Episoder

  • Today, we are speaking with the one and only Robert Sapolsky, a Stanford neurobiologist, a MacArthur "Genius", and best-selling author of books exploring the nature of stress, social behavior, and — as he puts it — "the biology of the human predicament."

    In his latest book, Determined, Sapolsky assertively lays out his vision of a world without free will — a world where as much as we feel like we're making decisions, the reality is that our choices are completely determined by biological and environmental factors outside of our control.

    Before we get into it, it's worth saying that where this is heading, the reason to care about this question is that Sapolsky's argument has profound moral implications for our understanding of justice, personal responsibility, and whether any of us deserve to be judged or praised for our actions.

    Mentioned on the Show

    Determined: A Science of Life Without Free Will (Sapolsky, 2023)Behave: The Biology of Humans at Our Best and Worst (Sapolsky, 2018 )A Primate's Memoir: A Neuroscientist's Unconventional Life Among the Baboons (Sapolsky, 2002)Free Agents: How Evolution Gave Us Free Will (Mitchell, 2023) Sapolsky / Mitchell Debates – Part 1 (2023), Part 2 (2024)

    Related Episodes

    Is addiction a disease? | Keith HumphreysBrain stimulation & "psychiatry 3.0" | Nolan WilliamsHow we understand each other | Laura Gwilliams


    Get in touch
    We're doing some listener research and we want to hear from your neurons! Email us at at [email protected] if you'd be willing to help out, and we'll be in touch with some follow-up questions.

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Join us as we dive back into the world of psychedelic medicine with anesthesiologists Boris Heifets and Theresa Lii, who share intriguing new data that sheds light on how ketamine and placebo effects may interact in treating depression.

    We explore provocative questions like: How much of ketamine's antidepressant effect comes from the drug itself versus the excitement of being in a psychedelics trial? What do we know about how placebo actually works in the brain? And should we view the placebo effect as a feature rather than a bug in psychiatric treatment?

    Join us as we examine the complex interplay between psychoactive drugs, the brain's own opioid system, and the healing power of hope in mental health care.

    Related research

    Preprint: Opioids Diminish the Placebo Antidepressant Response: A Post Hoc Analysis of a Randomized Controlled Ketamine Trial (medRxiv, 2024)Randomized trial of ketamine masked by surgical anesthesia in patients with depression (Nature Mental Health, 2023)

    Related episodes

    Psychedelics, placebo, and anesthetic dreams | Boris Heifets (Part 1) Psychedelics Inside Out: How do LSD and psilocybin alter perception? | Boris Heifets (Part 2)OCD and Ketamine | Carolyn RodriguezPsychedelics and Empathy: Why are psychiatrists taking a fresh look at MDMA? | Rob Malenka


    Related news

    Researchers find response to ketamine depends on opioid pathways, but varies by sex (Stanford Medicine, 2024)The rebirth of psychedelic medicine (Wu Tsai Neuro, 2023)Can Psychedelic Drugs Treat Physical Pain? (Scientific American, 2022)Scientists Say A Mind-Bending Rhythm In The Brain Can Act Like Ketamine (NPR, 2020)

    Get in touch
    We're doing some listener research and we want to hear from your neurons! Email us at at [email protected] if you'd be willing to help out, and we'll be in touch with some follow-up questions.

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is host

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Manglende episoder?

    Klik her for at forny feed.

  • Today, we are going back into the archives for one of my favorite episodes: We are talking to neuroscientist, entrepreneur, and best-selling author, David Eagleman. We're talking about synaesthesia — and if you don't know what that is, you're about to find out.

    Special Note
    We are beyond thrilled that From Our Neurons to Yours has won a 2024 Signal Award in the Science Podcast category. It's a big honor — thanks to everyone who voted!

    ---

    Imagine Thursday. Does Thursday have a color? What about the sound of rain — does that sound taste like chocolate? Or does the sound of a saxophone feel triangular to you?

    For about 3% of the population, the sharp lines between our senses blend together. Textures may have tastes, sounds, shapes, numbers may have colors. This sensory crosstalk is called synesthesia, and it's not a disorder, just a different way of experiencing the world.

