Thomas M. Jessel, Howard Hughes Medical Institute Investigator, explores the human brain, the sophisticated product of 500 million years of vertebrate evolution, assembled during just nine months of embryonic development. The functions encoded by its trillion nerve cells direct all human behavior. Yet the brain is a biological organ made from the same building blocks as skin, liver and lung. How does the brain acquire its remarkable computational power? Answers lie in the details of its construction — the cellular and molecular mechanisms that drive the formation of thousands of neural circuits, each wired for a specific behavior.
Category: computing
Beyond Neuralink: How China’s Bio-Tech Breakthrough Fuels Next-Gen Brain-Computer Interfaces
From ultra-flexible materials redefining brain-computer interfaces (BCIs) to record-shattering global out-licensing deals, China’s biopharmaceutical sector is undergoing a profound qualitative transformation. ShanghaiEye takes you inside the Yunfan Future Factory and the cross-discipline innovation hub hosted by Chia Tai Tianqing (CTTQ)—a subsidiary of top-50 global pharma giant Sino Biopharmaceutical—to explore the cutting-edge ecosystem driving the future of global healthcare.
We examine a breakthrough BCI technology developed in Shanghai: an ultra-flexible photoresist material for neural electrode arrays. Ye Tianyang, CEO and Co-Founder of Yunfan Future, explains how this material—engineered to be 1,000 times softer than the rigid alternatives utilized by Western counterparts like Elon Musk’s Neuralink—exponentially reduces tissue damage and immune rejection. With dozens of human clinical trials already successfully completed worldwide, this innovation highlights the immense strength of Shanghai’s local talent pool and medical device supply chain.
The feature also spotlights the strategic roadmap of China’s pharmaceutical leaders. Eric Tse, CEO of Sino Biopharmaceutical and Chairman of CTTQ, breaks down their vision to build an open, interdisciplinary incubator. This global nexus bridges experts, scholars, and upstream and downstream partners, transforming Shanghai into a premier launchpad for international innovative drugs. Furthermore, Mr. Tse discusses the \.
Studying the Neural Circuit Mechanisms of Cognition Using Rodents
Brody is professor of neuroscience and molecular biology at Princeton University and a Howard Hughes Medical Institute Investigator. His research focuses is on novel quantitative behaviors that allow exploring high-level cognitive questions using powerful emerging tools for studying neural mechanisms in rodents. Brody’s group uses rats to investigate the neural bases of decision making, working memory, and executive control, using a combination of high-throughput semiautomated behavior as well as computational, electrophysiological, pharmacological and optogenetic methods.
Quantum Computers Just Proved The Simulation Theory Is Terrifying
Time is something we experience every day, yet scientists still struggle to fully understand what it really is. Now, advances in quantum computing are allowing researchers to explore some of the deepest mysteries of physics—and the results are raising extraordinary questions about the nature of time itself.
By simulating complex quantum systems that were previously impossible to study, quantum computers are helping scientists test theories about causality, time reversal, and the strange behavior of particles at the quantum level. Some findings appear to challenge our most basic assumptions about how time works.
Researchers are investigating whether time is truly fundamental to the universe or whether it emerges from deeper physical processes we have yet to understand. These ideas may sound like science fiction, but they are being explored by some of the world’s leading physicists.
The implications are profound. If our understanding of time is incomplete, it could affect everything from cosmology and black holes to the future of computing and our understanding of reality itself.
In this video, we examine the groundbreaking quantum experiments, the theories they are testing, and why some scientists believe these discoveries could transform our view of the universe.
Watch until the end to uncover the most mind-bending implications of this research. Don’t forget to LIKE, SHARE, and SUBSCRIBE for more cutting-edge science, quantum mysteries, and incredible discoveries. Comment below: What do you think time really is?
