%0 Journal Article %1 Ismagilov2001 %A Ismagilov, Rustem F. %A Ng, Jessamine M. K. %A Kenis, Paul J. A. %A Whitesides, George M. %D 2001 %I American Chemical Society %J Anal. Chem. %K diffusion membrane microfluidics %N 21 %P 5207–5213 %R 10.1021/ac010502a %T Microfluidic Arrays of Fluid−Fluid Diffusional Contacts as Detection Elements and Combinatorial Tools %U http://pubs.acs.org/doi/full/10.1021/ac010502a %V 73 %X This paper describes microfluidic systems that can be used to investigate multiple chemical or biochemical interactions in a parallel format. These three-dimensional systems are generated by crossing two sets of microfluidic channels, fabricated in two different layers, at right angles. Solutions of the reagents are placed in the channels; in different modes of operation, these solutions can be either flowing or stationarythe latter is important when one set of channels is filled with viscous gels with immobilized reagents. At every crossing, the channels are separated either by a single membrane or by a composite separator comprising a membrane, a microwell, and a second membrane. These components allow diffusive mass transport and minimize convective transport through the crossing. Polycarbonate membranes with 0.1−1-μm vertical pores were used to fabricate the devices. Each crossing of parallel channels serves as an element in which chemical or biochemical interactions can take place; interactions can be detected by monitoring changes in fluorescence and absorbance. These all-organic systems are straightforward to fabricate and to operate and may find applications as portable microanalytical systems and as tools in combinatorial research.

@article{Ismagilov2001, abstract = {This paper describes microfluidic systems that can be used to investigate multiple chemical or biochemical interactions in a parallel format. These three-dimensional systems are generated by crossing two sets of microfluidic channels, fabricated in two different layers, at right angles. Solutions of the reagents are placed in the channels; in different modes of operation, these solutions can be either flowing or stationarythe latter is important when one set of channels is filled with viscous gels with immobilized reagents. At every crossing, the channels are separated either by a single membrane or by a composite separator comprising a membrane, a microwell, and a second membrane. These components allow diffusive mass transport and minimize convective transport through the crossing. Polycarbonate membranes with 0.1−1-μm vertical pores were used to fabricate the devices. Each crossing of parallel channels serves as an element in which chemical or biochemical interactions can take place; interactions can be detected by monitoring changes in fluorescence and absorbance. These all-organic systems are straightforward to fabricate and to operate and may find applications as portable microanalytical systems and as tools in combinatorial research.}, added-at = {2013-03-22T09:31:14.000+0100}, author = {Ismagilov, Rustem F. and Ng, Jessamine M. K. and Kenis, Paul J. A. and Whitesides, George M.}, biburl = {https://www.bibsonomy.org/bibtex/20121f8f0c4824e0ab2c2356e4445a74b/quantentunnel}, day = 20, doi = {10.1021/ac010502a}, file = {Ismagilov2001.pdf:Artikel/Ismagilov2001.pdf:PDF}, groups = {public}, interhash = {ed41b2ba17b2a97ec4066ca038092cd7}, intrahash = {0121f8f0c4824e0ab2c2356e4445a74b}, journal = {Anal. Chem.}, keywords = {diffusion membrane microfluidics}, month = {September}, number = 21, pages = {5207–5213}, publisher = {American Chemical Society}, timestamp = {2013-04-16T10:23:52.000+0200}, title = {Microfluidic Arrays of Fluid−Fluid Diffusional Contacts as Detection Elements and Combinatorial Tools}, url = {http://pubs.acs.org/doi/full/10.1021/ac010502a}, username = {quantentunnel}, volume = 73, year = 2001 }