    To learn about the neuroscience behind this fascinating phenomenon and what it tells us about how our brains perceive the world, we were fortunate enough to speak with David Eagleman, a neuroscientist, author, and entrepreneur here at Stanford who has long been fascinated by synesthesia and what it means about how our perceptions shape our reality.

    Links

    Livewired (book)Incognito (book)Wednesday Is Indigo Blue (book)Neosensory (website)Synesthete.org (website)Inner Cosmos with David Eagleman (podcast)


    Get in touch
    We're doing some listener research and we want to hear from your neurons! Email us at at [email protected] if you'd be willing to help out, and we'll be in touch with some follow-up questions.

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Earlier this year, President Obama's signature BRAIN Initiative, which has powered advances in neuroscience for the past 10 years, had its budget slashed by 40%.

    Over the past decade, the BRAIN Initiative made roughly $4 billion in targeted investments in more than 1500 research projects across the country and has dramatically accelerated progress tackling fundamental challenges in neuroscience. As we head into the next federal budget cycle, the future of the initiative remains uncertain.

    Today we take stock of how the BRAIN Initiative transformed neuroscience over the past 10 years, and what the outlook is for the future of the field.

    To give us an unparalleled behind the scenes view, we are fortunate to have Bill Newsome with us on the show. A world renowned expert in the brain mechanisms of visual perception and decision-making, Bill co-chaired the original BRAIN Initiative planning committee in 2013 (the same year he became the founding director of the Wu Tsai Neurosciences Institute here at Stanford). Don't miss this conversation!

    Learn More

    About the BRAIN Initiative NIH BRAIN Initiative websiteA Leader of Obama's New Brain Initiative Explains Why We Need It (WIRED, April 2013)BRAIN @ 10: A decade of innovation (Neuron, Sept 2024)Reflecting on a decade of BRAIN—10 Institutes and Centers, one mission (NIH BRAIN Blog, Aug 2024)

    About last year's funding cuts: Understanding the BRAIN Initiative budget (NIH BRAIN Initiative)$278 million cut in BRAIN Initiative funding leaves neuroscientists in limbo (The Transmitter, April 2024)The Future of BRAIN Initiative Funding Remains Unclear (The Transmitter, July 2024)


    Get in touch
    We're doing some listener research and we want to hear from your neurons! Email us at at [email protected] if you'd be willing to help out, and we'll be in touch with some follow-up questions.

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Given the widespread legalization of cannabis for medical and recreational uses, you'd think we'd have a better understanding of how it works. But ask a neuroscientist exactly how cannabinoid compounds like THC and CBD alter our perceptions or lead to potential medical benefits, and you'll soon learn just how little we know.

    We know that these molecules hijack an ancient signaling system in the brain called the "endocannabinoid" system (translation: the "cannabinoids within"). These somewhat exotic signaling molecules (made of fatty lipids and traveling "backwards" compared to other transmitters) have been deeply mysterious until recently, when new tools made it possible to visualize their activity directly in the brain.

    So what is the "day job" of the endocannabinoid system — and how does it connect to the dramatic highs that come with taking THC or the medical benefits of CBD?

    To unpack all this, we're talking this week with neuroscientist Ivan Soltesz, the James Doty Professor of Neurosurgery and Neuroscience at Stanford, and a leading expert on the endocannabinoid system.

    Learn More

    The Soltesz Lab"Weeding out bad waves: towards selective cannabinoid circuit control in epilepsy" (Soltesz et al, Nature Reviews Neuroscience, 2015) "Keep off the grass? Cannabis, cognition and addiction" (Parsons et al, Nature Reviews Neuroscience, 2016)"Marijuana-like brain substance calms seizures but increases aftereffects, study finds" (Goldman, Stanford Medicine News, 2021)"Retrograde endocannabinoid signaling at inhibitory synapses in vivo" (Dudok et al, Science, 2024)


    Vote for us!
    We are a finalist for a prestigious Signal Award for Best Science Podcast of 2024! Share your love for the show by voting for us in the Listener's Choice category by October 17. Thanks in advance!

    Get in touch:
    We're doing some listener research and we want to hear from your neurons! Email us at at [email protected] if you'd be willing to help out, and we'll be in touch with some follow-up questions.

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Today we are re-releasing an episode we did last year with Stanford neurobiologist Lisa Giocomo exploring the intersection of memory, navigation and the boundaries we create between ourselves and the world around us.

