Aleksei Aksimentiev
· Professor of PhysicsUniversity of Illinois Urbana-Champaign · Bioengineering
Active 1998–2024
About
Aleksei Aksimentiev is an Associate Professor in the Department of Bioengineering at the University of Illinois Urbana-Champaign. He received his Ph.D. in chemistry cum laude from the Institute of Physical Chemistry, Warsaw, Poland, in 1999, and completed a master's degree in particle physics at Ivan Franko Lviv State University in Ukraine in 1996. His postdoctoral training was conducted at the Materials Science Laboratory R&D Center of Mitsui Chemicals in Tokyo, Japan, from 1999 to 2001, after which he joined the Theoretical and Computational Biophysics Group at the University of Illinois as a research associate. He became a faculty member in the Physics Department at Illinois in 2005. His primary research focuses on computational and systems biology, including biomolecular modeling, bionanotechnology, and nanosensors. His work involves understanding biological nanomachines, developing nanopore systems for single-molecule detection and sequencing, modeling DNA processing machinery, and exploring the physics of DNA assemblies and synthetic molecular systems. His research aims to elucidate the molecular mechanisms underlying biological processes and to design synthetic systems that surpass natural counterparts.
Research signals
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Research topics
- Computer Science
- Chemistry
- Biology
- Computational biology
- Physics
- Bioinformatics
- Operating system
- Parallel computing
- Genetics
- Biophysics
- Computational science
- Computational chemistry
- Nanotechnology
- Biochemistry
- Materials science
Selected publications
Multiple rereads of single proteins at single–amino acid resolution using nanopores
Science · 2021 · 429 citations
- Computer Science
- Chemistry
- Computational biology
in single amino acid variant identification. These proof-of-concept experiments constitute a promising basis for the development of a single-molecule protein fingerprinting and analysis technology.
The emerging landscape of single-molecule protein sequencing technologies
Nature Methods · 2021 · 357 citations
- Computer Science
- Computational biology
- Biology
Scalable molecular dynamics on CPU and GPU architectures with NAMD
The Journal of Chemical Physics · 2020 · 3184 citations
- Computer Science
- Computer Science
- Parallel computing
NAMDis a molecular dynamics program designed for high-performance simulations of very large biological objects on CPU- and GPU-based architectures. NAMD offers scalable performance on petascale parallel supercomputers consisting of hundreds of thousands of cores, as well as on inexpensive commodity clusters commonly found in academic environments. It is written in C++ and leans on Charm++ parallel objects for optimal performance on low-latency architectures. NAMD is a versatile, multipurpose code that gathers state-of-the-art algorithms to carry out simulations in apt thermodynamic ensembles, using the widely popular CHARMM, AMBER, OPLS, and GROMOS biomolecular force fields. Here, we review the main features of NAMD that allow both equilibrium and enhanced-sampling molecular dynamics simulations with numerical efficiency. We describe the underlying concepts utilized by NAMD and their implementation, most notably for handling long-range electrostatics; controlling the temperature, pressure, and pH; applying external potentials on tailored grids; leveraging massively parallel resources in multiple-copy simulations; and hybrid quantum-mechanical/molecular-mechanical descriptions. We detail the variety of options offered by NAMD for enhanced-sampling simulations aimed at determining free-energy differences of either alchemical or geometrical transformations and outline their applicability to specific problems. Last, we discuss the roadmap for the development of NAMD and our current efforts toward achieving optimal performance on GPU-based architectures, for pushing back the limitations that have prevented biologically realistic billion-atom objects to be fruitfully simulated, and for making large-scale simulations less expensive and easier to set up, run, and analyze. NAMD is distributed free of charge with its source code at www.ks.uiuc.edu.
Recent grants
Plasmonic nanopores for trapping, controlled motion and sequencing of DNA
NIH · $2.4M · 2013–2018
NSF · $597k · 2023–2026
High Accuracy Nanopore Sequencing.
NIH · $14.0M · 2009–2025
Multi-resolution Approaches to Modeling the 3D Structure, Delivery, and Replication of Viral Genomes
NIH · $1.2M · 2020–2025
NIH · $6.7M · 2012
Frequent coauthors
- 69 shared
Christopher Maffeo
University of Illinois Urbana-Champaign
- 45 shared
Jejoong Yoo
Sungkyunkwan University
- 30 shared
Jeffrey Comer
Kansas State University
- 30 shared
Himanshu Joshi
- 25 shared
Meni Wanunu
Northeastern University
- 22 shared
Robert Hołyst
Polish Academy of Sciences
- 20 shared
G. Timp
University of Notre Dame
- 20 shared
Behzad Mehrafrooz
University of Illinois Urbana-Champaign
Labs
Education
- 2005
Ph.D., Bioengineering
University of Illinois Urbana-Champaign
- 2001
M.S., Bioengineering
University of Illinois Urbana-Champaign
- 1999
B.S., Bioengineering
University of Illinois Urbana-Champaign
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