Michael I. Miller is the Bessie Darling Massey Professor and Director of Biomedical Engineering at Johns Hopkins University. He is also co-director of the Kavli Neuroscience Discovery Institute.
As a biomedical engineer who specializes in data science, Miller is pioneering cutting-edge technologies in computational medicine to understand and diagnose neurodegenerative diseases. His research focuses on the functional and structural characteristics of the human brain in health and disease, including Huntington’s disease, Alzheimer’s disease, dementia, bipolar disorder, schizophrenia, and epilepsy. By developing new tools to analyze patient brain scans, derived from advanced medical imaging technologies, Miller aims to predict the risk of developing neurological disorders years before the onset of clinical symptoms. His lab is currently devising cloud-based methods to build and share libraries of brain images—and the algorithms used to understand them—associated with neuropsychiatric illness. Miller’s research is highly translational, and he has co-founded four start-up companies in the past decade.
Miller has co-authored more than 200 peer-reviewed publications, as well as two highly cited textbooks on random point processes and computational anatomy. In 2002, he was recognized by the Institute for Scientific Information (ISI) Essential Science Indicators for garnering the highest rate of increase in total citations in the field of engineering for his work in computational anatomy.
He has received numerous awards for his work, including the national Institute of Electrical and Electronics Engineers (IEEE) Biomedical Engineering Thesis Award in 1982, the Johns Hopkins Paul Ehrlich Graduate Student Thesis Award in 1983, and the National Science Foundation (NSF) Presidential Young Investigator Award in 1986. He was named an inaugural Johns Hopkins University Gilman Scholar in 2011 for demonstrating a distinguished record of research, teaching, and service. He is an elected Fellow of the American Institute for Medical and Biological Engineering, the Institute of Electrical and Electronics Engineers, and the Biomedical Engineering Society.
Miller earned his BS from the State University of New York at Stony Brook in 1976, and his MS and PhD in biomedical engineering from Johns Hopkins University in 1978 and 1983, respectively. He was the Newton R. and Sarah L. Wilson Professor in Biomedical Engineering at Washington University in St. Louis until joining Johns Hopkins University in 1998. He was named the Herschel and Ruth Seder Professor in Biomedical Engineering in 2003, before his appointment as the director of biomedical engineering in 2017. He was also previously the director of the Johns Hopkins Center for Imaging Science.
- Bessie Darling Massey Professor, Biomedical Engineering
- Director, Department of Biomedical Engineering
- Co-Director, Kavli Neuroscience Discovery Institute
- Johns Hopkins Gilman Scholar
- Professor, Electrical and Computer Engineering
Affiliated Centers & Institutes
- PhD, Biomedical Engineering, Johns Hopkins University, 1984
- MS, Electrical Engineering, Johns Hopkins University, 1979
- BS, Electrical Engineering, The State University of NY at Stony Brook, 1976
June 17, 2019Johns Hopkins University announced 32 multidisciplinary endeavors that have been selected to receive support this year from the JHU Discovery Awards program. Seven faculty from the Department of Biomedical Engineering are part of those endeavors.
May 20, 2019In a records review of 290 people at risk for Alzheimer’s disease, scientists at Johns Hopkins say they have identified an average level of biological and anatomical brain changes linked to Alzheimer’s disease that occur three to 10 years — some even more than 30 years — before the disease’s first recognizable symptoms appear.
October 11, 2017Michael I. Miller, director of the Johns Hopkins Department of Biomedical Engineering, opened the 2017 Biomedical Engineering Society Annual Meeting in Phoenix, AZ on October 11 by unveiling a plan for a new era of biomedical science discovery to respond to the challenges of the 21st century.