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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.

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.

Promega’s luciferase reporter assays are an important part of this training. Rather than using Western blots, which can be challenging for students, Dr. Miles took advantage of the ease of Promega’s NF-κB reporter assays to measure transcription factor activity. The results are both intuitive and impactful. “It’s a great way to show that you can actually have a transcription factor increase RNA and you get this lovely luciferase readout,” she explains. Students are quick to notice the advantages too. As Dr. Miles recalls, “They’ll ask, ‘Hey, I want to do that luciferase assay that was so easy.’” And with CellTiter-Glo® Assays, the students can monitor how their experiments affect cell viability, leveraging the data visualizations that are automatically generated with the ProNect® CellTiter-Glo® app.

Teaching the next generation with MyGlo® and the CellTiter-Glo® app

Making Science Accessible and Engaging

Affordability and portability are major advantages for a teaching institution with limited budgets and space. With a footprint only slightly larger than a microtiter plate, MyGlo® can be stored safely in a drawer and moved easily between teaching labs. “It’s so small, I don’t want it to sprout legs and walk away,” Dr. Miles jokes. The device connects through Wi-Fi, requiring only a power cord, and can be run with ProNect® Data Platform from any computer with internet access. Its user-friendly design means class time is spent on learning science, not troubleshooting equipment.

The integration with the ProNect® Data Platform adds another dimension. Immediately after reads are complete, heat maps are shown, helping students quickly check if their experiments worked before they download raw data for deeper analysis. Dr. Miles appreciates this feature to help the students do a quick QC check of their data. The short read time, color-coded heat maps and exportable data make experiments more interactive while still encouraging students to learn how to properly analyze data.

The experience MyGlo® provides is especially meaningful for undergraduates. Students at Taylor will likely encounter luciferase assays again in graduate school, medical programs, or biotech jobs. By gaining hands-on experience now, they build confidence and familiarity with techniques that will give them an advantage later. “I just felt like training the students on how you can use reporter assays and luciferase-based assays would be critical going forward. It’s just something that they’ll run into,” Dr. Miles explains. She wants them to be familiar with how the assays work, so they’re ready for whatever comes next in their careers.

A Trusted Partner for Scientific Training

MyGlo® has supported Dr. Miles’ vision for training the next generation of scientists. MyGlo® and the ProNect® Data Platform provide the students with sensitivity, accuracy, and user-friendly data visualizations at a price point compatible with limited budgets at teaching institutions. “I was thrilled to be able to access it right at this price point,” she says. “Love the product, love what it can do to teach students.” From her time in industry to her current role, Dr. Miles is focused on mentoring early career scientists and empowering them with knowledge of current technologies for future success. With MyGlo® in the classroom, she continues that mission: one student, one luminescent assay at a time.

Like Dr. Miles, you can bring industry-relevant assays into your classroom. Learn how MyGlo® Reagent Reader and Promega’s luminescent assays could transform your lab courses, and apply for Promega’s Training Support Program.

CellTiter-Glo, ProNect, and MyGlo are registered trademarks of Promega Corporation. 

For research use only. Not for use in diagnostic procedures.  

Compact Design, Big Impact: Tridek-One Therapeutics Leverages MyGlo® to Accelerate Discovery of Immunomodulating Treatments

Posted on by Promega

In today’s biotech landscape, speed and precision are essential. For Tridek-One Therapeutics, a Paris-based spin-off from INSERM founded in 2018, these qualities drive their mission to develop first-in-class CD31 checkpoint agonist therapies for autoimmune and inflammatory diseases. By leveraging CD31’s ITIM motifs to modulate ITAM signaling, their approach targets immune cells selectively, reducing the risk of broad immunosuppression.

Operating in a biotech incubator with limited space and shared equipment, the team—including Trang Tran, PhD, Preclinical Research Director, and Guillaume Even, Senior Laboratory Technician—depends on luminescent assays requiring both sensitivity and precise timing. Relying on a shared plate reader often delayed extracellular ATP assays that needed rapid measurement. Walking between lab spaces and potentially waiting for access to the plate reader was not feasible.

