School of Medicine
Showing 1-10 of 12 Results
David T. Paik
Instructor, Cardiovascular Institute
Bio Dr. David Paik is instructor working with Dr. Joseph Wu at Stanford Cardiovascular Institute. At Stanford, his focus is to utilize single-cell RNA-sequencing technology to elucidate patient-specific mechanisms of various cardiovascular diseases, characterize embryonic heart development, and optimize differentiation of iPSCs to subtypes of cardiovascular cells. Dr. Paik received his BA in Biochemistry and Molecular Biology at Boston University (2010) and PhD in Cell and Developmental Biology at Vanderbilt University (2015). At Vanderbilt, Dr. Paik investigated the endogenous cardiac repair mechanisms in the adult heart following ischemic injury such as myocardial infarction, with focus on the role of Wnt signaling pathway on coronary vessel formation and plasticity of endothelial cells during cardiac tissue repair. During his PhD training, Dr. Paik completed HHMI/VUMC Certificate Program in Molecular Medicine, where he was supervised by his clinical mentor Dr. Douglas Sawyer to interact with congestive heart failure patients and to bridge clinical sciences with basic and translational cardiovascular research. Dr. Paik is currently supported by the NIH NHLBI K99/R00 Pathway to Independence Award.
Postdoctoral Research Fellow, Cardiovascular Institute
Bio Dr. Paul Pang is a postdoctoral fellow at the Stanford Cardiovascular Institute with research interests in disease modeling, drug discovery, and precision medicine through the use of embryonic and induced pluripotent stem cells. Dr. Pang received his PhD from Baylor College of Medicine (2019) where he studied the alternative splicing of SCN5A in the heart and the effects of its misregulation in myotonic dystrophy. During his PhD training, he was a recipient of the NIH T32 and F31 NRSA Predoctoral Fellowships, Claude W. Smith Fellowship Award, and Dean's Award of Excellence among numerous presentation and travel awards from the Muscular Dystrophy Association and the American Heart Association. During his postdoctoral training, Dr. Pang has been awarded and funded by the NIH T32 and F32 NRSA Postdoctoral Fellowships.
Alan C. Pao
Assistant Professor of Medicine (Nephrology) and, by courtesy, of Urology at the Palo Alto Veterans Affairs Health Care System
Current Research and Scholarly Interests We are interested in how the kidneys control salt, water, and electrolyte homeostasis in the body. We use cultured kidney cells, transgenic mice, and human samples to study hormonal and signal transduction pathways that control epithelial ion transport. Clinical implications of our work include a better understanding of the pathogenesis of salt-sensitive hypertension and kidney stone formation and growth.
John M. Pauly
Reid Weaver Dennis Professor
Bio Interests include medical imaging generally, and magnetic resonance imaging (MRI) in particular. Current efforts are focused on medical applications of MRI where real-time interactive imaging is important. Two examples are cardiac imaging, and the interactive guidance of interventional procedures. Specific interests include rapid methods for the excitation and acquisition of the MR signal, and the reconstruction of images from the data acquired using these approaches.
Dr. Richard K. and Erika N. Richards Professor
Current Research and Scholarly Interests Mechanims (molecular and cellular) of pulmonary hypertension, treatment of pulmonary hypertension, treatment of respiratory failure, treatment of septic shock, hemodynamic monitoring
Boston Scientific Applied Biomedical Engineering Professor and Professor of Radiology, Emeritus
Current Research and Scholarly Interests Broadly, Dr. Pelc is interested in the physics, engineering and mathematics of medical imaging, especially computed tomography, digital x-ray imaging, magnetic resonance imaging, and hybrid multimodality systems. His current research is concentrated in the development of computed tomography systems with higher image quality and dose efficiency, in the characterization of system performance, and in the development and validation of new clinical applications.
Associate Professor of Medicine (Cardiovascular Medicine) at the Stanford University Medical Center
Bio Dr. Marco Perez's research goal is to better understand the fundamental causes of cardiovascular disease through the study of genetics and epidemiology. His group studies the genetic variations and environmental exposures that are associated with conditions such as atrial fibrillation and heart failure. He has led the studies of atrial fibrillation in Women's Health Initiative, one of the largest nation-wide population-based cohorts. He is currently conducting a large study monitoring for silent or asymptomatic atrial fibrillation in women from the WHI randomized to exercise intervention, and is co-PI in the Apple Heart Study, a clinical trial using the Apple Watch to screen for atrial fibrillation. He is interested in understanding the paradox that atrial fibrillation is less common in African Americans and Hispanics, despite a greater burden of risk factors such as hypertension. As director of the Stanford Inherited Arrhythmia Clinic, he evaluates families with rare inherited arrhythmias associated with sudden death such as Long QT and Brugada Syndromes and explores their links with novel genes. He is particularly interested in studying the genetic causes of very early onset atrial fibrillation. He also studies how best to use the electrocardiogram to identify patients at risk for atrial fibrillation and athletes at risk for life-threatening arrhythmias due to conditions such as hypertrophic cardiomyopathy. His genetic studies have led to the discovery of promising novel therapeutic targets that his group is now studying at a functional level. Dr. Perez receives funding from NIH/NHLBI (R01), Apple Inc., the Weston Havens Foundation, The Stanford Cardiovascular Division and the Stanford SPARK program.
Associate Professor of Electrical Engineering
Current Research and Scholarly Interests Our research focuses on providing theoretical foundations and engineering platforms for realizing electronics that seamlessly integrate with the body. Such systems will allow precise recording or modulation of physiological activity, for advancing basic scientific discovery and for restoring or augmenting biological functions for clinical applications.