Nastassja Lewinski is currently an Assistant Professor of Chemical and Life Science Engineering at Virginia Commonwealth University. She holds a Ph.D. in Bioengineering and a B.S. in Chemical Engineering from Rice University. Dr. Lewinski has focused her career on integrating biological and environmental compatibility into the design process of engineered nanomaterials. Her research areas include nanotoxicology, nanoinformatics, and sustainable nanotechnology. Her projects over the past three years were supported through industry and VCU sponsorship. She has received numerous prestigious awards and fellowships including the AIChE 35 Under 35 Award in 2017, Leenaards Nested Research Projects Award in 2014, Whitaker International Scholar Award in 2011, NSF Graduate Research Fellowship in 2008, Barry Goldwater Scholarship in 2005, and she is a member of both Tau Beta Pi and Phi Lambda Upsilon. Dr. Lewinski has authored and co-authored 25 peer-reviewed journal articles, 5 book chapters, and 1 provisional patent. She currently advises 1 Ph.D. student and 1 M.S. student as well as 12 undergraduate students under VIP and capstone projects.
Industry Expertise (3)
Areas of Expertise (5)
AIChE 35 Under 35 Awardee (professional)
Leenaards Nested Research Projects Prix Awardee (professional)
Whitaker International Scholar (professional)
NSF Graduate Research Fellow (professional)
Barry Goldwater Scholar (professional)
Institute for Work and Health, Lausanne, Switzerland: Postdoctoral 2014
Rice University: Ph.D., Bioengineering 2011
Rice University: B.S., Chemical Engineering 2006
Media Appearances (1)
AIChE 35 Under 35: Safety
American Institute of Chemical Engineering (AIChE) online
Nastassja is an assistant professor of chemical and life science engineering at Virginia Commonwealth University. She serves as faculty advisor to the student chapter and is the VCU faculty representative in the Tidewater Virginia Local Section. Nastassja is also active in the Sustainable Engineering Forum. Among her awards are the Leenaards Nested Research Projects Prix (2014), a NNEMS Fellowship with the U.S. EPA (2008), and an NSF Graduate Fellowship (2008).
AIChE YPC: What inspired you to pursue chemical engineering?
Nastassja Lewinski: I chose to pursue chemical engineering because it encompasses my lifelong interests in chemistry and math.
AIChE YPC: Chemical engineering is a diverse field. How did you get involved in your specialty?
NL: During my studies, several people reinforced my interest in nanotechnology and safety by design. My Ph.D. advisor, Rebekah Drezek, cultivated my interest in nanomedicine. The WISE program sponsored by AIChE and my advisor, Dave Gushee, encouraged my engagement in science policy. Vicki Colvin and Kristen Kulinowski drew my attention to aquatic toxicology and industrial hygiene.
AIChE YPC: What professional achievement are you most proud of?
NL: My postdoctoral fellowship in Lausanne, Switzerland, provided the opportunity not only to collaborate with fellow researchers in the institute who spoke English, but also work with non-English speaking staff. I learned how people outside the United States conduct research and how to work in a non-English speaking environment professionally.
AIChE YPC: What is the most challenging part of your job?
NL: The most challenging part of being a university professor is balancing research and teaching. Besides advancing my own research program, motivating and supporting both the students in my lab and also the students in my courses consumes a good portion of my time.
Portable in vitro exposure cassette (PIVEC)
U.S. Provisional Patent Application.
Inventors: N. Lewinski and L. Secondo
CLSE 202: Chemical Engineering Fundamentals II: Energy Balances and Engineering Thermodynamics
Spring 2018, 2019
CLSE 305: Thermodynamics of Phase Equilibria and Chemical Reactions
Fall 2014, 2015, 2016, 2017
This course provides the foundation needed to solve sophisticated problems encountered in thermodynamics and unit operations. Students are introduced to the mathematical relationships and thermodynamic models needed to describe pure component and mixture phase behavior. These models include equations of state, liquid solution activity coefficient models, and fugacity estimation techniques. Numerous phase equilibrium problems are addressed including liquid-vapor, liquid-liquid, liquid-liquid-vapor, and solid-vapor equilibria. The prediction of chemical equilibrium is also covered in this course.
ENGR 497: Vertically Integrated Project - Nanoinformatics
Fall 2017 - present
The VIP Nanoinformatics team will participate in cutting-edge research in machine learning and nanomedicine design. This includes the development of multiple natural language processing tools that use complex algorithms and artificial intelligence techniques to retrieve nanomedicine texts from the primary literature, classify the texts into topics, extract relevant entities on nanomedicine, and extract relationships between entities, to name a few. Students also have the opportunity to gain hands on laboratory experience in nanoparticle synthesis, physico-chemical characterization, exposure assessment, and biocompatibility testing.
ENGR 591: Nanotechnology Environmental, Health, and Safety Impacts
Spring 2016, 2017
This course provides a fundamental understanding of nanotechnology and its environmental, health, and safety impact. We will discuss nanomaterials synthesis, fabrication, and characterization. Applications of engineered nanomaterials in medicine, including nanotechnology-based drug delivery systems will be discussed and used as examples for nanoEHS analyses. Host response to nanomaterials and nanotoxicology will be the focal point of the course. Research methods in nanotoxicology will be emphasized, including essential skills such as critical analysis of scientific literature, effective oral and written communication.
Selected Articles (9)
In this paper, we review the different informatics methods that have been applied to patent mining, nanomaterial/device characterization, nanomedicine, and environmental risk assessment.
There is a critical opportunity in the field of nanoscience to compare and integrate information across diverse fields of study through informatics (i.e., nanoinformatics). This paper is one in a series of articles on the data curation process in nanoinformatics (nanocuration).
Tungsten inert gas welding (TIG) represents one of the most widely used metal joining processes in industry. Its propensity to generate a greater portion of welding fume particles at the nanoscale poses a potential occupational health hazard for workers. However, current literature lacks comprehensive characterization of TIG welding fume particles.