    This episode was inspired by the idea of memory palaces. The idea is simple: Take a place you're very familiar with, say the house you grew up in, and place information you want to remember in different locations within that space. When it's time to remember those things, you can mentally walk through that space and retrieve those items.

    This ancient technique reveals something very fundamental about how our brains work. It turns out that the same parts of the brain are responsible both for memory and for navigating through the world.

    Scientists are learning more and more about these systems and the connections between them, and it's revealing surprising insights about how we build the narrative of our lives, how we turn our environments into an internal model of who we are, and where we fit into the world.

    Join us to learn more about the neuroscience of space and memory.

    Before we get into this week’s episode, we have a favor to ask. We're working to make this show even better, and we want to hear from you. We're in the process of gathering listener input and feedback. If you'd be willing to help out, send us a short note and we'll be in touch. As always, we are at [email protected]

    Learn more:

    About Lisa Giocomo’s researchAbout the story of Henry Molaison (patient H. M.), who lost the ability to form new memories after epilepsy treatment removed his hippocampus.About the 2014 Nobel Prize in medicine, awarded to John O’Keefe and to May-Britt and Edvard Moser (Giocomo’s mentors) for their discovery of the GPS system of the brain.About Memory Palaces, a technique used since ancient times to enhance memory using mental maps.

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • In the past few years, Big Pharma has released not one, but three new treatments for Alzheimer’s disease.

    Aducanemab (2021), Lecanemab (2023), and Donanemab (2024), are the first treatments to effectively clear the brain of amyloid plaques — the sticky protein clumps whose build-up in the brain has defined the disease for decades. The problem? They may not help patients at all.

    Today’s guest, Stanford neurologist Mike Greicius, considers the new amyloid-clearing drugs a major disappointment — and worse, says they likely do more harm than good for patients.

    Despite this critique, Greicius, thinks that the next few years will be an exciting time for novel Alzheimer’s therapies, as growing biological understanding of Alzheimer’s risk and resilience bear fruit with promising new approaches to treatment.

    Learn More:

    Greicius is the Iqbal Farrukh and Asad Jamal Professor of Neurology and Neurological Sciences at Stanford Medicine, and a member of the Knight Initiative for Brain Resilience and Alzheimer's Disease Research Center at Stanford University.

    Amyloid Drug Skepticism:

    Substantial Doubt Remains about the Efficacy of Anti-Amyloid Antibodies
    (Commentary, Journal of Alzheimer's Disease, 2024)New Drug Approved for Early Alzheimer’s (New York Times, 2024)Alzheimer's drug adoption in US slowed by doctors' skepticism (Reuters, 2024)One step back: Why the new Alzheimer’s plaque-attack drugs don’t work (Stanford Medicine Scope Blog, 2024)

    Alzheimer's Genetics Research:

    Knight-funded research uncovers gene mutations that may prevent Alzheimer’s Disease (Knight Initiative for Brain Resilience, 2024)Why is a common gene variant bad for your brain? (Stanford Medicine Magazine, 2024)Scientists find genetic Alzheimer’s risk factor tied to African ancestry (Stanford Medicine, 2023)

    Episode Credits

    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Getting help for depression can be like purgatory. Setting aside for a moment the stigma and other barriers to seeking treatment in the first place, finding the right combination of medication and/or therapy can be a months- or years-long process of trial and error. And for about one third of people, nothing seems to work.

    Today we're talking with Dr. Leanne Williams, the founding director of the Stanford Center for Precision Mental Health and Wellness and Vincent V.C. Woo Professor in the Stanford Department of Psychiatry and Behavioral Sciences.

    Williams and her team have recently used brain imaging and machine learning techniques to identify six distinct "biotypes" of depression — each of which may require a different approach to treatment. Beyond setting the stage for more targeted therapies, better understanding the biology behind the disease could finally cut through the stigma of one of the world's most common brain disorders.

    Learn more

    Williams' Personalized and Translational Neuroscience Lab (PANlab)The Stanford Center for Precision Mental Health and WellnessNEW: Cognitive behavioral therapy enhances brain circuits to relieve depression (Stanford Medicine, 2024)Six distinct types of depression identified in Stanford Medicine-led study
    (Stanford Medicine, 2024)Personalized brain circuit scores identify clinically distinct biotypes in depression and anxiety (Nature Medicine, 2024)Brain scans could help personalize treatment for people who are depressed or suicidal (Science, 2022)Williams' scientific publications

    Episode Credits
    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.