The Simulated Multiverse: An MIT Computer Scientist Explores Parallel Universes, Quantum Computing, The Simulation Hypothesis and the Mandela Effect
Do multiple versions of ourselves exist in parallel universes living out their lives in different timelines?In this follow up to his bestseller, The Simulation Hypothesis, MIT Computer Scientist and Silicon Valley Game Pioneer Rizwan Virk explores these topics from a new that of simulation theory. If we are living in a digital universe, then many of the complexities and baffling characteristics of our reality start to make more sense. Quantum computing lets us simulate complex phenomena in parallel, allowing the simulation to explore many realities at once to find the most “optimum” path forward. Could this explain not only the enigmatic Mandela Effect but provide us with a new understanding of time and space? Bringing his unique trademark style of combining video games, computer science, quantum physics and computing with lots of philosophy and science fiction, Virk gives us a new way to think about not just our universe, but all possible realities!
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Particle-Simulated Foam In Custom C++ Coastal System
Leonard Saalfrank, also known as OMYOG, has showcased a custom C++ coastal renderer created as a one-week rendering challenge, exploring real-time shoreline rendering, shallow-water simulation, and GPU-driven visual effects.
The project builds on his earlier water-rendering work for Ferocious and expands it with shallow-water waves, GPU-driven breaking waves, and particle-based foam supporting up to 300K GPU particles.
Above is a render handling over 6 million triangles across all passes, using 8K textures at 2K resolution, running at around 250 FPS on an RTX 4,090 Laptop GPU with GPU profiling enabled. Without capture and profiling overhead, performance reportedly increases to around 300 FPS.
What Quantum Computers Just Proved About Time Is Terrifying
Time is something we experience every day, yet scientists still struggle to fully understand what it really is. Now, advances in quantum computing are allowing researchers to explore some of the deepest mysteries of physics—and the results are raising extraordinary questions about the nature of time itself.
By simulating complex quantum systems that were previously impossible to study, quantum computers are helping scientists test theories about causality, time reversal, and the strange behavior of particles at the quantum level. Some findings appear to challenge our most basic assumptions about how time works.
Researchers are investigating whether time is truly fundamental to the universe or whether it emerges from deeper physical processes we have yet to understand. These ideas may sound like science fiction, but they are being explored by some of the world’s leading physicists.
The implications are profound. If our understanding of time is incomplete, it could affect everything from cosmology and black holes to the future of computing and our understanding of reality itself.
In this video, we examine the groundbreaking quantum experiments, the theories they are testing, and why some scientists believe these discoveries could transform our view of the universe.
Watch until the end to uncover the most mind-bending implications of this research. Don’t forget to LIKE, SHARE, and SUBSCRIBE for more cutting-edge science, quantum mysteries, and incredible discoveries. Comment below: What do you think time really is?
Quantum hyperdimensional computing can work 500 times faster than other methods
Cleveland Clinic researchers are unlocking quantum computing’s full potential through the creation of a new computing paradigm inspired by the human brain. Fabio Cumbo, Ph.D., research associate in the lab of Daniel Blankenberg, Ph.D., associate staff, Computational Life Sciences, is developing the model, called quantum hyperdimensional computing (QHDC).
Cumbo published the first-ever implementation of QHDC in two distinct experiments in npj Unconventional Computing.
Hyperdimensional computing (HDC) is a type of computing based in neuroscience. It follows the idea that a concept in the brain is not stored on one single neuron. For example, when you think of a cat, there is no single neuron in your brain solely responsible for knowing what a cat is. That information is spread across thousands or millions of neurons, so if one neuron fails, you still remember what a cat is.
Brain-inspired chip fuses vision, memory, and processing in real time
Team leader Professor Sumeet Walia said the goal was to remove the delay and energy cost of transferring data between separate systems. “We’ve made real-time decision making a possibility with our invention, because it doesn’t need to process large amounts of irrelevant data and it’s not being slowed down by data transfer to separate processors.”
The device also showed the ability to retain visual information for longer periods without frequent electrical refresh signals, which reduces energy use and improves efficiency.
First author and RMIT PhD researcher Aishani Mazumder said the system draws inspiration from how the brain processes information. “Neuromorphic vision systems are designed to use similar analog processing to the human brain, which can greatly reduce the amount of energy needed to perform complex visual tasks compared with today’s technologies.”