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 \.
Category: bioengineering
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.
Nanozymes map nanoparticle routes inside live cells without genetic engineering
Nanoparticles are widely used in medicine to deliver drugs, genes or imaging agents to specific parts of the body. Once a nanoparticle reaches a cell, however, many things can happen—it can reach its target, be degraded, interact with proteins that help transport it, or interact with proteins that hinder its transport.
A longstanding problem in designing nanomedicines has been understanding what happens to nanoparticles at the cellular level, but scientists have faced many challenges. For example, optical microscopy imaging techniques provide only a generalized view of nanomedicine localization.
On the other hand, proteomics approaches require cell lysis, which disrupts the natural distribution of proteins around the nanoparticle, making it difficult to understand how nanoparticles are transported within the cell. Another method—proximity labeling—enables in situ investigation of intracellular protein-protein interactions, but it relies on genetically engineered enzyme fusion, which limits its applicability across diverse systems.
Brain dynamics of the « wave of death » highlighted for the first time
In 2023, scientists at the Paris Brain Institute investigated one of the most fascinating and unsettling transitions in neuroscience: what happens to the cortex when the brain is deprived of oxygen.
In a rat model of systemic anoxia, researchers found that the dying brain does not simply “shut off” all at once. Instead, cortical activity follows a structured sequence: brief high-frequency activity, slowing oscillations, electrical silence, and then a massive wave of anoxic depolarization — often called the “wave of death.”
This wave appeared to begin deep in the neocortex, especially around layer 5 pyramidal neurons, before spreading upward toward the cortical surface and downward toward the white matter. These neurons are large, metabolically demanding projection cells, which may make them especially vulnerable when oxygen and ATP collapse.
But the most important part of the study is that this wave did not always represent an absolute point of no return. When oxygenation was restored within a critical window, researchers observed a “wave of resuscitation,” followed by partial recovery of synaptic activity.
That does not mean death has been “reversed” in a simple or sensational sense. But it does suggest something scientifically powerful: the boundary between life and death in the brain may be more dynamic, layered, and measurable than we often imagine.
This is where the implications become fascinating.
If the “wave of death” is an organized biophysical event, future neurocritical care may one day be able to detect the brain’s approach toward irreversible injury in real time. Instead of relying only on broad markers like heartbeat, oxygen saturation, or flat EEG, clinicians may eventually use more detailed brain-state monitoring to identify whether the cortex is entering a reversible, borderline, or irreversible phase.
Lipids and DNA nanostructures independently control artificial cell mechanics
What if the mechanical properties of a cell could be programmed like the components of a machine? Researchers at the University of Tokyo have discovered that two fundamental modes of cellular deformation—stretching and bending—can be independently controlled using different molecular building blocks. The finding provides a new strategy for engineering artificial cells, drug-delivery capsules and adaptive soft materials with precisely tailored mechanical functions.
Miho Yanagisawa, an associate professor at the University of Tokyo, and Kazutoshi Masuda, a Ph.D. student, developed a new framework for dissecting the mechanics of artificial cells. Using lipid-coated microdroplets as simplified cell models, they combined micropipette aspiration experiments with a theoretical model that separates membrane mechanics into stretching and bending contributions. The approach successfully captured nonlinear deformation behaviors that conventional models could not explain. The work is published in the journal Small Science.
The researchers found that lipid molecular geometry primarily determines membrane stretching elasticity. In contrast, when Y-shaped DNA motifs were interconnected to form a three-dimensional network, they created a nanoscale scaffold that dramatically enhanced resistance to bending while leaving stretching elasticity largely unchanged.
Intelligence Without Brains: A Radical New Idea
What if intelligence doesn’t require a brain? Biologist Michael Levin argues that intelligence is not confined to neurons, but exists on a continuum of goal-directed behavior and problem-solving across a wide range of species and systems. Using a framework he calls the “cognitive light cone,” Levin explores diverse forms of intelligence extending all the way down to the cellular level. His research suggests that cells communicate through electrical networks, enabling them to make collective decisions and adapt to unexpected challenges, evidenced by engineered tadpoles capable of seeing through eyes located on their tails. Levin radically challenges the conventional wisdom even further, proposing that forms of intelligence may extend beyond biology to molecular systems and maybe even the weather.
00:00 What is intelligence?
01:03 The field of diverse intelligence.
01:33 Intelligence at the cellular level.
02:08 The cognitive light cone.
03:01 The intelligence of groups of cells.
03:52 The bioelectric language of cells.
04:20 The mind of the body.
04:23 Cells that solve problems.
05:17 The tadpole experiment.
06:25 The cognitive spectrum.
06:48 Can you train a hurricane?
07:03 A new science of intelligence.
07:28 Beyond human biases.
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Quantum-inspired AI could tailor patients’ cancer treatment to their entire molecular background
For a child diagnosed with neuroblastoma—the most common infant cancer, occurring when early nerve cells grow out of control—the path to treatment isn’t simple. Some types of neuroblastoma resolve on their own, while others require aggressive intervention. Researchers have tried matching treatments to patients based on one-gene mutations with limited success. This is because patients’ outcomes depend on their entire molecular background, containing millions or even billions of features, such as DNA and RNA from tissues and blood.
“It’s much more than just one gene—everything that’s happening in the cells of the patient matters,” said Orly Alter, an associate professor of biomedical engineering at the University of Utah’s Scientific Computing & Imaging Institute.
Current artificial intelligence and machine learning (AI/ML) approaches require massive amounts of training data and, specifically, vastly more patient samples than genetic features.
High-resolution mapping of CCR4-NOT recruitment elements reveals transcriptome-wide drivers of mRNA decay
Luo et al. present TRACER, a transcriptome-wide approach to identify RNA elements that recruit the CCR4-NOT complex. TRACER uncovers thousands of CCR4-NOT-associated elements, many mapping to known or predicted RBP and miRNA target sites. These elements drive mRNA repression and can be targeted using gene editing or ASO approaches.
Transhumanism: Should We Become More Than Human?
In the future, humanity may embrace genetic engineering and cybernetic augmentation of mind and body, but what does this Transhuman future look like? And should we embrace or resist these paths?
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/ discord Credits: Transhumanism & Humanity’s Future Science & Futurism with Isaac Arthur Episode 375, December 29, 2022 Written, Produced & Narrated by Isaac Arthur Editors: Briana Brownell Donagh Broderick Keith Blockus Lukas Konecny Graphics: Jeremy Jozwik Ken York of YD Visual Music Courtesy of Epidemic Sound http://epidemicsound.com/creator.
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Credits:
Transhumanism \& Humanity’s Future.
Science \& Futurism with Isaac Arthur.
Episode 375, December 29, 2022
Written, Produced \& Narrated by Isaac Arthur.
Editors:
Briana Brownell.
Donagh Broderick.
Keith Blockus.
Lukas Konecny.
Graphics:
Jeremy Jozwik.
Ken York of YD Visual.
Music Courtesy of Epidemic Sound http://epidemicsound.com/creator