    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Today, we're talking with Stanford neuro-oncologist, Michelle Monje. This is actually the third time we've had Michelle on the show, in part because she's been a pioneer of three exciting frontiers in neuroscience — so far!

    This week, we're going to talk about cancer neuroscience. Michelle founded this new field with her discovery that deadly brain tumors not only link up physically with the healthy brain tissue surrounding them, but the cancers actually need the brain's electrical activity to grow and spread.

    It turns out that many cancers — not only in the brain — depend on nervous system innervation for their survival. Understanding this dependent relationship better may present an exciting new line of attack for oncology.

    Join us to learn more!

    News coverage

    Brain tumors caused by normal neuron activity in mice predisposed to such tumorsBrain tumors form synapses with healthy neurons, Stanford-led study findsDeadly brain cancers act like 'vampires' by hijacking normal cells to growEngineered immune cells target broad range of pediatric solid tumors in mice

    Relevant Publications

    Glioma synapses recruit mechanisms of adaptive plasticityGlioblastoma remodelling of human neural circuits decreases survivalElectrical and synaptic integration of glioma into neural circuitsTargeting neuronal activity-regulated neuroligin-3 dependency in high-grade gliomaNeuronal Activity Promotes Glioma Growth through Neuroligin-3 Secretion

    Review Articles

    The neuroscience of cancerCancer hallmarks intersect with neuroscience in the tumor microenvironmentRoadmap for the Emerging Field of Cancer Neuroscience


    Episode Credits
    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • This week on From Our Neurons to Yours, we're talking about using new techniques for growing human brain tissue in the lab to solve a rare neurological disorder.

    Host Nicholas Weiler sits down with Sergiu Pasca an innovative Stanford scientist who has developed groundbreaking technologies to grow human brain tissue in the lab, creating "organoids" and "assembloids" that model brain disorders like autism and schizophrenia.

    Pasca describes the process of turning patient skin cells into embryo-like stem cells and then into functional brain cells that can live and develop for over two years, and even be transplanted into rat brains to study their growth and development.

    It may sound like science fiction, but these techniques represent a major step toward understanding and treating complex neurological conditions such as Timothy syndrome, a rare genetic disorder whose biology Pasca has spent the past 15 years unraveling.

    Join us for fascinating glimpse into the future of developmental neuroscience and potential for new therapies for our remarkable self-assembling brains.


    Learn more

    Brain organoids and assembloids are new models for elucidating, treating neurodevelopmental disorders | News Center | Stanford MedicineImpact of genes linked to neurodevelopmental diseases found | News Center | Stanford MedicineScientists discover how dozens of genes may contribute to autism - The Washington PostStudy suggests approach for treating rare disorder | National Institutes of Health (NIH)How lab-grown brain cells can now help us understand brain disorders


    Episode Credits
    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Today, we're going to talk about virtual reality and how it could be used to treat depression.

    We're talking with psychiatrist Kim Bullock, the founding director of Stanford's Neurobehavioral Clinic and Virtual Reality & Immersive Technologies (VRIT) program.

    Dr. Bullock — a physician certified in Neuropsychiatry, Psychiatry, and Lifestyle Medicine — calls herself a "radical behaviorist." Like other practitioners of cognitive behavioral therapy (CBT), she sees the troublesome thoughts and emotional states of many psychiatric disorders as just another form of behavior, which can be reshaped through self awareness and practice — much like you might work at avoiding junk food or not biting your nails.

    Of course, one of the biggest challenges is the practice part. It's no easy task for patients to practice experiencing the world in a more positive, healthy way. This is why Bullock is eager for practitioners of CBT and related forms of psychotherapy to embrace virtual reality technologies — which enable psychiatrists to prescribe precisely calibrated "experiences" to treat cognitive & behavioral disorders.

    We started by discussing early results from a clinical trial for a virtual reality-enhanced intervention major depressive disorder, which Dr. Bullock recently launched with support from the Wu Tsai Neurosciences Institute Neuroscience:Translate program.

