2025-12-30 23:00:00
Large Language Models Are Improving ExponentiallyGlenn Zorpette | IEEE Spectrum
“According to a metric [METR] devised, the capabilities of key LLMs are doubling every seven months. This realization leads to a second conclusion, equally stunning: By 2030, the most advanced LLMs should be able to complete, with 50 percent reliability, a software-based task that takes humans a full month of 40-hour workweeks. And the LLMs would likely be able to do many of these tasks much more quickly than humans, taking only days, or even just hours.”
There Is Only One AI Company. Welcome to the BlobSteven Levy | Wired ($)
“Even the most panicked Cassandra of a decade ago likely didn’t imagine that advanced AI would be controlled by a single, interlocking, money-seeking behemoth. …This rococo collection of partnerships, mergers, funding arrangements, government initiatives, and strategic investments links the fate of virtually every big player in the AI-o-sphere. I call this entity the Blob.”
The Next Revolution in Biology Isn’t Reading Life’s Code—It’s Writing ItAndrew Hessel | Big Think
“Andrew Hessel, cofounder of the Human Genome Project–write, argues that genome writing is humanity’s next great moonshot, outlining how DNA synthesis could transform biology, medicine, and industry. He calls for global cooperation to ensure that humanity’s new power to create life is used wisely and for the common good.”
Should We Intervene in Evolution? The Ethics of ‘Editing’ NatureDavid Farrier | Aeon
“It wasn’t our intention that humanity would become the planet’s greatest evolutionary force; yet the fact that we are confronts us with an urgent and difficult question. Some animals, plants and insects can adapt but, for many, the pace of change is too great. Should we try to save them by deliberately intervening in their evolution?”
The Quantum Apocalypse Is Coming. Be Very AfraidAmit Katwala | Wired ($)
“One day soon, at a research lab near Santa Barbara or Seattle or a secret facility in the Chinese mountains, it will begin: the sudden unlocking of the world’s secrets. Your secrets. Cybersecurity analysts call this Q-Day—the day someone builds a quantum computer that can crack the most widely used forms of encryption.”
9 Federally Funded Scientific Breakthroughs That Changed EverythingAlan Burdick and Emily Anthes | The New York Times ($)
“‘Basic research is the pacemaker of technological progress,’ Vannevar Bush, who laid out the postwar schema for government research support, wrote in a 1945 report to President Franklin D. Roosevelt. Look no further than Google, which got its start in 1994 with a $4 million federal grant to help build digital libraries; the company is now a $2 trillion verb.”
Covid Vaccines Have Paved the Way for Cancer VaccinesJoão Medeiros | Wired ($)
“Going from mRNA Covid vaccines to mRNA cancer vaccines is straightforward: same fridges, same protocol, same drug, just a different patient. In the current trials, we do a biopsy of the patient, sequence the tissue, send it to the pharmaceutical company, and they design a personalized vaccine that’s bespoke to that patient’s cancer. That vaccine is not suitable for anyone else. It’s like science fiction.”
Scientists Grow More Hopeful About Ending a Global Organ ShortageRoni Caryn Rabin | The New York Times ($)
“In a modern glass complex in Geneva last month, hundreds of scientists from around the world gathered to share data, review cases—and revel in some astonishing progress. Their work was once considered the stuff of science fiction: so-called xenotransplantation, the use of animal organs to replace failing kidneys, hearts, and livers in humans.”
This Baby Boy Was Treated With the First Personalized Gene-Editing DrugAntonio Regalado | MIT Technology Review ($)
“Doctors say they constructed a bespoke gene-editing treatment in less than seven months and used it to treat a baby with a deadly metabolic condition. The rapid-fire attempt to rewrite the child’s DNA marks the first time gene editing has been tailored to treat a single individual, according to a report published in the New England Journal of Medicine.”
It’s Waymo’s World. We’re All Just Riding in It.Ben Cohen | The Wall Street Journal ($)
“[Waymo] cracked a million total paid rides in late 2023. By the end of 2024, it reached five million. We’re not even halfway through 2025 and it has already crossed a cumulative 10 million. At this rate, Waymo is on track to double again and blow past 20 million fully autonomous trips by the end of the year. ‘This is what exponential scaling looks like,’”’ said Dmitri Dolgov, Waymo’s co-chief executive, at Google’s recent developer conference.”
This Incredible Map Shows the World’s 2.75 Billion BuildingsJesus Diaz | Fast Company
“From the latest skyscraper in a Chinese megalopolis to a six‑foot‑tall yurt in Inner Mongolia, researchers at the Technical University of Munich claim they have created a map of all buildings worldwide: 2.75 billion building models set in high‑resolution 3D with a level of precision never before recorded.”
