Sort by
Refine Your Search
-
Listed
-
Country
-
Employer
- The University of Iowa
- University of Cambridge
- Duke University
- Georgetown University
- Nature Careers
- University of Massachusetts Medical School
- Aston University
- DAAD
- Lulea University of Technology
- National Institute for Bioprocessing Research and Training (NIBRT)
- Purdue University
- The Ohio State University
- University of California Irvine
- University of California, Berkeley
- University of California, Santa Cruz
- University of New Hampshire – Main Campus
- University of Oxford
- University of Southern California
- University of Southern California (USC)
- Virginia Tech
- 10 more »
- « less
-
Field
-
About the Role Join a multi-disciplinary team that explores human intestinal development and disease using cutting edge single cell and spatial biology technologies, organoid models and
-
therapies for such cancers, and test them in cellular and animal models. If you thrive in a collaborative environment and have a keen interest in both imaging and treatment of cancer, this role is perfect
-
molecular biology, quantitative imaging and biophysical approaches to investigate cell shape changes in cultured cells and in vivo. Current projects in the lab include investigating the regulation
-
modeling) Molecular ecology and genetic analysis Ecosystem forecasting Salmon life history Climate and ecosystems CoastWatch /PolarWatch Fisheries resources (including advanced survey technologies
-
molecular biology, quantitative imaging and biophysical approaches to investigate cell shape changes in cultured cells and in vivo. Current projects in the lab include investigating the regulation
-
model complexes. This research is part of a large, funded collaborative project supported by the Swiss National Science Foundation, involving partner researchers based in Germany, Switzerland, and France
-
supervising studies that involve in vitro assays and in vivo mouse tumor models to understand mechanisms of immunotherapy resistance, exploration of pathways involved in signal transduction in different T cell
-
available to conduct research on chronic pain. Using animal pain models, behavioral tests, calcium imaging, patch-clamp, optogenetics, neuroanatomy, molecular biology, the successful candidate is expected
-
, which has seen little improvement in patient survival over the past decades. Utilizing genetically engineered mouse and human glioma models, our lab investigates how glioma cells interact with the tumor
-
supervising studies that involve in vitro assays and in vivo mouse tumor models to understand mechanisms of immunotherapy resistance, exploration of pathways involved in signal transduction in different T cell