School of Medicine
Showing 11-20 of 20 Results
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Peter Fitzgerald, MD, PhD
Professor (Research) of Medicine (Cardiovascular), Emeritus
BioDr. Peter Fitzgerald is the Director of the Center for Cardiovascular Technology and Director of the Cardiovascular Core Analysis Laboratory (CCAL) at Stanford University Medical School. He is an Interventional Cardiologist and has a PhD in Engineering. He is Professor in both the Departments of Medicine and Engineering (by courtesy) at Stanford. Presently, Dr. Fitzgerald’s laboratory includes 17 postdoctoral fellows and graduate engineering students focusing on state-of-the-art technologies in Cardiovascular Medicine. He has led or participated in over 175 clinical trials, published over 550 manuscripts/chapters, and lectures worldwide. He has trained over 150 post-docs in Engineering and Medicine in the past decade. In addition, he heads the Stanford/Asia MedTech innovation program.
Dr. Fitzgerald has been principle/founder of twenty-one medical device companies in the San Francisco Bay Area. He has transitioned fourteen of these start-ups to large medical device companies. He serves on several boards of directors, advised dozens of medical device startups as well as multinational healthcare companies in the design and development of new diagnostic and therapeutic devices in the cardiovascular arena. In 2001, Peter was on the founding team of LVP Capital, a venture firm, focused on medical device and biotechnology start-ups in San Francisco. In 2009, he co-founded TriVentures, which is an incubator/venture fund for early stage medical technology in Israel. -
Dominik Fleischmann
Professor of Radiology (Cardiovascular Imaging)
Current Research and Scholarly InterestsNon-invasive Cardiovascular Imaging
Image Post-processing
Contrast Medium Dynamics -
Michael B. Fowler, MBBS, FRCP
Professor of Medicine (Cardiovascular), Emeritus
Current Research and Scholarly InterestsAdrenergic nervous system; beta-adrenergic function in, heart failure; drugs in heart failure.
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Curtis Frank
W. M. Keck, Sr. Professor in Engineering, Emeritus
BioThe properties of ultrathin polymer films are often different from their bulk counterparts. We use spin casting, Langmuir-Blodgett deposition, and surface grafting to fabricate ultrathin films in the range of 100 to 1000 Angstroms thick. Macromolecular amphiphiles are examined at the air-water interface by surface pressure, Brewster angle microscopy, and interfacial shear measurements and on solid substrates by atomic force microscopy, FTIR, and ellipsometry. A vapor-deposition-polymerization process has been developed for covalent grafting of poly(amino acids) from solid substrates. FTIR measurements permit study of secondary structures (right and left-handed alpha helices, parallel and anti-parallel beta sheets) as a function of temperature and environment.
A broadly interdisciplinary collaboration has been established with the Department of Ophthalmology in the Stanford School of Medicine. We have designed and synthesized a fully interpenetrating network of two different hydrogel materials that have properties consistent with application as a substitute for the human cornea: high water swellability up to 85%,tensile strength comparable to the cornea, high glucose permeability comparable to the cornea, and sufficient tear strength to permit suturing. We have developed a technique for surface modification with adhesion peptides that allows binding of collagen and subsequent growth of epithelial cells. Broad questions on the relationships among molecular structure, processing protocol, and biomedical device application are being pursued. -
Victor Froelicher, MD
Professor of Medicine (Cardiovascular) at the Veterans Affairs Palo Alto Health Care System, Emeritus
Current Research and Scholarly InterestsScreening of athletes for sudden cardiac death, Computerized ECG and clinical data management; exercise Physiology including expired gas analysis; the effect of chronic and acute exercise on the heart; digital recording of biological signals; diagnostic use of exercise testing; development of Expert Medical System software and educational tools.
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Eri Fukaya
Clinical Associate Professor, Surgery - Vascular Surgery
Clinical Associate Professor, Medicine - Primary Care and Population HealthBioDr. Fukaya practices Vascular Medicine at the Stanford Vascular Clinics and Advanced Wound Care Center. She received her medical education in Tokyo and completed her medical training both in the US and Japan. She joined Stanford in 2015.
Vascular Medicine covers a wide range of vascular disorders including chronic venous insufficiency, varicose veins, deep vein thrombosis, post thrombotic syndrome, peripheral artery disease, carotid artery disease, cardiovascular risk evaluation, fibromuscular dysplasia, rare vascular disease, lymphedema, arterial/venous/diabetic ulcers, and wound care.
Dr. Fukaya has a special interest in venous disease and started the Stanford Vascular and Vein Clinic in 2016.
Board Certified in Vascular Medicine
Board Certified in Internal Medicine
Board Certified in Internal Medicine (Japan)
Board Certified in Plastic and Reconstructive Surgery (Japan) -
Gerald Fuller
Fletcher Jones Professor in the School of Engineering
BioThe processing of complex liquids (polymers, suspensions, emulsions, biological fluids) alters their microstructure through orientation and deformation of their constitutive elements. In the case of polymeric liquids, it is of interest to obtain in situ measurements of segmental orientation and optical methods have proven to be an excellent means of acquiring this information. Research in our laboratory has resulted in a number of techniques in optical rheometry such as high-speed polarimetry (birefringence and dichroism) and various microscopy methods (fluorescence, phase contrast, and atomic force microscopy).
The microstructure of polymeric and other complex materials also cause them to have interesting physical properties and respond to different flow conditions in unusual manners. In our laboratory, we are equipped with instruments that are able to characterize these materials such as shear rheometer, capillary break up extensional rheometer, and 2D extensional rheometer. Then, the response of these materials to different flow conditions can be visualized and analyzed in detail using high speed imaging devices at up to 2,000 frames per second.
There are numerous processes encountered in nature and industry where the deformation of fluid-fluid interfaces is of central importance. Examples from nature include deformation of the red blood cell in small capillaries, cell division and structure and composition of the tear film. Industrial applications include the processing of emulsions and foams, and the atomization of droplets in ink-jet printing. In our laboratory, fundamental research is in progress to understand the orientation and deformation of monolayers at the molecular level. These experiments employ state of the art optical methods such as polarization modulated dichroism, fluorescence microscopy, and Brewster angle microscopy to obtain in situ measurements of polymer films and small molecule amphiphile monolayers subject to flow. Langmuir troughs are used as the experimental platform so that the thermodynamic state of the monolayers can be systematically controlled. For the first time, well characterized, homogeneous surface flows have been developed, and real time measurements of molecular and microdomain orientation have been obtained. These microstructural experiments are complemented by measurements of the macroscopic, mechanical properties of the films. -
Margaret T. Fuller
Reed-Hodgson Professor of Human Biology, Katharine Dexter McCormick and Stanley McCormick Memorial Professor and Professor of Genetics and of Obstetrics/Gynecology (Reproductive and Stem Cell Biology)
On Leave from 04/01/2024 To 07/19/2024Current Research and Scholarly InterestsRegulation of self-renewal, proliferation and differentiation in adult stem cell lineages. Developmental tumor suppressor mechanisms and regulation of the switch from proliferation to differentiation. Cell type specific transcription machinery and regulation of cell differentiation. Developmental regulation of cell cycle progression during male meiosis.