Renewable Energy and EVs Have Grown So Much Faster Than Experts Predicted 10 Years AgoAdele Peters | Fast Company
“There’s now four times as much solar power as the International Energy Agency (IEA) expected 10 years ago. Last year alone, the world installed 553 gigawatts of solar power—roughly as much as 100 million US homes use—which is 1,500% more than the IEA had projected. …More than 1 in 5 new cars sold worldwide today is an EV; a decade ago, that number was fewer than 1 in 100. Even if growth flatlined now, the world is on track to reach 100 million EVs by 2028.”
Why the AI ‘Megasystem Problem’ Needs Our AttentionEric Markowitz | Big Think
“What if the greatest danger of artificial intelligence isn’t a single rogue system, but many systems quietly working together? Dr. Susan Schneider calls this the ‘megasystem problem’: networks of AI models colluding in ways we can’t predict, producing emergent structures beyond human control.”
Life Lessons From (Very Old) Bowhead WhalesCarl Zimmer | The New York Times ($)
“By measuring the molecular damage that accumulates in the eyes, ears, and eggs of bowhead whales, researchers have estimated that bowheads live as long as 268 years. A study published in the journal Nature [this year] offers a clue to how the animals manage to live so long: They are extraordinarily good at fixing damaged DNA.”
The Quest to Sequence the Genomes of EverythingGlenn Zorpette | IEEE Spectrum
“The road map calls for more than 1.65 million genome sequences between 2030 and 2035 at a cost of $1,900 per genome. If they can pull it off, the entire project will have cost roughly $4.7 billion—considerably less in real terms than what it cost to do just the human genome 22 years ago.”
The Ocean Teems With Networks of Interconnected BacteriaVeronique Greenwood | Quanta
“The Prochlorococcus [bacteria] population may be more connected than anyone could have imagined. They may be holding conversations across wide distances, not only filling the ocean with envelopes of information and nutrients, but also linking what we thought were their private, inner spaces with the interiors of other cells.”
An Entire Book Was Written in DNA—and You Can Buy It for $60Emily Mullin | Wired ($)
“DNA data storage isn’t exactly mainstream yet, but it might be getting closer. Now you can buy what may be the first commercially available book written in DNA. Today, Asimov Press debuted an anthology of biotechnology essays and science fiction stories encoded in strands of DNA. For $60, you can get a physical copy of the book plus the nucleic acid version—a metal capsule filled with dried DNA.”
Inside San Francisco’s Robot Fight ClubAshlee Vance | Core Memory
“For the past few months, Cix Liv—real name—has been operating his company REK out of a no-frills warehouse space off Van Ness in San Francisco. The office has a couple of makeshift desks with computers and a bunch of virtual reality headsets on some shelves. More to the point, REK also has four humanoid-style robots hanging from gantries, and they’ve been outfitted with armor, boxing gloves, swords, and backstories.”
Not Just Heat Death: Here Are Five Ways the Universe Could EndPaul Sutter | Ars Technica
“If you’re having trouble sleeping at night, have you tried to induce total existential dread by contemplating the end of the entire universe? If not, here’s a rundown of five ideas exploring how ‘all there is’ might become ‘nothing at all.’ Enjoy.”
The Dream of Offshore Launches Is Finally Blasting OffBecky Ferreirra | MIT Technology Review ($)
“‘The best way to build a future where we have dozens, hundreds, or maybe thousands of spaceports is to build them at sea,’ says Tom Marotta, CEO and founder of the Spaceport Company, which is working to establish offshore launch hubs. ‘It’s very hard to find a thousand acres on the coast over and over again to build spaceports. It’s very easy to build the same ship over and over again.'”
The Hottest Thing in Clean EnergyAlexander C. Kaufman | The Atlantic ($)
“For now, most of the efforts to debut next-generation geothermal technology are still in the American West, where drilling is relatively cheap and easy because the rocks they’re targeting are closer to the surface. But if the industry can prove to investors that its power plants work as described—which experts expect to happen by the end of the decade—geothermal could expand quickly, just like oil-and-gas fracking did.”
Firefly Releases Stunning Footage of Blue Ghost Landing on the MoonPassant Rabie | Gizmodo
“The Texas-based company released a clip of Blue Ghost’s descent toward the moon followed by a smooth landing. The footage is a masterclass in lunar landings, capturing striking views of the lander emerging from a cloud of dust, its shadow stretching across the moon’s surface in a superhero-like stance.”
AI Coding Assistant Refuses to Write Code, Tells User to Learn Programming InsteadBenj Edwards | Ars Technica
“The AI assistant halted work and delivered a refusal message: ‘I cannot generate code for you, as that would be completing your work. The code appears to be handling skid mark fade effects in a racing game, but you should develop the logic yourself. This ensures you understand the system and can maintain it properly.'”
