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Scientists Keep Teaching Life to Play Doom, But Why?

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Hello and welcome! My name is Anton and in this video, we will talk about why Doom is used in scientific experiments involving learning.
Links:
https://arxiv.org/pdf/2602.11632
https://corticallabs.com/cl1
• Rats in Doom.
https://theconversation.com/how-scien
#doom #biology #learning.

0:00 Doom runs on everything.
1:03 Brain organoids and why they are used.
2:50 New breakthrough — a biological computer.
3:50 How cells learns to play Doom.
5:10 Rats and Doom.
6:20 Organoids and engineering problems.
7:00 Implications for biology and information sciences.
9:08 Conclusions.

Enjoy and please subscribe.

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Immune cells get transformed into fungus-fighting nanoparticles

Tiny particles made from the membranes of human immune cells could offer a promising new way to fight fungal infections that are becoming harder to treat. Engineers at the University of California San Diego created antifungal nanoparticles that target Candida albicans, a fungus responsible for oral and vaginal yeast infections as well as life-threatening bloodstream infections. In mice with severe Candida infections, the nanoparticles greatly reduced the amount of fungus in major organs and significantly improved survival.

The research, published in Cell Biomaterials, was led by Liangfang Zhang, a professor in the Aiiso Yufeng Li Family Department of Chemical and Nano Engineering at the UC San Diego Jacobs School of Engineering, who also holds the Joan and Irwin Jacobs Chancellor’s Endowed Chair in Innovations for Engineering in Medicine.

Ultrasound-based pacemaker noninvasively steadies the heart

MIT engineers have developed a noninvasive pacemaker that stimulates the heart using ultrasound. The design could one day provide a surgery-free alternative to traditional cardiac implants.

The new device is designed as a small sticker that can be worn on the chest. Tiny transducers on the sticker send ultrasound pulses through the chest to stimulate the heart. The ultrasound waves trigger the opening of certain ion channels in heart cells, an effect the researchers amplified through genetic engineering. When the channels open, they let in calcium, which signals a heart cell to squeeze and beat.

In experiments in the lab, the researchers applied ultrasound waves to engineered human cardiac cells and found that the pulses effectively maintained the cells’ healthy contractions. They also tested the ultrasound sticker on rats and found the device quickly, safely, and noninvasively corrected arrhythmias and restored normal, regular heart contractions.

Sia Performs “Unstoppable” To Close the 2025 Breakthrough Prize Ceremony

Multi-platinum recording artist Sia closed the Breakthrough Prize ceremony with an inspiring rendition of “Unstoppable” as all prize laureates returned to the stage to a standing ovation.
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The eleventh Breakthrough Prize awards celebrated outstanding scientific achievements, honoring scientists driving remarkable discoveries in gene editing, human diseases, the search for the fundamental laws of the Universe and pure mathematics. Held at the Barker Barker Hangar in Santa Monica, CA, presentations were given by Christina Aguilera, Drew Barrymore, MrBeast, Lily Collins, Vin Diesel, Jodie Foster, Gal Gadot, Salma Hayek Pinault, Ke Huy Quan, Gayle King, Edward Norton, Gwyneth Paltrow, Seth Rogen, Lauren Sanchez, Jeremy Strong, will.i.am, and more. With live performances by Katy Perry and Sia. Continued at https://breakthroughprize.org/News/92.

Full show: • 2025 Breakthrough Prize Ceremony: Full Show.

https://breakthroughprize.org

Optimizing RNA design with AI and an Ising machine: Encoding matters

RNA has emerged as one of the most promising molecules in modern medicine, enabling advances from mRNA vaccines and gene therapies to genome editing and synthetic biology. However, designing RNA molecules that reliably fold into a desired secondary structure remains a major challenge. Even for relatively short sequences, the number of possible nucleotide combinations grows exponentially, making it difficult to identify optimal candidates. As a result, conventional computational methods often require extensive candidate evaluations, creating a significant bottleneck when experimental validation is both time-consuming and costly.

To address this challenge, researchers from Keio University, led by Project Lecturer Shuta Kikuchi of the Graduate School of Science and Technology and Professor Shu Tanaka of the Department of Applied Physics and Physico-Informatics, developed a novel RNA inverse folding framework based on factorization machine with quadratic optimization annealing (FMQA). This machine learning– and Ising machine–driven black-box optimization approach is designed to identify high-quality RNA sequence candidates with relatively few evaluations.

“We investigated a new application of FMQA in biomolecular design, where its potential remains relatively unexplored. Since RNA, DNA and protein sequences are inherently categorical in nature, it is unclear how converting them into binary representations affects optimization performance. In this study, we examined RNA inverse folding and the influence of different encoding and assignment choices within FMQA,” says Dr. Kikuchi. The findings are published in Scientific Reports.

How a Revolutionary Cancer Treatment Could Reset the Immune Systems of Patients With Autoimmune Diseases

But there are other possible CAR T risks for autoimmune patients. In February, FDA officials published a paper endorsing CAR T’s potential in autoimmunity but warning of “unpredictable long-term toxicity.” CAR T treatment for cancer, the authors noted, has been linked to diverse long-term issues such as Parkinson’s disease. There have also been cases in which the bioengineered cells themselves turned malignant, causing new, T cell-based cancers.

Causing a secondary cancer may be an acceptable risk when treating a life-threatening cancer, but probably not for autoimmunity, says Matt Lunning, medical director for gene and cellular therapy at Nebraska Medicine, in Omaha. How to balance the risk between the impacts of an autoimmune disease, which can range widely in severity, and the difficult-to-quantify risk of future side effects or cancers remains a major open question.

Researchers are already working on second-and third-generation versions of CAR T that they expect to be safer for both cancer and autoimmunity. For example, James Howard, a neuromuscular neurologist at the University of North Carolina at Chapel Hill, is testing a technology from a company called Cartesian Therapeutics that encodes the CAR using molecules of mRNA, the short-lived genetic messenger used in Covid-19 vaccines, instead of long-lasting DNA. The CAR T cells should wipe out B cells for only as long as the mRNA persists, then lose their B cell-targeting abilities. With no chance for genetically modified T cells to hang around long-term, there should be no cancer risk.

DiGem- Digital Twin

🧬 What if every human had their own Digital Twin?

Not in 100 years.

Not in science fiction.

But within our lifetime.

For the past months, I’ve been building DiGem — a project focused on creating a Human Digital Twin: a digital representation of a person that combines health data, AI, lifestyle habits, and gamification into one system.

Imagine:

⚡ Your body displayed as a dashboard 🧠 AI acting as your personal health coach 📈 Real-time monitoring of your health and performance 🎮 Improving yourself through levels, XP, and achievements 🧬 A digital twin that evolves together with you.

Scientists Recreate Life’s Building Blocks | Artificial Cell Performs Life-Like Functions | WION

Scientists have unveiled a synthetic cell capable of performing several life-like functions, marking a major milestone in modern biology. The breakthrough does not mean researchers have created life from scratch, but it does bring science closer to understanding how living systems emerge from simple chemical components. The artificial cell, known as \.

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