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News Story

Faculty Spotlight: Stefan Birmanns, PhD

Researcher creates 3D images with innovative approach to computational modeling

Published February 08, 2010 by Rachel Christianson


Stefan Birmanns, PhD, joined The University of Texas School of Health Information Sciences at Houston (SHIS) in 2003 as a post-doctoral research associate.  In the seven years since, he became part of the school's faculty and runs his own lab. Dr. Birmanns

Originally from Germany, Birmanns received his Master's and Doctoral degrees from the University of Aachen. During this time he collaborated with groups in Illinois and California. After receiving his PhD, he then decided to move to the U.S. permanently, where he first worked as a post-doctoral research associate at the Scripps Research Institute in California. Shortly thereafter, Birmanns came to Houston when he followed a faculty mentor to SHIS.

"The School of Health Information Sciences was an attractive opportunity, especially for me as an interdisciplinary researcher," said Birmanns.  "A school devoted to biomedical informatics, situated in the largest medical center in the world."

In 2006 Birmanns became a faculty member at SHIS and less than a year later he took over the Laboratory for Integrative Structural Bioinformatics, which focuses on two key areas of research.

The first is analyzing data from electron microscopy and tomography, which are low resolution, volumetric images of atomic structures. Researchers often look at these images to get a better understanding of molecules, viruses and other systems throughout the body.  However, these images don't provide an atomic level of detail, which makes a computer-based simulation of the dynamics of the molecule impossible. By using data from other experiments, Birmanns is able to develop algorithms that determine a high-resolution reconstruction of the volumetric information of the structure.

This leads to Birmann's second area of research.  After creating the algorithms, Birmann?s and his lab team are able to create interactive 3-D renderings of these complex systems. They develop the molecular modeling and visualization software "Sculptor," which uses state of the art, programmable computer graphics cards to display the large macromolecular systems.
   
"We put the glasses on and see," said Birmanns.

Through this visualization, millions of atoms are rendered and scientists are able to see much more detail than ever before. The challenge is developing meaningful visual renderings that can actually help researchers detect unknown features in data.

To augment the visual sense, Birmanns' team also uses haptic rendering to represent these complex 3D relationships and shapes. A haptic device is employed to create an artificial tactile sensation.  It applies forces, vibrations and motions upon the user.

This type of research is of significant importance for the better understanding of the body's complex systems at a molecular level. For example, glycosis is a process that produces energy for the body. It is also known that tumor cells, like those in cancer, have a very high glycosis rate. This is known as the Warburg effect. If glycosis is better understood at the molecular level, researchers might be able to block a molecular system in the glycolytic pathway and thereby potentially stop or even reverse tumor growth.

In the future, Birmann's research may be able to help in the process of rational drug design. Although his research occurs before actual drug development, it can help accelerate the process by suggesting leads, which makes it more efficient and cost effective.

As one of the relatively few places in the world like it, the lab is routinely used by scientists from the Texas Medical Center for modeling and rendering of large biomedical data sets.  Birmanns also has national and international collaborations with scientists from the University of Vermont, Weill College of Medicine, Penn State University and the Research Center in Juelich, Germany.

Birmann's vision for the lab is to integrate more experimental methods in order to be able to analyze data from images with lower and lower resolutions.

"A long term goal would be the development of an interactive 3D multi-resolution atlas of the cell," said Birmanns, "seamlessly combining experimental data from various sources and levels of resolution, at the same time displaying it using cutting-edge, multi-modal rendering techniques."

With this, he hopes the lab will continue to grow through the addition of more students and researchers.

Additionally, Birmanns teaches several courses at SHIS and won the John P. McGovern Outstanding Teacher Award in 2008. 

 

by Rachel Christianson, School of Health Information Sciences