Meet the Man Building a Starter Kit for CivilizationTiffany Ng | MIT Technology Review ($)
“[The Global Village Construction Set (GVCS) is] a set of 50 machines—everything from a tractor to an oven to a circuit maker—that are capable of building civilization from scratch and can be reconfigured however you see fit.”
Just One Exo-Earth Pixel Can Reveal Continents, Oceans, and MoreEthan Siegel | Big Think
“In the coming years and decades, several ambitious projects will reach completion, finally giving humanity the capability to image Earth-size planets at Earth-like distances around Sun-like stars. …Remarkably, even though these exo-Earths will appear as just one lonely pixel in our detectors, we can use that data to detect continents, oceans, icecaps, forests, deserts, and more.”
How AGI Became the Most Consequential Conspiracy Theory of Our TimeWill Douglas Heaven | MIT Technology Review ($)
“The idea that machines will be as smart as—or smarter than—humans has hijacked an entire industry. But look closely and you’ll see it’s a myth reminiscent of more explicitly outlandish and fantastical schemes. …I get it, I get it—calling AGI a conspiracy isn’t a perfect analogy. It will also piss a lot of people off. But come with me down this rabbit hole and let me show you the light.”
A Virtual Cell Is a ‘Holy Grail’ of Science. It’s Getting Closer.Matteo Wong | The Atlantic ($)
“Scientists are now designing computer programs that may unlock the ability to simulate human cells, giving researchers the ability to predict the effect of a drug, mutation, virus, or any other change in the body, and in turn making physical experiments more targeted and likelier to succeed.”
InventWood Is About to Mass-Produce Wood That’s Stronger Than SteelTim De Chant | TechCrunch
“The result is a material that has 50% more tensile strength than steel with a strength-to-weight ratio that’s 10 times better, the company said. It’s also Class A fire rated, or highly resistant to flame, and resistant to rot and pests.”
What If AI Doesn’t Get Much Better Than This?Cal Newport | The New Yorker
“In the aftermath of GPT-5’s launch, it has become more difficult to take bombastic predictions about AI at face value, and the views of critics like [Gary] Marcus seem increasingly moderate. Such voices argue that this technology is important, but not poised to drastically transform our lives. They challenge us to consider a different vision for the near-future—one in which AI might not get much better than this.”
I Gave the Police Access to My DNA—and Maybe Some of YoursAntonio Regalado | MIT Technology Review
“Scientists estimate that a database including 2% of the US population, or 6 million people, could identify the source of nearly any crime-scene DNA, given how many distant relatives each of us has. Scholars of big data have termed this phenomenon ‘tyranny of the minority.’ One person’s voluntary disclosure can end up exposing the same information about many others. And that tyranny can be abused.”
The $460 Billion Quantum Bitcoin Treasure HuntKyle Torpey | Gizmodo
“Early Bitcoin addresses, including many that have been connected to Bitcoin creator Satoshi Nakamoto, may also be associated with private keys (passwords to the Bitcoin accounts basically) that are lost or otherwise not accessible to anyone. In other words, they’re sort of like lost digital treasure chests that a quantum computer could potentially unlock at some point in the future.”
The post These Were Our Favorite Tech Stories From Around the Web in 2025 appeared first on SingularityHub.
2025-12-29 23:00:00
We can guess what the universe will look like a few billion years into the future, but eventually things could get weird.
Curious Kids is a series for children of all ages. If you have a question you’d like an expert to answer, send it to [email protected].
“How will the Universe end? – Iez M., age 9, Rochester, New York
Whether the universe will “end” at all is not certain, but all evidence suggests it will continue being humanity’s cosmic home for a very, very long time.
The universe—all of space and time, and all matter and energy—began about 14 billion years ago in a rapid expansion called the Big Bang, but since then it has been in a state of continuous change. First, it was full of a diffuse gas of the particles that now make up atoms: protons, neutrons, and electrons. Then, that gas collapsed into stars and galaxies.
Our understanding of the future of the universe is informed by the objects and processes we observe today. As an astrophysicist, I observe objects like distant galaxies, which lets me study how stars and galaxies change over time. By doing so, I develop theories that predict how the universe will change in the future.
Predicting the future of the universe by extending what we see today is extrapolation. It’s risky, because something unexpected could happen.
Interpolation—connecting the dots within a dataset—is much safer. Imagine you have a picture of yourself when you were 5 years old, and then another when you were 7 years old. Someone could probably guess what you looked like when you were 6. That’s interpolation.
Maybe they could extrapolate from the two pictures to what you’d look like when you are 8 or 9 years old, but no one can accurately predict too far into the future. Maybe in a few years you get glasses or suddenly get really tall.
Scientists can predict what the universe will probably look like a few billion years into the future by extrapolating how stars and galaxies change over time, but eventually things could get weird. The universe and the stuff within might once again change, like it has in the past.
