General

Before the First Dose

Posted on by Elise Johnson

Kierkegaard observed that one of humanity’s enduring tensions is that while life can only be understood backwards, it must be lived forwards. It’s a truth medicine knows intimately: in the treatment that worked until it didn’t, the resistance that arrived without warning, the moment a doctor has to tell a patient that the drug that was helping has stopped. Not because anyone made a mistake, but because the critical knowledge that would have mattered arrived too late, if at all.

A recent paper from the National Cancer Institute is, in a small but meaningful way, science’s pursuit of that elusive foresight: an understanding that emerges early enough, for once, to change what happens next.

The Elegant Idea

For decades, chemotherapy has worked by brute force, flooding the body with toxins designed to kill rapidly dividing cells. The problem is that rapid division isn’t unique to cancer. Hair follicle cells, gut lining cells and immune cells also divide rapidly, which is why patients lose hair, lose energy and become susceptible to infection. Chemotherapy targets a behavior, but the drug has no way to tell a healthy cell from a cancerous one.

Antibody-drug conjugates (ADCs) change that. Instead of targeting what cancer cells do, they target what cancer cells are. Cancer cells tend to display certain proteins on their surface in far greater numbers than healthy cells do. The antibody is engineered to seek out those proteins specifically. It navigates to its target, binds and waits for the cell to do what cells routinely do: pull it inside. Once there, the cell’s own digestive machinery (the lysosome) breaks down the chemical tether holding the toxin to the antibody, releasing the toxin to kill the cell from within. More than a dozen ADCs have received FDA approval in recent years, and the field is evolving fast.

What the Cell Does Next

But cancer cells don’t simply accept their fate. Even when an ADC delivers its payload perfectly—the antibody finds its target, the cell pulls it inside, the lysosome cuts the tether—a pump embedded in the cell membrane can grab the released toxin and throw it back out before it causes damage.

The delivery worked. The package got ejected anyway.

These pumps—ATP-binding cassette transporters, or more plainly, efflux pumps—are a normal feature of cell biology. Their job is cellular housekeeping, clearing out unwanted or toxic substances before they cause damage. Under the pressure of drug treatment, cancer cells do what life has always done under pressure: the ones best equipped to survive do. The same mechanism that has shaped living things for billions of years now works against the treatment. Not all cancer cells are identical, and the ones that happen to produce more pumps survive while others don’t, gradually shifting the tumor toward resistance.

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More Than Beer and Cheese: Why Wisconsin Has Always Been Good Ground for Science 

Posted on by Elise Johnson

Challenging Assumptions About Innovation

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.

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The Breakthrough Was There All Along

Posted on by Elise Johnson

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.

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From Forever Chemicals to Ancient Proteins: Five Science Stories from 2025

Posted on by Kelly Grooms

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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From Young Researcher Award Finalist to International Collaborator: Two Visits to Promega

Posted on by Jordan Villanueva

In 2022, Luiza Abdo traveled from her home in Rio de Janeiro, Brazil, to the United States to visit the Promega campus in Madison, WI. A PhD student at the time, Luiza was one of ten finalists for the inaugural Young Researchers Award sponsored by Promega Brazil.

Luiza (center) visited Promega Madison in 2025 with Martin Bonamino (far left).

In 2025, Luiza was invited to Promega Madison once again, but this time she came as a customer and collaborator. Now a postdoctoral researcher at the Brazil National Cancer Institute, she was excited to return to Madison to discuss technologies that may help advance her project.

“Once I saw the Kornberg Center, I remembered everything from my last visit,” Luiza says. “It was one of the best travels I’ve ever had, and I made great friends.”

Luiza studies immunotherapy in the lab of Martin Bonamino, Head of Cell and Gene Therapy, at the National Cancer Institute. When she visited Promega in 2022, Luiza presented her project aimed at producing CAR-T cell therapies in under 24 hours. She and the other nine award finalists toured Promega facilities, networked with industry researchers, and went on adventures around the Madison area. They went to a baseball game, played sand volleyball against Promega employees and manipulated giant molecules in virtual reality.

“This was a different kind of visit. I’m here with my PI, and we learned several ways Promega technology can make our lives and research easier,” Luiza says in 2025. “The conversations are more specific to our field of work.”

Luiza (front row, left) visited Promega Madison in 2022 with 9 other Young Researchers Award finalists.

Today, she’s working on translating her CAR-T production methods into clinical applications. This visit introduced her to new technologies like cell fitness and metabolism assays that may help with this new phase. Promega researchers such as Julia Gilden joined to talk through challenges and solutions in cell therapy research.

“We’re making a new kind of product, which is very innovative, but we also have to prove a lot of different things to translate it to the clinic. We have many challenges, but we’ve found several ways Promega can help us solve our problems.”

Three years after her initial visit, Luiza says that visiting Promega has impacted not only her research, but also how she looks at her research field and potential career paths.

