Difference between revisions of "Collins Lab"

From OpenWetWare
Line 15: Line 15:
{| cellspacing="3"  
{| cellspacing="3"  
|- valign="top"
|- valign="top"
|width=380px class="MainPageBG" style="border: 1px solid #cc3300; color: #000; background-color: #ff6633"|
|width=360px class="MainPageBG" style="border: 1px solid #cc3300; color: #000; background-color: #ff6633"|
<div style="padding: .4em .9em .9em">
<div style="padding: .4em .9em .9em">

Revision as of 12:40, 23 November 2006

This site is in development. Please see our Boston University homepage


Home        Contact        Internal        Lab Members        Publications        Research        Talks       

In the press

USA Today article on "Tools help seniors be independent"
Discovery Channel Canada video on "Insoles to keep you upright"
IEEE Spectrum Editor's Blog on "Feel the Noise"
Op-Ed in the New York Times
Scientific American article on "In the Business of Synthetic Life"
IEEE Spectrum article on "Good Vibrations"
Trends in Biotechnology article on "Engineering Regulatory RNAs"
Trends in Biotechnology article on "Rewiring the Cell"
Nature Biotechnology News & Views article on "Custom Design of Metabolism"
Trends in Biotechnology article on "Synthetic Biology Evolves"
First Annual Conference on Synthetic Biology
Scientific American article on "Synthetic Life"
Science article on "Microbes Made to Order"
Nature News & Views article on "Medical Technology: Balancing the Unbalanced"




Our lab is focused on developing and using nonlinear dynamics approaches to study, mimic and improve the function of biological systems. We are currently working in three areas:

Systems Biology: We are developing and implementing computational-experimental methods to reverse engineer and analyze regulatory networks in microbes and higher organisms.

Synthetic Biology: We are modeling and building synthetic gene networks for a variety of biotechnology and biocomputing applications. We are also using engineered gene networks to study general principles underlying gene regulation.

Noise-Enhanced Sensorimotor Function: We are developing noise-based devices, such as vibrating insoles, to improve balance control in older adults and patients with diabetic neuropathy, stroke, Parkinson's disease, and multiple sclerosis, respectively.

Our lab is part of the Center for BioDynamics, the Department of Biomedical Engineering, the Bioinformatics Program, the Center for Advanced Biotechnology, the Molecular Biology, Cell Biology & Biochemistry (MCBB) Program at Boston University, and the Frontiers in Integrative Biological Research.