Good news: The sun, our medium-sized yellow star, is going to continue shining for billions of years. It’s about halfway through its 10 billion-year lifetime. The lifetime of a star depends on its size. Big, hot, blue stars live shorter lives, while tiny, cool, red stars live for much longer.
Today, some galaxies are still producing new stars, but others have depleted their star-forming gas. When a galaxy stops forming stars, the blue stars quickly go “supernova” and disappear, exploding after only a few million years. Then, billions of years later, the yellow stars like the sun eject their outer layers into a nebula, leaving only the red stars puttering along. Eventually, all galaxies throughout the universe will stop producing new stars, and the starlight filling the universe will gradually redden and dim.
In trillions of years—hundreds of times longer than the universe’s current age—these red stars will also fade away into darkness. But until then, there will be lots of stars providing light and warmth.
Think of building a sand castle on the beach. Each bucket of sand makes the castle bigger and bigger. Galaxies grow over time in a similar way by eating up smaller galaxies. These galactic mergers will continue into the future.
In galaxy clusters, hundreds of galaxies fall inward toward their shared center, often resulting in messy collisions. In these mergers, spiral galaxies, which are orderly disks, combine in chaotic ways into disordered blob-shaped clouds of stars. Think of how easy it is to turn a well-constructed sand castle into a big mess by kicking it over.
For this reason, the universe over time will have fewer spiral galaxies and more elliptical galaxies because the spiral galaxies combine into elliptical galaxies.
The Milky Way galaxy and the neighboring Andromeda galaxy might combine in this way in a few billion years. Don’t worry: The stars in each galaxy would whiz past each other totally unharmed, and future stargazers would get a fantastic view of the two galaxies merging.
The Big Bang kick-started an expansion that probably will continue in the future. The gravity of all the stuff in the universe—stars, galaxies, gas, dark matter—pulls inward and slows down the expansion, and some theories suggest that the universe’s expansion will coast along or slow to a halt.
However, some evidence suggests that some unknown force is starting to exert a repulsive force, causing expansion to speed up. Scientists call this outward force dark energy, but very little is known about it. Like raisins in a baking cookie, galaxies will zoom away from each other faster and faster. If this continues into the future, other galaxies might be too far apart to observe from the Milky Way.
To summarize the best current prediction of the future: Star formation will shut down, so galaxies will be full of old, red, dim stars gradually cooling into darkness. Each group or cluster of galaxies will merge into a single, massive, elliptical galaxy. The accelerated expansion of the universe will make it impossible to observe other galaxies beyond the local group.
This scenario eventually winds down into a dark eternity, lasting trillions of years. New data might come to light that changes this story, and the next stage in the universe’s history might be something totally different and unexpectedly beautiful. Depending on how you look at it, the universe might not have an “end,” after all. Even if what exists is very different from how the universe is now, it’s hard to envision a distant future where the universe is entirely gone.
How does this scenario make you feel? It sometimes makes me feel wistful, which is a type of sadness, but then I remember we live at a very exciting time in the story of the universe: right at the start, in an era full of exciting stars and galaxies to observe! The cosmos can support human society and curiosity for billions of years into the future, so there’s lots of time to keep exploring and searching for answers.
This article is republished from The Conversation under a Creative Commons license. Read the original article.
The post How Will the Universe End? The Dark Eternity That Awaits Us Trillions of Years From Now appeared first on SingularityHub.
2025-12-27 23:00:00
Readers went all-in on biotech this year. Gene editing brought the broad treatment of genetic disease into view; cancer-fighting T cells took on tumors; and scientists found a way to 3D print tissues inside the body. Beyond biotech, AI chips and progress in quantum computing made waves; humanoid robots began to look almost affordable; and Kawasaki dreamed up a robot you ride like a horse. Here’s to another year of breakthroughs—thanks for reading!
Parkinson’s Patients Say Their Symptoms Eased After Receiving Millions of New Brain CellsShelly Fan
“Medications can keep some [Parkinson’s] symptoms at bay, but eventually, their effects wear off. For nearly half a century, scientists have been exploring an alternative solution: replacing dying dopamine neurons with new ones. [This year], two studies of nearly two dozen people with Parkinson’s showed the strategy is safe. A single transplant boosted dopamine levels for 18 months without notable side effects. Patients had few motor symptoms, even when they stopped taking regular medications.”
New Gene Therapy Reverses Three Diseases With Shots to the BloodstreamShelly Fan
“A team from the IRCCS San Raffaele Scientific Institute in Italy treated infant mice for three blood-related genetic diseases with a custom gene-editing shot that directly edited cells in the mice’s blood. …The edits were long-lasting and survived when transplanted into mice who had not been given the therapy. A dose of ‘mobilizing agents’—chemicals that stimulate cells in the blood and immune system—further boosted the effect in young adult mice.”
