Team:Princeton

From 2008.igem.org

(Difference between revisions)
 
(5 intermediate revisions not shown)
Line 10: Line 10:
-
The goal of the Princeton iGEM team is to utilize the immense capabilities of neurons and in particular of neuronal networks – in terms of efficiency, speed of transmission of information and output, physical size, robustness, reliability, and programmable versatility – by taking two very different approaches to neuronal networks using gene-regulatory circuits.[[Team:Princeton/Project#Overall_project | Read more.]]
+
The goal of the Princeton iGEM team is to utilize the considerable capabilities of neurons and in particular of neuronal networks – in terms of speed of transmission of information, physical and programmable versatility – by designing neural networks using gene-regulatory circuits and microfabrication of surfaces. [[Team:Princeton/Project_Overview | Read more.]]
-
|[[Image:iGEM_Logo.jpg|right]]
+
|[[Image:iGEM_Logo2.jpg|right|250px]]
|}
|}
-
 
-
 
-
THIS WIKI IS STILL UNDERGOING CONSTRUCTION. PARDON THE MISSING LINKS AND ANY RANDOM STUFF THAT POPS UP.
 

Latest revision as of 03:39, 30 October 2008

PrincetonLogo.gif

PRINCETON IGEM 2008

Home Project Overview Project Details Experiments Results Notebook
Parts Submitted to the Registry Modeling The Team Gallery




When they’re not locking each other in a 4 C freezer or arguing about whether Dennis Kucinich is anti-American, the Princeton iGEM team is hard at work: to do with neurons what electrical engineers had already done with silicon chips back when the Charleston was the dance craze sweeping the nation. They are a motley crew of accomplished coffee thieves with majors ranging from chemical engineering to economics, which probably explains why they can’t agree upon anything and settle their differences with cold torture.




The goal of the Princeton iGEM team is to utilize the considerable capabilities of neurons and in particular of neuronal networks – in terms of speed of transmission of information, physical and programmable versatility – by designing neural networks using gene-regulatory circuits and microfabrication of surfaces. Read more.

IGEM Logo2.jpg