Corporate Banner
Satellite Banner
Technology Networks Header
Wednesday, November 26, 2014
Technology Networks
 
Register | Sign in
Home Page
  News
Return

Electron Beam Fabrication of a Microfluidic Device for Studying Submicron-Scale Bacteria

Published: Friday, April 26, 2013
Last Updated: Friday, April 26, 2013
Bookmark and Share
This study presents an EBL and poly(dimethylsiloxane) (PDMS) [28] soft-lithography [29] protocol for the fabrication of a micro?uidic device for microbial studies.


For access to this article, enter your email address to instantly recieve a Password Reset link.

Please enter your email address below:

Existing users please Sign In here. Don't have an account? Register Here for free access.

Don't have an account? | Register Here


Scientific News
Stanford Engineers Discover How to Record the Forensic History of Chemical Contaminations in Water
An invention called a time capsule is a tiny chemistry lab designed to take a fingerprint of contamination and also disclose when it occurred.
Wallet-Sized Labs The Next Big Thing
RMIT researchers are developing inexpensive, portable toxicology laboratories so small you could fit them in your wallet.
Device Invented at Johns Hopkins Provides Up-close Look at Cancer on the Move
Microscopic view of metastasis could give insight about how to keep cancer in check.
A Medical Lab For The Home
Fraunhofer FIT demonstrates a mobile wireless system that monitors the health of elderly people in their own homes, using miniature sensors.
Detecting Prostate Cancer With a Microfluidic Device
Innovative device detects prostate cancer, kidney disease on the spot.
Hello? Sweat and a Smartphone Could Become The Hot New Health Screening
A new article highlighting UC research reveals how sweat and microfluidics can pinpoint and help dodge potential health issues for everyone from athletes to preemies.
New 'Lab-on-a-Chip' Could Revolutionize Early Diagnosis of Cancer
Faster result times, reduced costs, minimal sample demands and better sensitivity of analysis.
How Fluid Flow Influences Neuron Growth
A University of Texas at Arlington team exploring how neuron growth can be controlled in the lab and, possibly, in the human body has published a new paper in Nature Scientific Reports on how fluid flow could play a significant role.
‘Tissue Chip’ to Screen Neurological Toxins
UW-Madison team are developing a faster, more affordable way to screen for neural toxins.
Modular Components Make Building 3-D “Labs-on-a-Chip” a Snap
New building blocks take microfluidics from flat to 3-D quickly and easily.
Scroll Up
Scroll Down
Skyscraper Banner
SELECTBIO Market Reports
Follow TechNetcom1 on Twitter
Technology Networks Ltd. on LinkedIn
Go to LabTube.tv
Go to Lab-on-a-Chip RSS Feed