A Humanoid Robot Is Now on Sale for Under $6,000—What Can You Do With It?Kartikeya Walia
“[Unitree’s R1 is] a humanoid robot priced at under $6,000. That’s not pocket change, but it’s orders of magnitude cheaper than most robots in its class, which can run into tens or even hundreds of thousands of dollars. The R1 packs serious mobility, sensors, and AI potential into a package that could fit in a university lab, a workspace—or even, if you’re adventurous, your living room.”
Scientists Can Now 3D Print Tissues Directly Inside the Body—No Surgery NeededShelly Fan
“Dubbed deep tissue in vivo sound printing (DISP), the system uses an injectable bioink that’s liquid at body temperature but solidifies into structures when blasted with ultrasound. A monitoring molecule, also sensitive to ultrasound, tracks tissue printing in real time. Excess bioink is safely broken down by the body.”
Forget Nvidia: DeepSeek AI Runs Near Instantaneously on These Weird ChipsJason Dorrier
“Whereas answers can take minutes to complete on other hardware, Cerebras said that its version of DeepSeek knocked out some coding tasks in as little as 1.5 seconds. According to Artificial Analysis, the company’s wafer-scale chips were 57 times faster than competitors running the AI on GPUs and hands down the fastest. That was last week. Yesterday, Groq overtook Cerebras at the top with a new offering.”
Meta’s New AI Translates Speech in Real Time Across More Than 100 LanguagesShelly Fan
“Using a voice synthesizer, the system translates words spoken in 101 languages into 36 others—not just into English, which tends to dominate current AI interpreters. In a head-to-head evaluation, the algorithm is 23 percent more accurate than today’s top models—and nearly as fast as expert human interpreters. It can also translate text into text, text into speech, and vice versa.”
Kawasaki Is Building a Robot You Ride Like a HorseMatías Mattamala
“A video shows the automated equine galloping through valleys, crossing rivers, climbing mountains, and jumping over crevasses. …Kawasaki’s current motorbikes are constrained to roads, paths, and trails, but a machine with legs has no boundaries—it can reach places no other vehicles can go.”
Scientists Target Incurable Mitochondrial Diseases With New Gene Editing ToolsShelly Fan
“Many [mitochondrial] diseases are inherited. But none are treatable. …The new study, published in Science Translational Medicine, took a new approach [to treatment]—gene therapy. Using a genetic tool called base editing to target mitochondrial DNA, the team successfully rewrote damaged sections to overcome deadly mutations in mice.”
Miniaturized CRISPR Packs a Mighty Gene Editing PunchShelly Fan
“CRISPR has a hefty problem: The system is too large, making it difficult to deliver the gene editor to cells in muscle, brain, heart, and other tissues. Now, a team at Mammoth Biosciences has a potential solution. …Their new iteration, dubbed NanoCas, slashed the size of one key component, Cas9, to roughly one-third of the original. …The compact NanoCas ‘opens the door’ for editing tissues inside the body.”
CAR T Therapy Wipes Out Deadly Metastasized Cancer in MiceShelly Fan
“The new study aimed to treat solid tumors like blood cancer—with a single injection into a patient’s vein. The team engineered CAR T cells that could hunt down metastasized cancer cells. When infused into the veins of mice they found the engineered cells rapidly shrank tumors in the liver and large intestines without causing dangerous immune side effects. The results ‘pave the way for a…clinical trial,’ wrote the team.”
Record-Breaking Qubits Are Stable for 15 Times Longer Than Google and IBM’s DesignEdd Gent
“[Transmons, the type of qubit favored by the likes of Google and IBM,] have advantages such as faster operation speeds, but their short shelf life [known as coherence] remains a major disadvantage. Now a team from Princeton has designed novel transmon qubits with coherence times of up to 1.6 milliseconds—15 times longer than those used in industry and three times longer than the best lab experiment.”
The post These Were SingularityHub’s Top 10 Stories in 2025 appeared first on SingularityHub.
2025-12-26 23:00:00
From Blue Origin to Airbus, private space stations are on the way, with the first scheduled to launch next year.
Commercial space stations are rapidly moving from concept to reality. As NASA prepares for the International Space Station’s retirement around 2030, a burgeoning private orbital industry could step into its shoes.
The ISS was humanity’s only permanent outpost in space for nearly a quarter of a century, until China’s Tiangong station was permanently crewed in 2022. But the ISS is nearing the end of its planned lifespan and NASA’s been clear that it doesn’t intend to replace the space station.
Instead, the agency wants to shift from landlord to tenant, purchasing space station services from private players rather than running a facility of its own. It’s betting the private space industry can help drive down costs and accelerate innovation.
This transition would mark a fundamental shift in the economics of low Earth orbit. And the first major milestone could come as soon as May 2026, when California-based startup Vast plans to launch its Haven-1 space station.
