Many consider enzymes the workhorses of biochemistry (move over, mitochondria)—catalyzing reactions, breaking down substrates, keeping the machinery of life humming along. But a growing number of researchers are re-envisioning what enzymes can do. Instead of facilitating chemistry, what if enzymes could steer and even guide tiny robots to a tumor?
That’s exactly what’s happening in the rapidly expanding field of enzyme-powered microscopic robots (a.k.a “microrobots”). Microrobots are tiny, engineered devices—often smaller than the width of a human hair—built to perform tasks inside the body that would be difficult or impossible at a larger scale, like delivering drugs to a specific tissue. A recent paper published in Nature Nanotechnology by a team of researchers at California Institute of Technology and the University of Southern California offers a particularly elegant example that we highlight below1.
mRNA-based therapeutics are being explored across a range of applications, including vaccines, protein replacement and immunotherapies (2).
Before any formulation decisions enter the picture, teams need confidence in the RNA itself: that it is the right sequence, right properties and the right purity to behave predictably downstream. That is where it helps to separate drug substance from drug product. The drug substance is the active ingredient intended to deliver a pharmacological effect, while drug product is the finished dosage form that contains that ingredient (6).
This post focuses on what happens upstream, making the mRNA drug substance before formulation. In practical terms, that upstream work spans choosing an mRNA construct, producing it by IVT, and then purifying and analyzing the product so it has the desired quality attributes (5).
When people talk about places where science and technology tend to flourish, a few names surface almost immediately. Silicon Valley, Boston, Seattle, Houston. Cities associated with density, competition and speed.
For many people outside the state, Wisconsin still collapses into a short list of associations: beer, cheese, cold winters, maybe a football team. Biotechnology rarely makes that list.
That hesitation usually has less to do with science itself and more to do with assumptions about where innovation is supposed to live. National Wisconsin Day, celebrated February 15, is a good moment to look past those assumptions and consider what Wisconsin has quietly offered for a long time: an environment and culture that is well-suited for scientific advances.
You’re sitting in the dentist’s chair, nodding along to the familiar flossing lecture you’ve been politely ignoring for most of your adult life. Fair enough. It’s hard to get excited about gum health. But it turns out your dentist may have been underselling the pitch.
A study published in January 2026 in Cell Communication and Signaling shows that a common gum disease bacterium can promote breast cancer growth and spread in mice, and the findings hint at a particularly troubling link for people carrying BRCA1 mutations (1). “Floss to help prevent cancer” probably wasn’t on your 2026 bingo card, yet here we are.
When you think about climate change in the Arctic, you might imagine melting sea ice or maybe hungry polar bears. After all, polar bears depend on sea ice to hunt seals, and seals are their main source of energy. The negative effects of decreasing sea ice on polar bear body condition index (BCI), survival and reproduction have been documented in polar bear populations from regions such as the Western Hudson Bay and the Southern Beaufort Sea. So, when researchers started studying the polar bears in Svalbard, Norway (Barents Sea region), which is losing sea ice at a faster rate than any other region, they expected the BCI of those bears would also be declining. Except it isn’t.
Whether it’s Home Alone’s booby-trapped icy steps, Bambi learning his legs have zero traction, or an Ice Age chase scene defying gravity, ice has been comedy gold for decades. In real life, the joke lands a little harder (sometimes literally).
We all know ice is slippery. The more surprising part is why it’s slippery and how long it took scientists to start agreeing on something closer to an answer. Researchers have long known the surface of ice behaves like it’s wearing a microscopic “wet” layer that lubricates motion. What they’ve argued about for nearly 200 years is what creates that layer in the first place (3,4).
So, let’s treat this like a mystery. Ice is the crime scene. Your dignity is the victim. Here are the main suspects.
If you’ve ever played The New York Times game Connections, you know the feeling. You’re staring at a grid of words, knowing the solution is there, but unable to see how the pieces fit together. All you can do is work with the words in front of you. There are no extra clues, no new information coming. The only option is to shuffle, to look at the same information in a different arrangement until patterns begin to appear.
Nothing about the problem changes. Then something about how you see it does.
In 2014, a third-year medical student named David Fajgenbaum checked himself into the emergency room mid-exam. He felt off. By the time anyone understood why, he was in the ICU with multiple organ failure from a disease so rare it wasn’t taught in medical school: Castleman disease. The only approved drug didn’t work. A priest came to his bedside and read him his last rites. He was 25.
Fajgenbaum survived that relapse, and four more after it. As he recounted in a recent episode of NPR’s Radiolab, he understood that chemotherapy was keeping him alive without curing him, and that waiting for a new drug to be developed (a process that typically takes 10 to 15 years and billions of dollars) wasn’t an option he had. So he did something unusual. He started asking his doctors to save his blood samples, and he ran experiments on himself.
What he found was that a specific signaling pathway in his immune system, mTOR, was in overdrive. When he searched the existing pharmacological literature for something that could block it, he found an answer that had been sitting in pharmacies for 25 years. Sirolimus, a drug approved in 1999 to prevent organ transplant rejection, had never been used for Castleman disease. The biology of his disease hadn’t changed. The drug had always existed. The connection simply hadn’t been made.
He took it. It worked. He has been in remission for over a decade.
The detail worth holding onto isn’t the drug or the disease. It’s the instinct. Fajgenbaum didn’t wait for new knowledge to arrive. He looked differently at what already existed.
Adoptive T-cell therapies rely on generating metabolically fit, functional cells during ex vivo expansion—but this process often pushes T cells toward highly glycolytic, terminally differentiated states that limit their persistence and therapeutic potential. These metabolic programs begin shifting within hours of activation, therefore understanding early metabolic remodeling is essential for designing culture conditions that support durable, cytotoxic, and memory-enriched T-cell populations.
Researchers at Promega set out to address this challenge by systematically mapping how media composition and activation strength shape T-cell metabolism during the first 72 hours after stimulation. Using a suite of bioluminescent assays, they profiled intracellular energy cofactors, redox balance, and extracellular metabolites across several conditions. This approach revealed distinct, media-driven metabolic states that not only emerged early but also predicted downstream expansion, proliferation, and cytotoxic function.
Their work demonstrates how integrating metabolic profiling into in vitro expansion workflows can provide a more informed framework for optimizing T-cell manufacturing strategies.
What if a vaccine didn’t come in a vial or a syringe, but in a pint glass?
It’s the kind of question that sounds hypothetical–something meant to provoke discussion rather than describe a real experiment. And yet, it’s one that a virologist claims to have taken seriously enough to test in his own kitchen.
Since publicly sharing his experiment and preliminary results, the idea of “vaccine beer” has drawn fascination, skepticism and no small amount of discomfort from across the scientific community.
As science advances, its most meaningful moments often come not in a single breakthrough, but in the accumulation of insights that reshape how we understand our world. As we close the door on 2025 it is worth pausing to reflect on some of the discoveries of the past year that stood out—not just for their technical achievement, but for what they reveal about our planet, our past and ourselves. From dismantling so-called “forever chemicals” to reading molecular histories written millions of years ago, these five stories offer a snapshot of the breadth, creativity and impact of modern scientific inquiry.
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