    Join us to learn more about how VR is transforming the world of psychotherapy!

    Learn More

    Imagining virtual reality as a simple tool to treat depression (Stanford Medicine, 2024)Extended Reality(XR) enhanced behavioral activation for treatment of Major Depressive Disorder (2022 Neuroscience:Translate grant)Clinical Trial: Virtual Reality Behavioral Activation: An Intervention for Major Depressive DisorderThe Stanford Virtual Reality and Immersive Technologies (VR-IT) ProgramRecent VR-IT publications

    Episode Credits
    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • The skin is full of contradictions. It’s soft and sensitive, but also tough and resilient, even self-healing. It’s both the barrier that protects us from infections and our most intimate connection with the outside world.

    Today’s guest, Zhenan Bao, has spent the last two decades reverse engineering the skin’s many remarkable properties in order to create wearable electronics that are just as soft, flexible, and versatile as the skin itself.

    Bao envisions a world where stick-on devices could help heal injuries, manage anxiety, and even enhance our perceptions, and soft, implanted devices could give neurosciences new insights into the workings of the body and brain.

    In today’s episode, we talk about what makes the skin such an intriguing problem for an engineer like Bao; some of the many applications of her technology for medicine, neuroscience, and mental health; and its potential to enhance or extend our perceptions.

    Bao is K.K. Lee Professor of Chemical Engineering at Stanford and founding director of eWEAR — the Stanford Wearable Electronics Initiative.


    Learn More

    Bao Lab website

    Stanford Wearable Electronics Initiative (eWEAR)

    Advancing toward wearable, stretchable electronics | Stanford News (2024)

    Soft ‘e-skin’ that talks to the brain | Stanford News (2023)

    The Science of Skin | STANFORD magazine (2023)

    Skin Inspired Electronics: Changing the Future of Electronics with Zhenan Bao (2023)

    Dr. Zhenan Bao Keynote - Stanford Center for Precision Mental Health & Wellness Symposium (2022)

    Episode Credits
    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.


    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • This week, we're diving into recent research that sheds light on a new form of brain plasticity involving changes in the insulation of nerve fibers — called myelin. It turns out that myelin plasticity is implicated in a number of serious conditions, from epilepsy to drug abuse and addiction.

    We're excited to bring back two previous guests on the show to share their insights on this previously unknown form of plasticity: Stanford psychiatry professor Rob Malenka (S1 E1 - Psychedelics and Empathy), a pioneer in the study of synaptic plasticity and addiction, and neuro-oncologist Michelle Monje (S1 E12 - Brain Fog), who made some of the very first observations of myelin plasticity in the brain, essentially founding this field.

    Together, they discuss their recent findings on the role of myelin plasticity in opioid addiction and its implications for understanding addictive behaviors.

    Get ready to nerd out as we uncover a new angle on our brain's remarkable capacity for change.

    Learn More

    Myelination in the brain may be key to ‘learning’ opioid addiction | Stanford Medicine (2024)

    Adaptive and maladaptive myelination in health and disease | Nature Reviews Neurology (2022)

    Brain plasticity promotes worsening of epileptic seizures, study finds | Stanford Medicine (2022)

    The Brain Learns in Unexpected Ways | Scientific American (2020)

    Brain boosting: It's not just grey matter that matters | New Scientist (2015)

    Neural activity promotes brain plasticity through myelin growth, researchers find | News Center | Stanford Medicine (2014)


    Episode Credits
    This episode was produced by Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • -- We're re-releasing our conversation with Carla Shatz, one of our favorites from the archive, which comes up all the time on the show in the context of brain plasticity and aging. Enjoy, and see you next time! -NW --

    When we're kids, our brains are amazing at learning. We absorb information from the outside world with ease, and we can adapt to anything. But as we age, our brains become a little more fixed. Our brain circuits become a little less flexible.

    You may have heard of a concept called neuroplasticity, our brain's ability to change or rewire itself. This is of course central to learning and memory, but it's also important for understanding a surprisingly wide array of medical conditions, including things like epilepsy, depression, even Alzheimer's disease.

    Today's guest, Carla Shatz, is a pioneer in understanding how our brains are sculpted by our experiences. She's credited with coining the phrase neurons that fire together, wire together. Her work over the past 40 years is foundational to how we understand the brain today.

