Skip to main content
MIT Corporate Relations
MIT Corporate Relations
Search
×
Read
Watch
Attend
About
Connect
MIT Startup Exchange
Search
Sign-In
Register
Search
×
MIT ILP Home
Read
Faculty Features
Research
News
Watch
Attend
Conferences
Webinars
Learning Opportunities
About
Membership
Staff
For Faculty
Connect
Faculty/Researchers
Program Directors
MIT Startup Exchange
User Menu and Search
Search
Sign-In
Register
MIT ILP Home
Toggle menu
Search
Sign-in
Register
Read
Faculty Features
Research
News
Watch
Attend
Conferences
Webinars
Learning Opportunities
About
Membership
Staff
For Faculty
Connect
Faculty/Researchers
Program Directors
MIT Startup Exchange
Back to Faculty/Researchers
Prof. C Forbes Dewey, Jr
Professor of Mechanical and Bioengineering, Emeritus
Co-Director, International Consortium for Medical Imaging Technology (ICMIT)
Primary DLC
Department of Mechanical Engineering
MIT Room:
3-354
(617) 253-2235
cfdewey@mit.edu
Areas of Interest and Expertise
Biomedical Fluid Mechanics
Atherosclerosis
Microvascular Flow
Molecular Engineering
Applications of Lasers to Spectroscopy
Biomedical Research and Pollution Monitoring
Medical Imaging Technology
Databases for Health Care
Biological Imaging and Functional Measurement
Cell, Tissue and Fluid Biomechanics
Cell and Tissue Engineering
Physiological Modeling
Fluid Flow Effects on Biological Cells
Laboratory Imaging System
Computational Biology
Actin Dynamics
Bioinformatics
Biological and Physiological Transport Phenomena
Computational Modeling of Biological and Physiological Systems
Molecular Dynamics
Heparan Sulfate
Research Summary
Professor Dewey's group uses microscopy to probe the effects of mechanical forces on living cells. The targets of interest, endothelial cells, protect the artery wall from the inflammatory reactions that result in atherosclerosis. The cells have a mechanical structure that depends on a network of polymerized actin molecules. Fluorescent dyes are used as markers to tag individual molecules of actin, and we look at how they move and diffuse through the cell. This can tell us how much of the actin is polymerized and how much is in monomeric form. Application of a fluid shear force comparable to those that blood flow applies to these cells causes a major transient decrease in polymerization, and we believe that this is correlated with the observed realignment of the cells in the flow direction. Additional measurements of cell motility and intercellular gap junction proteins is extending our understanding of the interaction process. We are also undertaking major computational modeling of actin polymerization in collaboration with colleagues at the University of Rochester. The ability to peer inside individual cells with modern fluorescence techniques has powered a profound change in our quantitative understanding of cellular biological function. Imaging research also includes the reconstruction of 3-D images from stereo pairs taken using scanning electron microscopy (SEM). These images allow us to see the interaction of individual structural features within the cells at the molecular level. We currently use antibodies tagged with gold particles to visualize the specific conformation and interaction between different proteins, for example between polymerized actin filaments and the actin binding protein filamin-A.
A second major program within the lab is the development of robust information systems for biological data. The goal is to develop a common technology that will capture all major experimental biological data types in a single ontological framework. So far, we have shown this with gel electrophoresis, microarrays, and fluorescence-activated cell sorting, and are currently implementing mass spectrometry and optical microscopy. We've shown that these data can all be stored and searched from within a single database or from collaborating (federated) databases. The methods of federation are novel and have significant potential for application. A second area of research is the development of new algorithms for extracting structured information from unstructured documents. Additional information on these results will be available in the Fall of 2003.
Recent Work
Projects
July 18, 2008
Department of Mechanical Engineering
Da Vinci's Notebook - A Revolution in Scientific Database Management
Principal Investigator
C Dewey
July 18, 2008
Department of Mechanical Engineering
Advanced Imaging Informatic Technologies (AIIT)
Principal Investigator
C Dewey
August 4, 2006
Department of Mechanical Engineering
Probing the Effects of Medical Forces in Living Cells
Principal Investigator
C Dewey
August 2, 2006
Department of Mechanical Engineering
Integration of Experimental Data from Different Sources
Principal Investigator
C Dewey
August 1, 2006
Department of Mechanical Engineering
A New Class of Functions for Describing Logical Structures in Text
Principal Investigator
C Dewey
March 7, 2002
Department of Mechanical Engineering
Actin Dynamics in Vascular Endothelium
Principal Investigator
C Dewey
August 20, 1998
Department of Mechanical Engineering
International Consortium for Medical Imaging Technology (ICMIT)
Principal Investigator
C Dewey
Related Faculty
Julie Diop
Senior Program Manager
Prof. Woodie C Flowers
Pappalardo Professor of Mechanical Engineering, Emeritus
Brian D Hemond
Lecturer