“If we stick to our plan, we will be the first standalone commercial LEO platform ever in space with Haven-1, and that’s an amazing inflection point for human spaceflight,” Drew Feustel, Vast’s lead astronaut and a former NASA crew member, recently told Space.com.
The company has already booked its launch on a SpaceX Falcon 9, and at around 31,000 pounds, Haven-1 will be the largest payload the rocket has ever carried. But as far as space stations go, it’s fairly modest.
Roughly the size of a shipping container, the single-module station will host crews of four for up to 10 days. But the company has tried its best to make the facility more comfortable than the utilitarian ISS, with “earth tones,” soft surfaces, inflatable sleep systems, and a revamped menu for astronauts.
Though the company hopes the design will tempt some customers, the station is really a proof of concept for Haven-2, a larger modular station that Vast hopes could succeed the ISS. Haven-2 will feature a second docking port to connect with cargo supply craft or new modules.
Development of Vast’s second station relies on funding from NASA’s Commercial Low Earth Orbit Destinations program, however, the company says. Eager to spur a new orbital economy that can support its missions, the agency started the program in 2021 to fund and assist a host of startups building space stations.
The agency has paid out about $415 million in the program’s first phase to help companies flesh out their designs. But next year, NASA plans to select one or more companies for Phase 2 contracts worth between $1 billion and $1.5 billion and set to run from 2026 to 2031.
Axiom Space, one of the companies vying for this funding, plans to piggyback on the ISS to build its space station. The company will first launch a power and heating module and connect it to the ISS. The module will be able to operate independently starting in 2028. They’ll then gradually add habitat and research modules alongside airlocks to create a full-fledged private space station.
Meanwhile, Voyager Space and Airbus are designing a space station called Starlab, which recently moved into “full-scale development” ahead of an expected 2028 launch. The station can host four astronauts, features an external robotic arm, and is designed to launch in one go aboard SpaceX’s forthcoming Starship rocket.
In addition, Blue Origin, founded by Jeff Bezos, is working with Sierra Space and Boeing to build Orbital Reef, which they describe as a “mixed-use business park 250 miles above Earth.” The project recently put its designs to the test by asking people to carry out various day-to-day tasks, like cargo transfer, trash transfer, and stowage in life-size mockups of the habitat modules.
All these projects hope to have NASA as an anchor tenant. But they are also heavily reliant on the idea that there are a broad range of potential customers also willing to pay for orbital office space. With the cost of space launches continuing to fall, there’s hope that there will be ample demand from space tourists, researchers, and manufacturers eager to take advantage of the unique microgravity environments these stations can provide.
The economics are far from certain though, and competition will be fierce. Even if NASA is able to spur a private orbital economy, there may not be enough business to support multiple private space stations.
But with the sun setting on the ISS, a gap in the market is undoubtedly opening up. If things go to plan, we may soon find that humans have a lot more orbital destinations on the menu.
The post The Era of Private Space Stations Launches in 2026 appeared first on SingularityHub.
2025-12-25 23:00:00
Among pressing ethical concerns are whether brain organoids could one day feel pain or become conscious—and how would we know?
When brain organoids were introduced roughly a decade ago, they were a scientific curiosity. The pea-sized blobs of brain tissue grown from stem cells mimicked parts of the human brain, giving researchers a 3D model to study, instead of the usual flat layer of neurons in a dish.
Scientists immediately realized they were special. Mini brains developed nearly the whole range of human brain cells, including neurons that sparked with electrical activity, making them an excellent way to observe and study the human brain—without the brain itself.
As the technology advanced and brain organoids matured, researchers coaxed them to grow structural layers with blood vessels roughly mimicking the cortex, the part of the brain that handles reasoning, working memory, and other high-level cognitive tasks. Parallel efforts derived organoids for other parts of the brain.
Mini brains can be made from a person’s skin cells and faithfully carry the genetic mutations that could cause neurodevelopmental disorders, such as autism. The lab-grown blobs also provide a nearly infinite source of transplantable neural tissue, which in theory could help heal the brain after a stroke or other traumatic events. In early studies, organoids transplanted into rodent brains formed neural connections with resident brain cells.
More recently, assembloids have combined mini brains with other tissues, like muscles or blood vessels. These Frankenstein-ish assemblies capture how the brain controls bodily functions—and when those connections go awry.
As brain organoids have grown increasingly complex, ethical concerns about their use have grown too. After all, they’re made of neural tissue, which in our heads forms the basis of memory, emotions, sensations, and consciousness.
To be clear, there’s no evidence brain organoids can think or feel. They are absolutely not brains in a jar. But scientists can’t ignore the possibility they could eventually develop some sort of “sensation,” such as pain and, if they do, what that might mean for their development.
