Cornell University held the first Annual Cornell Cancer Research Symposium at the College of Veterinary Medicine on April 5-6 to showcase the breadth of cancer research on the Ithaca campus.Read more about Cancer event explores ways to bridge Ithaca, NYC campuses
Claudia Fischbach-Teschl is an Associate Professor of Biomedical Engineering at Cornell University and the Director of Cornell's Physical Sciences Oncology Center on the Physics of Cancer Metabolism. She received her Ph.D. in Pharmaceutical Technology from the University of Regensburg, Germany and holds an M.S. in Pharmacy from the Ludwigs-Maximilians-University, Munich, Germany. She conducted her postdoctoral work at Harvard University in the Division of Engineering and Applied Sciences and joined the faculty of Cornell in 2007. Dr. Fischbach-Teschl's lab applies biomedical engineering strategies to study cancer with the ultimate goal of identifying new mechanisms that may ultimately help to prevent and treat this disease. She serves on the NIH Tumor Microenvironment Study Section and is an editorial board member of various journals including the new ACS journal Biomaterials Science and Engineering.
Cellular interactions with their surrounding including other cells and extracellular matrix are critically important in the development and progression of cancer. However, current cancer research mostly studies cells under conditions that do not reflect how cells exist in the body. By exploring tissue engineering, microfabrication, and biomaterials strategies the Fischbach-Teschl lab engineers model systems that allow studying tumor cells under conditions that mimic those within patients. In particular, the Fischbach-Teschl lab uses these model systems to gain a better understanding of the biological and physical principles that tumors use to modulate the function of normal blood vessels, stem cells, and bone in order to become more aggressive and ultimately metastasize to distant sites.
- Molecular and Cellular Engineering
- Polymers and Soft Matter
- Nanobio Applications
- Mechanics of Biological Materials
- Biomedical Engineering
- Biomechanics and Mechanobiology
- Drug Delivery and Nanomedicine
- Tissue Engineering & Biomaterials
- Microfluidics and Microsystems
- Multiphase and Granular Flows
- 2016."Collagen I hydrogel microstructure and composition conjointly regulate vascular network formation."Acta Biomateriala44. .
- 2015."Obesity-dependent changes in interstitial ECM mechanics promote breast tumorigenesis."Science translational medicine7(301): 301ra130. .
- 2014."In vitro models of tumor vessels and matrix: engineering approaches to investigate transport limitations and drug delivery in cancer.."Advanced drug delivery reviews69-70: 205-216. .
- 2013."In Vivo Tibial Compression Decreases Osteolysis and Tumor Formation in a Human Metastatic Breast Cancer Model."Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research28(11): 2357-67. .
- 2011."Hydroxyapatite Nanoparticle-containing scaffolds for study of breast cancer bone metastasis."Biomaterials32(22): 5112-22. .
Selected Awards and Honors
- Research Excellence Award(Cornell College of Engineering)2016
- Elected Fellow(American Institute for Medical and Biological Engineering)2016
- Humboldt Research Fellowship for Experienced Researchers(Max Planck Institute for Colloids and Interfaces in Potsdam, Germany)2013
- ORS Young Investigator(AAOS / ORS Molecular Biology and Therapeutics in Musculoskeletal Oncology (MBTMO) Meeting)2008
- Invited Speaker(Gordon Research Conference, "Mammary Gland Biology" at Mount Snow Resort in Vermont)2015
- MS(Pharmacy),Ludwig Maximilians University,1998
- Ph D(Pharmaceutical Technology),University of Regensburg,2003
In the News
Cornell will hold the first Annual Cancer Research Symposium to showcase diverse and groundbreaking cancer research on campus, and to better integrate investigators from the Ithaca campus and Weill...Read more about Cancer symposium aims to unify Cornell researchers
Researchers discover cancer favors a certain state of bone mineral, breast cancer tumors remotely enhance that favorable state.Read more about Metastatic breast cancer affects bone mineral before spreading