Tridek-One needed a dedicated, reliable luminometer that could support their time-sensitive workflow and fit into their small lab space. That’s when Tridek-One discovered the MyGlo® Reagent Reader, Promega’s compact, portable 96-well luminometer and transformed their workflow. Even noted that, when they first tried MyGlo®, they “directly saw the power of this small machine.” Tran and Even found that MyGlo®’s performance and sensitivity were comparable to more expensive multi-mode readers, which gave them confidence in choosing MyGlo® as a reliable and cost-effective solution. Because they prefer to use 96-well microplates, MyGlo® fit their experimental setup perfectly.

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Top 5 Luciferase Reporter Vectors You Didn’t Know You Needed (But Now Can’t Live Without) 

Posted on by Simon Moe

Ever spent your Friday night troubleshooting a cloning reaction that just won’t work? 

We’ve been there. So have thousands of other scientists. That’s why Promega and Addgene teamed up to create something game-changing: a curated collection of 600+ luciferase reporter vectors, designed to help you skip the cloning and get straight to the data. 

Addgene, the nonprofit plasmid-sharing platform trusted by researchers worldwide, and Promega, a global leader in luminescent assay technologies, have joined forces to make your gene expression, pathway analysis, and cell signaling experiments faster, easier, and reproducible. 

In this post, we’re spotlighting 5 standout vectors from the new collection that are making life in the lab a whole lot better. 

Continue reading “Top 5 Luciferase Reporter Vectors You Didn’t Know You Needed (But Now Can’t Live Without) “

One Health in Action: Integrated Solutions for Animal Health Pathogens

Posted on by Promega

For research use only

Introduction: Diagnostic Innovation for Zoonotic Threats

When a veterinarian detects influenza A in pigs, they’re not just protecting a herd; they’re helping safeguard public health through broad ongoing surveillance.

To support rapid, biosafe detection of Influenza A viruses (H5N1, H3N2, H1N1) in animal populations, Promega and Longhorn Vaccines and Diagnostics have partnered to create a workflow that doesn’t require BSL-3 containment. It’s scalable, field-ready, and designed with One Health in mind.

This work is part of our broader commitment to enabling real-time disease surveillance—across species and borders. Together with Longhorn, we’re building molecular diagnostics that meet the moment, and the future.

Want the technical details? Read the press release. 

Why It Matters: Influenza A and Diagnostic Bottlenecks

Influenza A viruses—including highly pathogenic strains like H5N1—pose a dual threat to animal health and human safety. Yet despite the urgency, many surveillance and research efforts stall at the lab bench. Why? Because working with zoonotic pathogens often requires high-containment (BSL-3) facilities—especially when dealing with real-world samples like cow milk, poultry swabs, or pig oral fluids.

To help overcome this barrier, Promega and Longhorn set out to design a complete diagnostic workflow that does more than just detect. It needed to:

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What Drives Muscle Fiber Shifts in Obesity and Type ll Diabetes?

Posted on by Kari Kenefick

Skeletal muscle is the body’s main consumer of glucose derived from food.

Muscle Fiber Types
Skeletal muscle is composed of two types of muscle fiber: Type I (slow-twitch) and Type II (fast-twitch).
Type I fibers contract slowly and can maintain contraction over long periods of time. They are rich in mitochondria and myoglobin and are well vascularized. These fibers rely mostly on aerobic metabolism to make the ATP that fuels cells. Type I muscle fibers are fatigue-resistant and efficient—great for supporting posture, distance running, cycling and any activity that needs steady output.

Type II fibers contract quickly, produce more force and power, but also fatigue more quickly. They have fewer mitochondria and less vasculature and rely more on anaerobic pathways like glycolysis (using glucose without oxygen).

Type I muscle fibers are smaller in diameter and generate less peak force but excel at endurance and heat management. Type II fibers are typically larger, produce more force and speed and handle explosive tasks like sprinting, jumping or heavy lifting.

Most muscles are a mix of fiber types, and genetics sets the starting ratio of Type l to Type ll, but fibers are adaptable. With aging and disuse, Type II fibers tend to atrophy more, which is one reason that power declines faster than endurance.

Another distinction important for this story: Type I fibers are more insulin-sensitive than Type II fibers. Additionally, these fiber types differ in different body types.

Continue reading “What Drives Muscle Fiber Shifts in Obesity and Type ll Diabetes?”

