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Center for Systems and Computational Biology

Applying Advanced Computational and Technological Systems to the Understanding of Human Disease

The Center supports the development of new tools for integrating and analyzing data from a wide variety of sources — including genomics, proteomics, metabolomics, molecular modeling, high-throughput screening, chemical biology, structural biology, and imaging — all of which involve large complex datasets that can challenge limits of available software tools and require high capacity as well as reliable data storage.

As part of its mission to support biomedical research at The Wistar Institute, the CSCB provides comprehensive services to assist with every aspect of scientific computing. The CSCB offers consultations for scientific computing and data management, primarily through the Bioinformatics Core Facility.

Members of the CSCB also collaborate on a variety of projects related to detecting, understanding and treating cancer, other diseases and clinical disorders, as well as projects on infectious disease and the development of new and more effective vaccines.

Systems Biology

Systems biology is an approach to biomedical research in which scientists combine complex “omics” datasets to develop a more complete understanding of complex biological systems, such as the regulation of whole genome-level transcription, regulation of the 3D genome, the role of signaling and metabolic pathways in disease, and more. Systems biology uses a variety of omics tools including genomics, bioinformatics, metabolomics and proteomics to understand biology at a high level of complexity, such as how mutation or loss of a single gene affects cells, tissues and even the entire organism.

Computational Biology

Computational biology is a critical component of systems biology, and in many areas new and improved algorithms are being developed or optimized. These efforts involve the use of computer science, mathematics, and statistics to process and interpret large complex data sets. It provides scientists with the tools to deconstruct these data sets and provide a better understanding of the complexity of normal biological processes and how disruption of those processes leads to a wide range of diseases.

Leadership and Members

Leadership

Bin Tian, Ph.D.

  • Professor and Co-leader, Gene Expression and Regulation Program
  • Co-director, The Wistar Institute Center for Systems and Computational Biology

Louise C. Showe, Ph.D.

  • Professor, Molecular and Cellular Oncogenesis Program
  • Scientific Director, Genomics Facility
  • Associate Director, The Wistar Institute Center for Systems and Computational Biology

Members

Noam Auslander, Ph.D.

  • Assistant Professor, Molecular and Cellular Oncogenesis Program

Qin Liu, M.D., Ph.D.

  • Professor, Molecular and Cellular Oncogenesis Program

Zach Schug, Ph.D.

  • Assistant Professor, Molecular and Cellular Oncogenesis Program

Contact Us

For more information, please contact:

The Wistar Institute Center for Systems and Computational Biology

3601 Spruce Street
Philadelphia, PA 19104
Office: 215-898-3972
Fax: 215-898-0664
cscbhelp@wistar.org