School of Medicine
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Instructor, Radiology - Rad/Molecular Imaging Program at Stanford
Current Research and Scholarly Interests My current research areas of interest include developing new strategies for: 1) novel radioligand and radiotracer development for various targets involved in brain cancer, 2) preclinical animal models of glioblastoma, and 3) clinical translation of useful radiopharmaceuticals for early-detection of disease and monitoring therapy.
Associate Professor (Research) of Radiology (Molecular Imaging)
Current Research and Scholarly Interests To develop novel molecular imaging probes and techniques for non-invasively early detection of cancer using multimodality imaging technologies including PET, SPECT, MRI, optical imaging, etc.
Frederick T. Chin, Ph.D.
Assistant Professor (Research) of Radiology (Molecular Imaging)
Current Research and Scholarly Interests Our group's primary objectives are:
1) Novel radioligand and radiotracer development.
We will develop novel PET (Positron Emission Tomography) imaging agents with MIPS and Stanford faculty as well as other outside collaborations including academia and pharmaceutical industry. Although my personal research interests will be to discover and design of candidate probes that target molecular targets in the brain, our group focus will primarily be on cancer biology and gene therapy. In conjunction with our state-of-the-art imaging facility, promising candidates will be evaluated by PET-CT/MR imaging in small animals and primates. Successful radioligands and/or radiotracers will be extended towards future human clinical applications.
2) Designing new radiolabeling techniques and methodologies.
We will aim to design new radiolabeling techniques and methodologies that may have utility for future radiopharmaceutical development in our lab and the general radiochemistry community.
3) Radiochemistry production of routine clinical tracers.
Since we also have many interests with many Stanford faculty and outside collaborators, our efforts will also include the routine radiochemistry production of many existing radiotracers for human and non-human use. Our routine clinical tracers will be synthesized in custom-made or commercial synthetic modules (i.e. GE TRACERlab modules) housed in lead-shielded cells and be distributed manually or automatically (i.e. Comecer Dorothea) to our imagers.
Senior Associate Dean of Research for Platforms/Shared Facilities, Associate Professor of Materials Science and Engineering and, by courtesy, of Radiology (Molecular Imaging Program at Stanford)
Bio Jennifer Dionne is the Senior Associate Dean of Research for Platforms/Shared Facilities and an Associate Professor of Materials Science and Engineering and of Radiology (by courtesy) at Stanford. Jen received her Ph.D. in Applied Physics at the California Institute of Technology, advised by Harry Atwater, and B.S. degrees in Physics and Systems & Electrical Engineering from Washington University in St. Louis. Prior to joining Stanford, she served as a postdoctoral researcher in Chemistry at Berkeley, advised by Paul Alivisatos. Jen?s research focusses on nanophotonics - developing methods to control light at the nano- and molecular scale. She is especially interested in imaging chemical and biological processes as they unfold with nanometer scale resolution, and using these observations to help improve health and sustainability (including photocatalysis and medical diagnostics). Her work has been recognized with the Alan T. Waterman Award (2019), an NIH Director's New Innovator Award (2019), a Moore Inventor Fellowship (2017), the Materials Research Society Young Investigator Award (2017), Adolph Lomb Medal (2016), Sloan Foundation Fellowship (2015), and the Presidential Early Career Award for Scientists and Engineers (2014), and was featured on Oprah?s list of ?50 Things that will make you say ?Wow!'"
Assistant Professor (Research) of Radiology (Molecular Imaging Program at Stanford)
Current Research and Scholarly Interests Dr. Durmus' research focuses on applying micro/nano-technologies to investigate cellular heterogeneity for single-cell analysis and personalized medicine. At Stanford, she is developing platform technologies for sorting and monitoring cells at the single-cell resolution. This magnetic levitation-based technology is used for wide range of applications in medicine, such as, label-free detection of circulating tumor cells (CTCs) from blood; high-throughput drug screening; and rapid detection and monitoring of antibiotic resistance in real-time. During her PhD, she has engineered nanoparticles and nanostructured surfaces to decrease antibiotic-resistant infections.
Professor of Radiology (Molecular Imaging Program at Stanford)
Current Research and Scholarly Interests My focus is image-guided drug and gene delivery and I am engaged in the design of imaging devices, molecularly-targeted imaging probes and engineered delivery vehicles, drawing upon my education in biology and imaging physics and more than 20 years of experience with the synthesis and labeling of therapeutic particles. My laboratory has unique resources for and substantial experience in synthetic chemistry and ultrasound, CT, MR and PET imaging.
Sanjiv Sam Gambhir, MD, PhD
Virginia and D.K. Ludwig Professor for Clinical Investigation in Cancer Research and Professor, by courtesy, of Materials Science and Engineering
Current Research and Scholarly Interests My laboratory focuses on merging advances in molecular biology with those in biomedical imaging to advance the field of molecular imaging. Imaging for the purpose of better understanding cancer biology and applications in gene and cell therapy, as well as immunotherapy are all being studied. A key long-term focus is the earlier detection of cancer by combining in vitro diagnostics and molecular imaging.
Associate Professor of Radiation Oncology (Radiation Physics) and, by courtesy, of Radiology (Molecular Imaging Program at Stanford)
Current Research and Scholarly Interests Applications of molecular imaging in radiation therapy, development of hypoxia and radiosensitivity imaging techniques, small animal image-guided conformal radiotherapy, image processing and analysis.