Measure Engagement to Target Proteins within Complexes: Why Context Matters

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.

For target-based drug discovery programs, biochemical assays using purified target proteins are often run for initial hit discovery, as these assays are target-specific, quantitative and amenable for high-throughput screens, allowing for precise characterization of target-compound interactions. However, proteins do not act in isolation inside the cells. Instead, proteins form complexes with other cellular components to drive cellular processes, signaling cascades, and metabolic pathways. Just as the interactions between a target protein and its binding partners can influence the target function, compound engagement with target proteins can vary depending on the protein complex formed.

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At the Forefront of Biologics Characterization: Insights from Promega R&D Scientists 

Posted on by Tera Madigan Ogorazalek

As biologics grow more complex, so do the tools required to understand, validate, and ensure their quality. From monoclonal antibody cocktails to antibody-drug conjugates (ADCs) and cell therapies, developers are navigating new frontiers in potency, purity, and functional characterization. 

Promega’s R&D scientists have been actively contributing to this evolving dialogue through respected industry platforms like BioCompare and BEBPA. Through ongoing collaboration with industry experts, Promega scientists are developing innovative assays and strategies that address the complex challenges of biologics development and quality assurance. 

This article highlights key takeaways from five recent publications featuring Promega experts and collaborators, with insights spanning from early research to quality assurance in manufacturing. 

Continue reading “At the Forefront of Biologics Characterization: Insights from Promega R&D Scientists “

Cellular Selectivity Profiling: Unveiling Novel Interactions and More Accurate Compound Specificity

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.

Determining the selectivity of a compound is critical during chemical probe or drug development. In the case of chemical probes, having a clearly defined mechanism of action and specific on-target activity are needed for a chemical probe to be useful in delineating the function of a biological target of interest in cells. Similarly, optimizing a drug candidate for on-target potency and reducing off-target interactions is important in the drug development process (1,2). A thorough understanding of the selectivity profile of a drug can facilitate drug repurposing, by enabling approved therapeutics to be applied to new indications (3). Interestingly, small molecule drugs do not necessarily require the same selectivity as a chemical probe, since some drugs may benefit from polypharmacology to achieve their desired clinical outcome.

Selectivity profiling panels based on biochemical methods have commonly been used to assess compound specificity for established target classes in drug discovery and chemical probe development. Biochemical assays are target-specific and often quantitative, enabling direct measurements of compound affinities for targets of interest and facilitate comparison of compound engagement to a panel of targets. As an example, several providers offer kinase selectivity profiling services using different assay formats and kinase panels comprised of 100 to 400 kinases (4). However, just as biochemical target engagement does not always translate to cellular activity, selectivity profiles based on biochemical platforms may not reflect compound selectivity in live cells (5).

Continue reading “Cellular Selectivity Profiling: Unveiling Novel Interactions and More Accurate Compound Specificity”

Is Your Lab Environment Messing with Your Results? How to Spot the Signs Early

Posted on by Promega

This blog was contributed by guest Avi Aggarwal, 2025 summer intern at Promega.

If you’ve ever scratched your head over inconsistent experimental results, especially ones that seem to fluctuate for no obvious reason—you’re not alone. Sometimes the problem isn’t your pipetting, your reagents, or even your protocol. It might be the room itself.

Changes in temperature, humidity, or even invisible dust particles can quietly throw off your results. Something as simple as moving your thermocycler under an air vent or setting up a plate reader where sunlight hits it in the afternoon could cause subtle but significant issues.

Scientist removes samples from liquid nitrogen tank, affecting the immediate laboratory environment.
Any number of things can affect the laboratory environment, from opening a cryo tank to moving an instrument under an air vent.

Our Project to Learn How Subtle Environmental Changes Can Affect Sensitive Lab Equipment

We spent some time developing an environmental anomaly detection framework aimed at helping scientists understand how subtle environmental changes can affect sensitive lab equipment and experimental results. Our team set out to monitor real-world lab conditions using temperature and humidity sensors, including live testing with a GloMax® Discover platform and Sensirion SHT45 sensors. We also worked with open-source environmental datasets to simulate a variety of lab-like conditions, such as daily cycles, sudden temperature spikes, and slow humidity drifts.

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