Title :
Engineering neural networks in vitro: microstamping biomolecules to control cell position
Author :
Wheeler, Bruce C. ; Branch, Darren W. ; Corey, J.M. ; Weyhenmeyer, James A. ; Brewer, Gregory J.
Author_Institution :
Beckman Inst. for Adv. Sci. & Technol., Illinois Univ., Urbana, IL, USA
fDate :
30 Oct-2 Nov 1997
Abstract :
The authors have developed a technique in which biomolecules may be stamped on glassy substrates in arbitrary patterns, with micrometer resolution, and in multiple layers. The silicone rubber microstamps are formed from micromachined (by reactive ion-etch) polyimide molds. Fluorescence patterns demonstrate efficacy in biomolecule transfer. Patterns of stamped and photoresist patterned polylysine are equally effective in controlling growth of neuroblastoma cells. The technique is promising for the creation of biological neural networks in culture
Keywords :
biocontrol; biological techniques; biomolecular electronics; cellular biophysics; fluorescence; lithography; micromachining; neural nets; neurophysiology; silicone rubber; biological neural networks creation technique; biomolecule transfer; cell position control; engineering neural networks in vitro; fluorescence patterns; micromachined polyimide molds; microstamping biomolecules; neuroblastoma cells growth control; photoresist patterned polylysine; reactive ion-etch; silicone rubber microstamps; Biological neural networks; In vitro; Molecular biophysics; Neural networks; Neurons; Page description languages; Polyimides; Resists; Substrates; Titanium;
Conference_Titel :
Engineering in Medicine and Biology Society, 1997. Proceedings of the 19th Annual International Conference of the IEEE
Conference_Location :
Chicago, IL
Print_ISBN :
0-7803-4262-3
DOI :
10.1109/IEMBS.1997.756859
