Title :

Microscale Manipulation of Cells and Their Environment for Cell Sorting and Stem Cell Biology

Speaker :

Prof. Joal Voldman

Department of Electrical Engineering and Computer Science

Massachusetts Institute of Technology, USA

Venue :

Room 215, William M. W. Mong Engineering Building, CUHK

Date :

Jan 17, 2012, Tuesday
11:00 AM - 12:00 PM

Abstract :

Microsystems have the potential to impact biology by providing new ways to manipulate cells and the microenvironment around them. Simply physically manipulating cells or their environment--using microfluidics, electric fields, or optical forces--provides new ways to separate cells and organize cell-cell interactions. One example illustrating the power of microscale manipulation of cells is to sort cells based on their intrinsic electrical properties. Electrical properties have previously been correlated with important biological phenotypes (apoptosis, cancer, etc.), but a sensitive and specific method approach has been lacking. We have developed a method called iso-dielectric separation that uses electric fields to drive cells to the point in a conductivity gradient where they become electrically transparent, resulting in a continuous separation method specific to electrical properties. With this method, we have screened the entire genome of an organism to understand the biological basis of electrical properties, finding that the relationship between genetics and intrinsic properties has both intuitive and non-intuitive features. Microfluidics can also be used to manipulate the environment around cells. For example, we have developed arrays of microfluidic perfusion culture chambers that use fluid flow to create a convection-dominated transport environment, allowing control over local cell-cell diffusible signaling. This in turn provides a more controlled soluble microenvironment in which to study diffusible signaling in cell systems. In particular, we have examined the impact of diffusible signaling on self-renewal and neural specification of embryonic stem cells. Using these microsystems, we have identified the existence of previously unknown autocrine loops involved in fate specification, and have delineated the effects of shear itself on self-renewal. Together, these new microscale tools provide ways to exploit cells` potential for both basic science and applied biotechnology.

Biography :

Prof. Joel Voldman, Ph. D., is an Assoociate Professor of Electrical Engineering and Computer Science at the Massachusetts Institute of Technology in Cambridge, MA. Prof. Voldman received the B.S. degree in electrical engineering summa cum laude from the University of Massachusetts, Amherst, in 1995. He received the Masters degree in electrical engineering from the Massachusetts Institute of Technology (MIT), Cambridge, in 1997 and his Ph.D. from MIT in 2001. Following this, he performed postdoctoral training in George Church`s lab at Harvard Medical School. He has been on the MIT faculty since July 2002. In 2004, he was awarded the NBX Career Development Chair, and in 2006 he was promoted to associate professor. Prof. Voldman`s research interests include cellular bioMEMS, dielectrophoresis microfluidic devices, microfabrication technology, surface science, bioengineering and fluid mechanics in general.

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Enquiries: Ms. Winnie Wong, Department of Mechanical and Automation Engineering, CUHK at 3943 8337. *MAE Series (2011-12) is contained in the World-Wide Web home page at http://www3.mae.cuhk.edu.hk/maeseminars.php#mae.

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