“My first visit was very good for me because I come from academic research, and we don’t have many interactions with industry. After touring Promega, I started to look at industry with new eyes. Even if I’m not working in an industry position, I see how there are people who can help with your needs, and work with you to solve problems.”

“I’m very happy to be here again,” she laughs. “I’m thankful to have this opportunity twice.”

Your Science in Review: Our Top Blogs of 2025

Posted on by Johanna Lee

As we look back on 2025, it’s clear that this year brought incredible innovation, practical solutions, and inspiring stories from labs around the world. From cutting-edge cellular imaging to behind-the-scenes looks at manufacturing, our readers showed us what matters most: tools that work, science that inspires, and stories that connect us to the bigger picture.

Here are the five most popular blogs from 2025:

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From Mt. Fuji to the Lab Bench: A UW-Madison Student’s Summer in Japan

Posted on by Promega

This blog is guest-written by Lucy Kneeley, a 2025 recipient of the Promega International Internship Scholarship. The scholarship is granted annually to University of Wisconsin-Madison students traveling abroad for internship opportunities.

Lucy Kneeley poses at the summit of Mt Fuji.

Last summer, I completed an internship at the Institute of Science Tokyo in the lab of Professor Satoshi Kaneko. As someone who has never been out of the United States for more than a 10-day vacation, I gained a lot of valuable communication experience by navigating a language barrier, but more importantly, across different social norms. Immersing myself in a new country with a new language and culture has led me to think differently and realize how quickly a group of strangers can become a new community. By the end of the three months, I had formed a network of colleagues and friends at the university and within the local community.

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Residence Time: The Impact of Binding Kinetics on Compound-Target Interactions

Posted on by Promega

This blog was written by guest contributor Tian Yang, Associate Product Manager, Promega, in collaboration with Kristin Huwiler, Manager, Small Molecule Drug Discovery, Promega.

During the development of chemical probes or small-molecule drugs, compound affinity (Kd) or potency (IC50) is used to characterize compound-target interactions, to guide structure-activity relationship analysis and lead optimization and to assess compound selectivity.

However, neither parameter provides information on how quickly a compound engages with and dissociates from the target. The dissociation constant Kd reflects the relative concentrations of unbound and bound state of the compound at thermodynamic equilibrium, and while IC50 is an empirical metric that measures the concentration at which a biochemical or cellular process is reduced to half of the maximum value, IC50 values are typically determined when the process is assumed to be at equilibrium or steady-state. For a closed system, like cells in a culture dish, these thermodynamic parameters are quite informative. In an open system like the human body, where compound-target interactions often do not reach equilibrium, the kinetic parameters, in addition to the thermodynamic parameters, are needed to better understand and characterize compound target engagement over time (1,2).

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From Content Creators to Communication Partners: The Role of Motion in Scientific Storytelling

Posted on by Taylor McAda
Image generated by DALL-E.

Moving Science Forward — Literally

I’ve always believed that the best science stories don’t just inform — they move us. And in many cases, that’s quite literal.

Whether I’m designing a figure for a new assay or animating a step-by-step protocol, I see motion as a bridge that turns complexity into clarity. When used well, that bridge transforms scientific communication from dense and static into something dynamic, visual and memorable.

And it’s not just me — a graphic designer — saying this. Scholars like Daniel Liddle describe motion as a form of visual rhetoric: a way to persuade, clarify and build trust through movement. Motion isn’t just decoration — it’s meaning made visible.

In this post, I’ll explore why motion matters in scientific communication and how animation makes complex ideas easier to grasp. From turning a protocol into a story that sticks to making technical jargon something you can remember, motion design helps science feel more approachable and a lot more memorable.

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Bringing Industry-Relevant Lab Experience to Undergraduate Life Sciences Majors with MyGlo®

Posted on by Promega

When Dr. Rebecca Miles retired from her 25-year career in pharmaceutical research at Eli Lilly, she refocused her passion for science on a new challenge. Having worked her way from the bench to Senior Director, she knew first-hand the technical skills required to successfully advance genetic medicine programs. Now, she leverages her industry experience and the latest technologies at Taylor University, a liberal arts institution in Indiana known for its strong emphasis on education and practical training for students’ future careers. As a Visiting Assistant Professor of Biology, Dr. Miles trains her students to develop real-world skills and provides them exposure to technologies that impacted her own career. “I wanted to redesign the lab so that students could come out of the semester with some job skills if they wanted to be a technician in a lab,” she explains.

Dr. Rebecca Miles undergraduate class with their MyGlo®

Teaching Students Modern Technologies

Dr. Miles structures her lab courses to incorporate techniques that scientists would routinely use in an industry setting. Students learn cell culture, plating, luminescent assays, and data analysis in ways that mirror the workflows used in biotech and pharmaceutical labs. She encourages her students to analyze their raw data to learn how the calculations work. “I want the students to calculate it in Excel and do it themselves and see the standard deviation,” she says.

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