Harvard’s Paula Arlotta is among those who are concerned. An expert in the field, her team has developed ways to keep brain organoids alive for an astonishing seven years. Each nugget, smaller than a pea, is jam-packed with up to two million neurons and other human brain cells.
Studying these mini brains for years has delivered an unprecedented look into human brain development. Our brains take nearly two decades to mature, an exceptionally long period of time compared to other animals. As the team’s organoids aged, they slowly changed their wiring and gene expression, reports Arlotta and colleagues in a recent preprint.
In older organoids, progenitor cells—these are young cells that can form different types of brain cells—quickly decided what type of brain cell they would become. But in younger organoids, the same cells took time to make their decision. As the blobs grew over an astonishing five years, their neurons matured in shape, function, and connections, similar to those of a kindergartner.
These long-lasting organoids could reveal secrets of the developing brain. Some efforts are tracing the origins of different cell types and how they populate the brain. Others are generating organoids from people with autism or deadly inherited brain disorders to test treatments.
Excitement is at an all-time high. But while championing the research, Arlotta and other experts recently penned an article arguing for a global regulation committee to steer the nascent field.
While scientists always keep ethics in the mind, they’re also motivated by scientific discovery and the search for new treatments. Plenty of promising research has also raised ethical concerns regarding sourcing or consent. Take the notorious CRISPR baby scandal in 2018. A Chinese scientist unlawfully and permanently altered a gene in embryos, and the children subsequently born with those DNA edits didn’t have a say in the matter.
Brain organoids present a different challenge. As they become more sophisticated and capture the brain’s cellular and structural makeup, could they begin to feel pain? Used in biocomputers, could they show signs of intelligence? Is it ethical to implant human mini brains into animals, where experiments show they integrate with host brains and blur the lines between man and beast? What about implanting lab-grown brain tissue into humans?
This November, experts (including Arlotta), ethicists, and patient advocates gathered at a conference co-organized by Stanford law professor Henry Greely, who specializes in bioethics. The meeting wasn’t designed to generate comprehensive guidelines regarding brain organoids. But ethics was a throughline during the entire conference as researchers presented recent successes in the field and pitched where it could go next.
In particular, Stanford’s Sergiu Pasca, a co-organizer of the meeting, attracted attention. Earlier this year, his team linked four organoids into a neural “pain pathway.” The model combined sensory neurons, spinal and cortex organoids, and parts of the brain that process pain.
The scientists dabbed the chemical behind chili’s tongue-scorching heat onto the sensory side of the assembloid. It produced waves of synchronized neural activity, suggesting the artificial tissue had detected the stimuli and transferred information.
That’s not to say it felt pain. Detecting pain is only part of the story. It takes a second neural pathway, which the assembloids lacked, to trigger the unpleasant feeling. But the experiment and others underscore the need for regulation. One idea pitched at the conference is to create a new global organization similar to the International Society for Stem Cell Research.
The commission would track advances in the field and provide oversight that balances scientific merit with patient needs. During the meeting, patients and family members expressed hope that mini brains could lead to new therapies, especially for those with rare genetic disorders or severe autism.
Pasca may soon deliver on that promise. His team is working to understand Timothy syndrome, a rare genetic disorder that leads to autism, epilepsy, and often fatal heart attacks. Last year they developed a gene-altering molecule that showed promise in brain organoids mimicking the disease. The treatment also worked in a rodent model, and the team is planning to submit a proposal for a clinical trial next year.
Drawing the line for brain organoid research will require global cooperation. “A continuing international process is needed to monitor and advise this rapidly progressing field,” wrote Arlotta, Pasca, and others. While there aren’t any universal agreements yet, dialogue on ethics, including discussion and engagement with the public, should guide the nascent field.
The post Five-Year-Old Mini Brains Can Now Mimic a Kindergartener’s Neural Wiring. It’s Time to Talk Ethics. appeared first on SingularityHub.
2025-12-23 23:00:00
The treatment reprograms T cells to hunt down a patient’s cancer. The approach could speed treatment and cut costs, but needs more study.
With just a single injection, a new treatment transforms immune cells in cancer patients into efficient tumor-killing machines. Now equipped with homing beacons, the cells rapidly track down and destroy their cancerous foes.
The shot is based on CAR T cell therapy, a breakthrough that uses genetic engineering to supercharge cancer-fighting T cells. Since its first FDA approval in 2017, CAR T has vanquished some deadly cancer cases with a one-and-done treatment.
But the technology is costly—for both body and wallet. CAR T cells are usually made outside the body in a lab. Patients undergo chemotherapy and other harsh treatments to make room for the enhanced immune cells, taxing an already ailing body with side effects. Making CAR T cells also takes precious time, and unfortunately, the clock often runs out.