    So I was excited to talk to Shatz about our brain's capacity for change, and I started off by asking about this sort of simple question, why exactly do we have this learning superpower as kids to do things like pick up languages and why does it go away?

    Shatz is Sapp Family Provostial Professor of Biology and of Neurobiology and the Catherine Holman Johnson director of Stanford Bio-X.

    Learn More

    In conversation with Carla Shatz (Nature Neuroscience)Carla Shatz, her breakthrough discovery in vision and the developing brain (Stanford Medicine Magazine)Making an Old Brain Young | Carla Shatz (TEDxStanford)Carla Shatz Kavli Prize Laureate LectureStanford scientists discover a protein in nerves that determines which brain connections stay and which go (Wu Tsai Neurosciences Institute)

    Episode Credits
    This episode was produced by Webby award-winning producer Michael Osborne, with production assistance by Morgan Honaker, and hosted by Nicholas Weiler. Art by Aimee Garza.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Hi everyone — quick programming announcement. As we head into summer, we'll be moving to an every-other-week cadence as we prepare more conversations from the frontiers of neuroscience. I'm very excited about what we're working on for you, so stay tuned!

    In the meantime, we'd love to hear from you! Email us at [email protected] with your thoughts, praise, critiques, or just to say hello.

    That's all for now. See you next time!

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • The powerful new generation of AI tools that has come out over the past few years — DALL-E, ChatGPT, Claude, Gemini, and the rest — have blown away our old ideas about what AI can do and raised questions about what it means for computers to start acting... intelligent?

    This week, we ask what the rise of these systems might teach us about our own biological intelligence — and vice versa. What does modern neuroscience have to say about how AI could become as flexible, efficient, and resilient as the human brain.

    Few people are better positioned to speak to the intersection of neuroscience and AI than today's guest: Surya Ganguli.

    Ganguli's lab produced some of the first diffusion models — which are at the foundation of today's AI revolution — and is now working to understand how complex emergent properties arise from biological and artificial neural networks.

    Ganguli is a member of the Neuroscience Theory Center at the Wu Tsai Neurosciences Institute, a Senior Fellow at Stanford's Institute for Human-Centered Artificial Intelligence (HAI), and an associate professor in Stanford's Department of Applied Physics.

    Further Reading

    Interpreting the retinal neural code for natural scenes: From computations to neurons (Neuron, 2023)Beyond neural scaling laws: beating power law scaling via data pruning (arXiv, 2023)Cortical layer-specific critical dynamics triggering perception (Science, 2019)Stanford team stimulates neurons to induce particular perceptions in mice's minds (Stanford Medicine, 2019)What DALL-E reveals about human creativity (Wu Tsai Neurosciences Institute, 2023)

    Visit us!
    Want to learn more about AI and Neuroscience? Join us at Wu Tsai Neuro's annual symposium on October 17, 2024, which will showcase the frontiers of biological and artificial intelligence research. (More details coming soon!)

    Episode credits
    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • At some point in our lives, we all struggle with memory — learning a new name, remembering that book you were reading just yesterday or that word on the tip of your tongue.

    So what can neuroscience teach us about why we remember, why we forget, and how we might even improve our memories?

    To answer this question, I spoke with neuroscientist Anthony Wagner, a memory expert in Stanford's Department of Psychology.

    Learn More
    Wagner lab website

    Recent lab publicationsAnthony's new book: Brain Sciences for Lawyers, Judges, and Policymakers (2024). Jones, O. D., Schall, J. D., Shen, F. X., Hoffman, M. B., & Wagner, A. D. Oxford University Press. Order

    Stress thwarts our ability to plan ahead by disrupting how we use memory, Stanford study finds (Stanford News 2020)

    Stanford researchers link poor memory to attention lapses and media multitasking (Stanford News, 2020)

    Episode credits
    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Today, we're going to talk about how psychedelics alter our perception of reality and what that says about... reality!

    Welcome to part two of our conversation with Stanford anesthesiologist and psychedelics researcher Boris Heifets!

    Last time, we talked with Boris about the question of why psychedelics help people with mental health disorders.

