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Scientists Turned Human Cells into Tiny Biological Computers

The researchers also built in a warning signal. When the cell received a confusing instruction—the biological equivalent of two commands arriving at once—it produced a separate alert instead of continuing as if nothing had happened.

To show how the system might one day be used in medicine, the team programmed cells to secrete IL-15, an immune protein that can help activate cancer-fighting immune cells.

The experiments relied on engineered circuits delivered into cells under controlled lab conditions. The authors note several challenges ahead, including avoiding unwanted RNA interactions, limiting leaky genetic switches, and finding reliable ways to insert larger circuits into cell genomes.

Ultrasound-based approach may reduce harmful inflammation and support joint healing

As an aging population experiences joint pain and inflammation at an all-time high, researchers at The University of Alabama in Huntsville (UAH), a part of The University of Alabama System, have published new findings suggesting continuous low-intensity ultrasound may help shift the body’s immune response from prolonged inflammation toward tissue repair, a discovery that could eventually contribute to novel treatments for joint injuries and post-traumatic osteoarthritis.

The study, published in Scientific Reports, was conducted by a multidisciplinary team of UAH researchers under the leadership of Dr. Anuradha Subramanian, a professor of chemical and materials engineering.

The work brought together biological experimentation conducted by Dr. Shahid Khan as part of his doctoral work with computational and statistical methods developed by Dr. Satyaki Roy, a professor of mathematical sciences, along with additional contributions from graduate student Owen Trippany.

Single ion maps 3D electromagnetic fields above chips with record sensitivity

Researchers at ETH Zurich have developed a method that uses a single ion to detect electromagnetic fields above a surface and to create a three-dimensional map of them. In the future, this approach can be used to improve chips for quantum computers and quantum sensors.

Single electrically charged atoms—ions—have been successfully used for some time as quantum bits in quantum computers and quantum sensors. Unlike the bulky ion traps of the early years, there are now miniaturized chips in which ions can be trapped and manipulated only a hair’s breadth above the surface of the chip. This has many advantages, but also one decisive drawback: Noisy electromagnetic fields coming from the chip itself can severely impair the sensitive quantum states of the ions and hence the performance of the computer or sensor.

A team of researchers led by Jonathan Home, a professor at the Institute for Quantum Electronics at ETH Zurich, has now developed a technique that allows them to create a very precise three-dimensional map of electric and magnetic fields very close to the surface of the chip. In the future, materials for chip production can be better optimized and tested for their suitability for use in quantum applications. The results of their research were recently published in Science Advances.

Cell-type resolved transcriptional network analysis of in vivo cellular senescence following injury

Senescence is a key manifestation of aging at the cellular level, caused by damage incurred by cells in time. In spite of their wide-ranging implications on how our multicellular bodies age, senescent cells are very challenging to identify due to their complex nature: many different aspects of cells are affected by this cellular state. This complicates defining clear criteria that help us decide whether a cell is senescent or not. In this paper, we propose a computational pipeline that enables us to identify a small subset of genes associated with senescence. The method combines two approaches commonly used in the study of networks, community detection and node centrality, and applies them to gene expression data obtained from the muscle tissue of mice after damage. The results obtained can contribute to establish the molecular correlates of a complex cellular state such as senescence.

Citation: Sabalic A, Moiseeva V, Cisneros A, Deryagin O, Perdiguero E, Muñoz-Cánoves P, et al. (2026) Cell-type resolved transcriptional network analysis of in vivo cellular senescence following injury. PLoS Comput Biol 22: e1014429. https://doi.org/10.1371/journal.pcbi.

Editor: Christoph Kaleta, Christian Albrechts Universitat zu Kiel, GERMANY.

Tiny magnetic waves could unlock quantum computers the size of a penny

A team of physicists has overcome a major obstacle in quantum computing by dramatically increasing the lifetime of magnons, tiny magnetic waves that can carry quantum information. The researchers extended their lifespan from just a few hundred nanoseconds to as long as 18 microseconds, nearly 100 times longer than previously achieved. The advance could eventually help make ultra-compact quantum computers, potentially as small as a 1-cent coin.

The international research team, led by Andrii Chumak of the University of Vienna, also uncovered an important insight. They found that the lifespan of magnons is not ultimately limited by the laws of physics, but by the quality of the material they travel through. Their findings were published in Science Advances.

Strange Things Are Happening in Quantum Computing

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Quantum computing is supposed to be one of the most exciting new technologies that humanity is working on, with companies promising it can be used in chemistry, material science, logistics, and finance. Over the years, those use cases have been slowly eroded, but investment in quantum tech has only increased. Why? Let’s take a look.

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Microsoft Accelerates Post-Quantum Cryptography Shift to 2029

“Advances in quantum research and development have shifted the risk horizon,” Mark Russinovich, chief technology officer of Microsoft Azure, said. “We believe cryptographically relevant quantum computers could arrive sooner than previously expected – and the work required to prepare is significant, so organizations need to start now.”

To that end, the Windows maker is speeding up the Microsoft Quantum Safe Program (QSP) timeline with the goal of transitioning critical products and services to post-quantum cryptography (PQC) by 2029. The company is also planning to incorporate PQC requirements into its Secure Future Initiative (SFI).

Some key focus areas include upgrading network cryptography by adopting TLS 1.3, building crypto-agility for stored data to facilitate the ability to change cryptography without having to redesign the underlying systems, and transitioning to PQC algorithms to secure trust chains, such as code signing, certificate issuance, key protection, and update pipelines.

Adobe Patches 7 CVSS 10.0 Flaws in ColdFusion and Campaign Classic

The issues have been addressed in ColdFusion 2023 Update 21 and ColdFusion 2025 Update 10. Security researchers Anirudh Anand, Matan Sandori, and 2Bsecure have been credited with discovering and reporting CVE-2026–48283, CVE-2026–48313, and CVE-2026–48307.

Separately, Adobe has also shipped fixes to close out a critical flaw in Adobe Campaign Classic impacting versions ACC v7: 7.4.3 build 9,396 and earlier for Windows and Linux that could result in arbitrary code execution.

The vulnerability, tracked as CVE-2026–48286 (CVSS score: 10.0), is a case of incorrect authorization that could enable an attacker to execute arbitrary code on affected systems. It has been patched in version ACC v7: 7.4.3 build 9397.

The secret code behind the universe | Stephen Wolfram

Simple rules. Infinite complexity. Physicist Stephen Wolfram has spent forty years working out the connection. Here’s the short version.

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Physicist Stephen Wolfram spent decades running computer experiments on simple rules — not looking for anything grand, just seeing what happened. What he found turned into a model of how the universe works, an explanation for why evolution never gets stuck, and a mathematical argument for why your life can’t be shortcut or predicted by anyone.

Read the full video transcript: https://bigthink.com/videos/the-unive

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Do we inhabit a multiverse? Do we have free will? What is love? Is evolution directional? There are no simple answers to life’s biggest questions, and that’s why they’re the questions occupying the world’s brightest minds.

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