stem Cell Channel" [Science] [Show ID: 34267]

Cerebral organoids, also known as mini-brains, are tridimensional self-organized structures derived from stem cells that resemble the early stages of the human embryonic brain. This new tool allows researchers to explore fundamental neurodevelopmental steps otherwise inaccessible in utero experimentally. Alysson Muotri, UC San Diego Stem Cell Program, explains how mini brains are generated in his lab and how this strategy can create novel therapeutical insights on neurogenetic disorders, such as autism. He also describes the use of mini-brains to explore the uniqueness of the human brain compared to other extinct species, such as the Neanderthals. Limitations and ethical concerns surrounding this exciting technology are also discussed. Series: "Exploring Ethics" [Humanities] [Science] [Show ID: 33715]

Cerebral organoids, also known as mini-brains, are tridimensional self-organized structures derived from stem cells that resemble the early stages of the human embryonic brain. This new tool allows researchers to explore fundamental neurodevelopmental steps otherwise inaccessible in utero experimentally. Alysson Muotri, UC San Diego Stem Cell Program, explains how mini brains are generated in his lab and how this strategy can create novel therapeutical insights on neurogenetic disorders, such as autism. He also describes the use of mini-brains to explore the uniqueness of the human brain compared to other extinct species, such as the Neanderthals. Limitations and ethical concerns surrounding this exciting technology are also discussed. Series: "Exploring Ethics" [Humanities] [Science] [Show ID: 33715]

Researchers at the UC San Diego Stem Cell Program have used a rare disorder, Aicardi Goutieres (AGS), to explore fundamental brain mechanisms. By utilizing cortical organoids, or brains in a dish, they have tracked neurodevelopment while discovering new information about the relationship between retrotransposons and neuroinflammation. Series: "UCTV Prime" [Health and Medicine] [Show ID: 32743]

Researchers at the UC San Diego Stem Cell Program have used a rare disorder, Aicardi Goutieres (AGS), to explore fundamental brain mechanisms. By utilizing cortical organoids, or brains in a dish, they have tracked neurodevelopment while discovering new information about the relationship between retrotransposons and neuroinflammation. Series: "UCTV Prime" [Health and Medicine] [Show ID: 32743]

Researchers at the UC San Diego Stem Cell Program have used a rare disorder, Aicardi Goutieres (AGS), to explore fundamental brain mechanisms. By utilizing cortical organoids, or brains in a dish, they have tracked neurodevelopment while discovering new information about the relationship between retrotransposons and neuroinflammation. Series: "UCTV Prime" [Health and Medicine] [Show ID: 32743]

Researchers at the UC San Diego Stem Cell Program have used a rare disorder, Aicardi Goutieres (AGS), to explore fundamental brain mechanisms. By utilizing cortical organoids, or brains in a dish, they have tracked neurodevelopment while discovering new information about the relationship between retrotransposons and neuroinflammation. Series: "UCTV Prime" [Health and Medicine] [Show ID: 32743]

Stem cells, cells that have the ability to develop into different cell types, hold great promise for the treatment and prevention of Alzheimer’s disease. Dr. Larry Goldstein – Distinguished Professor in the Department of Cellular and Molecular Medicine at University of California, San Diego; Director of the UC San Diego Stem Cell Program; Director of the Sanford Stem Cell Clinical Center; and Scientific Director of the Sanford Consortium for Regenerative Medicine – joined us for November’s Alzheimer’s Talks. He described some of the groundbreaking research being done and offered a glimpse of potential future therapies and treatments for Alzheimer’s disease using stem cell technology.Support the show (https://www.usagainstalzheimers.org/ways-donate)