    This week, we're going to dive into a different question, which is to explore how psychedelics work in the brain. How are they able to alter something as fundamental as our perceptions of reality — and could understanding these effects teach us about the nature of our everyday perceptions?

    Learn more:

    Review: Therapeutic mechanisms of psychedelics and entactogens (Heifets and Olsen, 2024)As psychedelics near approval, there’s no consensus on how they work (STAT News, 2023)How do psychedelics work? (Carhart-Harris, 2019)Heifets Lab website


    Episode credits
    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • Psychedelics are a hot topic in psychiatry today. They’re producing dramatic reversals for patients with severe depression, PTSD, and other mental health conditions. But scientists still have fundamental questions about why these drugs are so effective.

    For example, is the "trip" even necessary? Some think it is not and are working to design drugs with similar brain chemistry but no psychoactive effects — “Taking the trip out of the drug.”

    Others suspect that many of the benefits of psychedelics can be attributed to hype and expectation: People expect to get better, so they do.

    Normally scientists control for placebo using a blinded study where patients don't know if they're getting the real treatment or a sugar pill. But how are you going to do this with mind-altering substances? Patients are probably going to figure out pretty quickly whether they got a sugar cube with or without LSD.

    Today's guest, Stanford anesthesiologist Boris Heifets, has come up with a particularly clever strategy to tease apart the psychedelic experience, biochemistry, hype and placebo.

    Listen for the whole story!

    Learn more:

    The Heifets Lab at Stanford MedicineThe Early Days of a Psychedelic Resurgence? (Stanford Medicine Magazine, 2024)

    Depression, ketamine & anesthesia:

    Randomized trial of ketamine masked by surgical anesthesia in patients with depression (Nature 2023 - paywall)Ketamine’s effect on depression may hinge on hope (Stanford Medicine, 2023)

    Anesthetic dreams and trauma recovery:

    Case report 1: dreaming & knife attack (A & A Practice, 2022 - paywall)Case report 2: dreaming & PTSD (American Journal of Psychiatry, 2024)Could anesthesia-induced dreams wipe away trauma? (Stanford Medicine, 2024)Video: Mothers with PTSD following their sons' deaths talk about dreaming of their sons under anesthesia (Heifets Lab, 2024 — content advisory)

    Related episodes:

    S1 E1: Psychedelics and EmpathyS3 E3: OCD and Ketamine

    Episode credits
    This episode was produced by

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.

  • This week on From Our Neurons to Yours, we're talking about the neuroscience of climate change with neuroeconomist Nik Sawe.

    If you follow the science or the news, you know how big of a risk climate change is. Storms, coastal flooding, heat waves, extinctions, mass migration — the list goes on.

    But — as you can probably also appreciate — it’s really hard to properly perceive that risk. It’s much easier to focus on today’s emergency, this week’s looming deadline, this quarter’s economic forecast — where the risks are objectively much smaller, but feel more pressing.

    This is where neuroscience comes in: Why are our brains so bad at perceiving this existential, long-term risk to our society and our planet? And are there ways we could work with our brains' limitations to improve our decision-making around environmental issues and the future more broadly?

    To answer this question, we spoke with Nik Sawe, a neuro-economist who uses brain imaging to study environmental decision making in the lab of Brian Knutson in the Stanford Department of Psychology. Nik is also a policy analyst at the think tank Energy Innovation, where he is working on policy avenues to reduce carbon emissions in the industrial sector.

    References

    Parks donation FMRI studyEcolabeling/energy-efficient purchasing FMRI study"Price of your soul" study by Greg BernsDan Kahan science literacy/numeracy and climate change risk studyBrain stimulation for perspective-taking of future generations

    Episode Credits

    This episode was produced by Michael Osborne at 14th Street Studios, with production assistance by Morgan Honaker. Our logo is by Aimee Garza. The show is hosted by Nicholas Weiler at Stanford's Wu Tsai Neurosciences Institute and the Knight Initiative for Brain Resilience.

    Send us a text!

    Thanks for listening! If you're enjoying our show, please take a moment to give us a review on your podcast app of choice and share this episode with your friends. That's how we grow as a show and bring the stories of the frontiers of neuroscience to a wider audience.

    Learn more about the Wu Tsai Neurosciences Institute at Stanford and follow us on Twitter, Facebook, and LinkedIn.