“I find it fulfilling to be a scientist because I know that even if at some points it seems like I’m working on an incremental experiment, eventually it’s going to help solve a bigger problem,” says Caroline Jones, Ph.D., an assistant professor of bioengineering at the University of Texas at Dallas. Check out the highlights of our interview with Dr. Jones to learn about her career path, her passion for sharing science with the public, and her research on sepsis—an overwhelming or impaired whole-body immune response to an insult, such as an infection or injury that’s responsible for the deaths of nearly 270,000 Americans every year.
Q: How did you first become interested in science?
A: My mother was a high school math teacher, so I had that role model growing up. I also had a math and engineering teacher in high school who encouraged me and sparked my interest in the quantitative side of science. I decided to study biomedical engineering in college because I wanted to apply quantitative tools in a way that helped people.
“You’re doing something really important with people who are important to you,” Paul Worsley remarks when asked about having his younger brothers Caleb and Adam as lab mates. The trio are undergraduate students working in the lab of Santimukul Santra, Ph.D., at Pittsburg State University in Pittsburg, Kansas.
All three brothers are part of the Kansas IDeA Networks of Biomedical Research Excellence (K-INBRE). Paul is currently a junior majoring in biology and history. He plans to go to medical school when he graduates, but his time in the lab has given him a love for research—and has even led him to toy with the idea of going to graduate school instead. His twin brothers Caleb and Adam are only freshmen, but they both think they want to pursue scientific research when they graduate.
When Paul was a sophomore, he applied for a K-INBRE research spot in Dr. Santra’s lab and was immediately accepted. He quickly realized that organic chemistry in the lab was much different—and more exciting—than anything he’d seen in the classroom. “I like organic synthesis because it really tests your knowledge,” he says. “Answering exam questions is way different than actually doing it in a lab.” Despite the challenges that came with research, Paul was clearly doing great work because one day Dr. Santra joked, “Hey, you got any brothers?” Paul responded, “Actually, yes.”
Attention, educators! We’re announcing a new clearinghouse of free STEM education resources covering a wide range of health and biomedical research topics for students in grades K through 12. The STEM teaching resources website provides links to great content from various institutes and centers within NIH, as well as materials developed under the NIGMS Science Education Partnership Award program.
The resources are easy to navigate within the following subject areas:
“My parents told me that I already wanted to be a scientist when I was 7 or 8 years old. I don’t remember ever considering anything else,” says Ry Young, Ph.D., a professor of biochemistry, biophysics, and biology at Texas A&M University, College Station.
Dr. Young has been a researcher for more than 45 years and is a leading expert on bacteriophages—viruses that infect bacteria. He and other scientists have shown that phages, as bacteriophages are often called, could help us fight bacteria that have developed resistance to antibiotics. Antibiotic-resistant infections cause more than 35,000 deaths per year in the U.S., and new, effective treatments for them are urgently needed.
Many of us learned in English class that an antagonist is a person or thing that a hero fights. But in biomedical science, an antagonist is a molecule that binds to a cellular receptor to prevent a response, such as a muscle contraction or hormone release. Antagonists can be important medical treatments, like the antagonist naloxone—also known as
Narcan —that can reverse an opioid overdose.
NIGMS is pleased to bring you Pathways: The Vaccine Science Issue [PDF], which explains how the messenger RNA (mRNA) vaccines for COVID-19 work and how they were developed. Building on years of research, scientists were able to create these vaccines, thoroughly test them, and get them to the public as quickly as possible—while still making sure they were safe and effective.
Pathways, designed for students in grades 6 through 12, aims to build awareness of basic biomedical science and its importance to health while inspiring careers in research. All materials in the collection are available online for free.
“I love the mystery of chemistry. It explores the great unknown of the universe,” says Phil Baran, Ph.D., a professor of chemistry at Scripps Research, La Jolla, California. His passion for the subject catalyzed a successful career in organic synthesis—building molecules that are the foundation of living things and can be developed as medicines.
Setting His Sights on Science
School didn’t interest Dr. Baran until he found chemistry in 10th grade. “From there, the mission was clear: do whatever was required to do chemistry for the rest of my life,” he says. At the time, that meant achieving certain grades, so he focused on improving his academic performance. He also took courses at a community college and graduated with his high school diploma and associate degree simultaneously.
“Patients at urban and inner-city hospitals are in dire need of high-quality care and frequently don’t have access to clinician-scientists doing cutting-edge research. That’s part of what has made me committed to performing research in these settings,” says Faheem Guirgis, M.D., an associate professor of emergency medicine at the University of Florida College of Medicine, Jacksonville. Check out the highlights of our interview with Dr. Guirgis below to learn how he became a doctor and what inspired him to conduct research on sepsis.
Q: How did you become interested in science and medicine?
A: After the phase of wanting to be a firefighter or police officer, the next thing I remember wanting to be was a doctor. My father was and is my ultimate inspiration for pursuing a career in medicine. He was a family-practice physician committed to providing the best care possible for his patients before retiring recently, and they loved him.
The cloud. To many, it’s a mysterious black hole that somehow transports photos and files from their old or lost phone to their new one. To some researchers, though, it’s an invaluable resource that allows them access to data analytics tools they wouldn’t otherwise have.
Scientists have begun using cloud computing to store, process, and analyze their data through online bioinformatics tools. Biological data sets are often large and hard to interpret, requiring complex calculating instructions—or algorithms—to understand them. Fortunately, these algorithms can run on local computers or remotely through cloud computing.
One advantage of cloud-based programs over local computers is the ability to analyze data without taking up the user’s personal storage space. With cloud-based storage, researchers can store their large data files, including their labeled notes called annotations. Another benefit is that users have easy access to software packages within the cloud for data analysis. The cloud also encourages collaboration among scientists by making it easy to share large amounts of data.
The intricate process of
mitosis—a cell splitting into two identical daughter cells—plays a pivotal role in sustaining life. Many scientists study this process to understand what’s needed for it to progress normally and why it sometimes goes awry, such as in cancer. During their research, the scientists often create eye-catching images and videos, and we showcase some of those visuals here.