Assistant Professor Joonil Seog

About Dr. Seog

Ph.D., Massachusetts Institute of Technology, 2003

Before joining the faculty as a joint apointee to the Department of Materials Science & Engineering and The Fischell Department of Bioengineering, Dr. Seog was a research fellow at the CBR Institute for Biomedical Research, Inc., located at the Harvard Medical School. He will be developing and teaching undergraduate courses in the MSE and BioE programs and a graduate-level course in single molecule mechanics. One of his goals is to get students involved in cutting-edge research.

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Current Research

Seog's research will provides insight into the design of nanomechanically tailored smart biomaterials that can enhance tissue regeneration or slow down disease progression. His focus is on studying the structure-function relationship of biological molecules using single molecule force spectroscopy. Previously, Seog studied the molecular origin of cartilage biomechanical properties, and by directly measuring intermolecular forces discovered that about 50% of the compressive resistance of cartilage originates from the highly charged polysaccharides within it. This was the first study elucidating the structure and biomechanical function of polysaccharides in cartilage using tools that could measure very small forces such as individual molecular interactions.

Seog is currently pursuing a study of the structural change of biological molecules in relationship to diseases. Many diseases are caused by mutations in the genes that result in structural change in the cell, leading to the degeneration of the body's auto-immune response. Seog believes that understanding how these changes affect the nanomechanical properties of proteins and tissues can help prevent or cure diseases.
He also explores the interaction between synthetic and biological materials. His research in this area will support current efforts to incorporate biological molecules into small devices in order to utilize them as molecular sensing devices such as DNA chips, protein chips, and silicon-based drug delivery devices.

Seog also will also be examining the single molecule mechanical properties of synthetic and biological macromolecules. His goal is to enhance our understanding of basic biological and physical phenomena, as well as enable us to apply them directly when building smart molecular devices or single molecule devices.

Q&A with Dr. Seog

What impact could your work have on society or consumers?

Understanding the relationship between structure of biological material and its function at molecular level is critical for designing novel biomaterials. One of the hot research areas these days is regenerative medicine, where a smart biomaterial is used as a tissue engineering scaffold. It's well known that micromechanical environment of the cell is important for cell development, migration, and tissue regeneration. These microenvironments change during development or disease progression. My research focuses on studying the nanomechanical properties of biological materials that interact with cells and measuring the interaction forces between them at molecular scale. This will provide insight on how to design nanomechanically tailored smart biomaterials that can enhance tissue regeneration or slow down disease progression.

What attracted you to the Clark School?

When I visited the Clark School, I was very impressed by its pioneering research activities and collaborative environment. It's very exciting—the people here are pushing the boundaries of the field with innovative ideas, and in many cases moving toward examining phenomena at the molecular scale with practical application in mind. I felt that my research (single molecule mechanics and nanomechanics of biomaterials) and unique background in single molecule force spectroscopy would fit in very well, since my strength is in providing insightful information for the design of novel biomaterials. Since my research is closely related to that a lot of other faculty members, I felt I'd have numerous collaborative opportunities, which benefits everyone's research.

Why should students (graduate or undergraduate) interested in a career in bioengineering or materials science and engineering study at the University of Maryland?

Nowadays most of the fields are becoming more and more interdisciplinary and requiring collaboration as a team. In that sense, UMD provides perfect environment, since many government research labs and leading experts are close by. In addition, many key industries are located around D.C. area. We have the opportunity to learn about their needs, and work together to solve their problems.

Why should young engineers consider bioengineering or materials science and engineering for their field of study?

There are so many new challenges that lie ahead in this field. There has been continuous need for better materials and it's growing more and more these days. The tremendous success of the semiconductor industry would not have been possible without the breakthroughs in materials science and engineering, and now there is growing demand for soft materials for biomedical application. BioMEMs devices are creating another challenge: How we can incorporate biological materials into inorganic material systems?