At this year’s American Society of Hematology Annual Meeting & Exposition, an Australian team presented a different approach: Transforming normal T cells into super soldiers inside the body. Four people treated for stubborn multiple myeloma—a blood cancer that destroys bones and kidneys—went into remission for up to five months.
Led by Phoebe Joy Ho at the University of Sydney in collaboration with Kelonia Therapeutics, the trial, although small and still preliminary, marks a step towards the next revolution in CAR T therapy. Reported in The American Journal of Managed Care, an audience member from the conference said the findings “take your breath away.”
CAR T therapy has transformed cancer care. Six formulations are approved in the United States for a variety of blood cancers. Hundreds of clinical trials that expand the life-saving technology to solid cancers—including breast and brain tumors—are underway.
Beyond cancer, the therapy is also being used to treat life-long autoimmune diseases, such as lupus and multiple sclerosis, where the body’s immune system destroys its own organs. A small trial found a single infusion of CAR T cells reduced symptoms in patients with lupus. Other efforts are using these custom living drugs to tamp down infections, restore heart health after an attack, and remove the “zombie cells” that accumulate during aging.
The procedure usually goes like this: A patient’s own T cells are extracted from their blood. Using gene editing tools, like CRISPR, the cells are supplied with extra protein “hooks.” These hooks let them better grab onto their targets—cancer cells or otherwise.
After a short course of chemotherapy or radiation to deplete existing immune cells and make room for new ones, the engineered CAR T cells are infused back into the body. Once there, the genetically engineered cells repopulate the immune system and hunt down their prey. The process, while undeniably efficient for some cancers, is costly and takes months—time that some patients don’t have.
“Off-the-shelf” CAR T is one solution. Instead of editing a patient’s own cells, scientists could transform a healthy population of donor T cells. But attempts have faced immune rejection. Even with more genetic tinkering, the cells struggle to survive and expand in the body.
An alternative method directly converts a person’s T cells inside their own body.
In 2022, a team designed a shot to reprogram T cells using RNA. This avoids tinkering with a patient’s DNA. In mice with heart scarring, the injection revived the organ.
Other successes soon followed. Another shot converted T cells into CAR T cells within hours in mice and monkeys. The therapy targeted a type of blood cancer deriving from an overgrowth of B cells (another immune cell type). The shot boosted the immune system’s ability to destroy cancers in mice and slashed B cell numbers in monkeys. The effects lasted at least a month.
Both these treatments used fatty nanoparticles to deliver their payloads. They were also heavily modified to get around the so-called liver “sink.” Treatments often end up in the organ after injection. Careful design of surface proteins helped the therapies home in on T cells.
Gene-editors can also hitch a ride on a benevolent virus, stripped of disease-causing genes but highly efficient at tunneling into cells. Kelonia’s new technology used a virus to target T cells and avoid other cell types. One tweak, for example, added a small, engineered protein fragment that precisely targets T cells. Once inside, the payload synthesizes a gene that kills cancers.
The trick paid off. In a small trial, researchers gave the shot to four patients with previously uncontrollable multiple myeloma. The patients showed no signs of cancer in their bone marrow after a month. For one, the effect lasted at least five months. The side effects were also relatively minor, although some experienced mild cytokine release syndrome—an immune reaction that causes fever, chills, and other symptoms, which were easily managed.
The results come on the heels of a separate trial with similarly positive results. In July, four patients with multiple myeloma received an infusion of a virus carrying genes targeting T cells. Crafted by EsoBiotec in Belgium and Shenzhen Pregene Biopharma in China, the shot vanquished abnormal cells in the bone marrow of two patients after three months. The patients had previously undergone multiple cancer-related therapies to no avail.
The treatment did come with side effects. Blood pressure plunged, and two patients required supplemental oxygen. One showed confusion and temporary “brain fog.” These mental troubles aren’t common with traditional CAR T therapy, motivating researchers to find out why.
Despite risks, results from both trials highlight the promise of one-and-done CAR T therapy for deadly blood cancers. But it’s still early days. Scientists need to carefully follow patients over years to understand how long upgraded T cells remain in the body and their effect on cancers.
And not all viral carriers are made the same. Lentiviruses, used in both studies, can tunnel into the human genome, causing DNA typos that potentially trigger secondary cancers. The durability of the therapy, its longevity, and immune side effects also need to be studied.
Kelonia is adding more patients to their trial, amid an increasingly competitive landscape. AstraZeneca has acquired EsoBiotec to bring its technology to market. AbbVie, a drug company in Illinois, is testing the delivery of gene-editing tools to T cells via fatty nanoparticles in clinical trials. And Kelonia is planning a second clinical trial with an initial 20 patients and 20 more in an expansion phase, none of whom responded to at least three previous treatments.
“I think it gives us a glimpse into the future,” Ho told Science. “In vivo CAR T for multiple myeloma is here and hopefully it will stay.”
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