Amanda Randles | |
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Education | |
Awards |
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Scientific career | |
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Institutions | Duke University |
Thesis | Modeling Cardiovascular Hemodynamics Using the Lattice Boltzmann Method on Massively Parallel Supercomputers (2013) |
Doctoral advisor |
Amanda Randles is an American computer scientist who is the Alfred Winborne and Victoria Stover Mordecai Associate Professor of Biomedical Sciences at Duke University. Randles is an associate professor of biomedical engineering with secondary appointments in computer science, mathematics, and mechanical engineering and materials science. She is a member of the Duke Cancer Institute. Her research interests include biomedical simulation, machine learning, computational fluid dynamics, and high-performance computing.
In high school, Randles attended the Utica Center for Math, Science, and Technology, where she learned computer programming and its applications in the sciences. She also participated in Science Olympiad and FIRST Robotics. [1]
Randles attended Duke University, where she completed a B.A. in physics and computer science in 2005. After working for three years as a software developer on the IBM Blue Gene project, [1] she went to Harvard University to earn an S.M. in computer science (2010) and a PhD in applied physics (2013) [2] advised by Efthimios Kaxiras and Hanspeter Pfister. [1] She was awarded an NSF Graduate Research Fellowship (GRFP) and in 2011, she was awarded a Computational Science Graduate Fellowship by the Krell Institute. She subsequently completed a practicum at Lawrence Livermore National Laboratory [2] and was a visiting scientist at Franziska Michor's laboratory in the Dana–Farber Cancer Institute. [1]
Randles joined the Duke University Biomedical Engineering Department in 2015, where she is currently serving as the Alfred Winborne and Victoria Stover Mordecai Associate Professor of Biomedical Sciences. [3] She received tenure in 2023 in Biomedical Engineering and has secondary appointments in mathematics, computer science, and mechanical and materials science. She is also a member of the Duke Cancer Institute. [4]
Randles' research interests are biomedical simulation and high-performance computing; specifically, her focus is developing computational tools that can examine the behavior of different diseases, from atherosclerosis to cancer. [4] Randles and her research group have developed fluid dynamics simulation software capable of modeling blood flowing throughout a human body based on full-body CT and MRI scans, dubbed HARVEY after the physician William Harvey. Possible applications include examining how different medical interventions in cardiovascular disease impact the circulatory system and modeling the flow of singular cancer cells through the system. [5]
In 2018, Randles was one of ten researchers selected to test simulation-based projects on the Aurora exascale supercomputer in 2021, as part of the Aurora Early Science Program at the Argonne National Laboratory. [6] [7] She was awarded an NSF CAREER Award in May 2020 to support her work on HARVEY. [8]
In 2023, she was warded the NIH Pioneer award to support her work combining wearables with physics-based models. She is a Fellow of the National Academy of Inventors. For her work on ventilator splitting during the Covid-19 pandemic, she was awarded the Alexandra Jane Noble Epiphany Science Inspiration Award. In 2014, Randles was awarded the NIH Director's Early Independence Award. [9] She was named to the 2015 World Economic Forum Young Scientist List for her work on the "design of large-scale parallel applications targeting problems in physics". [10] In 2017, she was awarded the Grace Murray Hopper Award and was later named to the MIT Technology Review Innovators Under 35, both given for her work on HARVEY. [11] [12]
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