Dissolvable membranes as sensing elements for microfluidics based biological/chemical sensors.

We demonstrate a chemical and biological sensing mechanism in microfluidics that transduces chemical and biological signals to electrical signals with large intrinsic amplification without need for complex electronics. The sensing mechanism involves a dissolvable membrane separating a liquid sample chamber from an interdigitated electrode. Dissolution of the membrane (here, a disulfide cross-linked poly(acrylamide) hydrogel) in the presence of a specific target (here, a reducing agent-dithiothreitol) allows the target solution to flow into contact with the electrode. The liquid movement displaces the air dielectric with a liquid, leading to a change (open circuit to approximately 1 kOmega) in the resistance between the electrodes. Thus, a biochemical event is transduced into an electrical signal via fluid movement. The concentration of the target is estimated by monitoring the difference in dissolution times of two juxtaposed sensing membranes having different dissolution characteristics. No dc power is consumed by the sensor until detection of the target. A range of targets could be sensed by defining membranes specific to the target. This sensing mechanism might find applications in sensing targets such as toxins, which exhibit enzymatic activity.

[1]  R. Spencer,et al.  Preparedness and response to bioterrorism. , 2001, The Journal of infection.

[2]  R Lejeune,et al.  Chemiluminescence as diagnostic tool. A review. , 2000, Talanta.

[3]  E. Lai,et al.  Surface plasmon resonance-based immunoassays. , 2000, Methods.

[4]  W. P. Bennekom,et al.  Chemiluminescence and immunoassays. , 1994, Journal of pharmaceutical and biomedical analysis.

[5]  Charles M Lieber,et al.  Label-free detection of small-molecule-protein interactions by using nanowire nanosensors. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[6]  G. Deng,et al.  Applications of mass spectrometry in early stages of target based drug discovery. , 2006, Journal of pharmaceutical and biomedical analysis.

[7]  H. Elwing,et al.  Protein absorption and ellipsometry in biomaterial research. , 1998, Biomaterials.

[8]  D. Seliktar,et al.  Biosynthetic hydrogel scaffolds made from fibrinogen and polyethylene glycol for 3D cell cultures. , 2005, Biomaterials.

[9]  Robin H. Liu,et al.  Microfluidic tectonics: a comprehensive construction platform for microfluidic systems. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[10]  M. Ghadiri,et al.  A porous silicon-based optical interferometric biosensor. , 1997, Science.

[11]  Loomans,et al.  Real-Time Monitoring of Peptide-Surface and Peptide-Antibody Interaction by Means of Reflectometry and Surface Plasmon Resonance , 1997, Journal of colloid and interface science.

[12]  M. Hamburg,et al.  Bioterrorism: responding to an emerging threat. , 2002, Trends in biotechnology.

[13]  Anna Whyatt,et al.  Notes and references , 1984, International Journal of Legal Information : Official Publication.

[14]  R. Misra,et al.  Biomaterials , 2008 .

[15]  C. Lieber,et al.  Nanowire Nanosensors for Highly Sensitive and Selective Detection of Biological and Chemical Species , 2001, Science.

[16]  A. K. Agarwal,et al.  Integration of polymer and metal microstructures using liquid-phase photopolymerization , 2006 .

[17]  A. K. Agarwal,et al.  Programmable autonomous micromixers and micropumps , 2005, Journal of Microelectromechanical Systems.

[18]  Günter Gauglitz,et al.  Surface plasmon resonance sensors: review , 1999 .

[19]  G G Guilbault,et al.  Recent applications of electrogenerated chemiluminescence in chemical analysis. , 2001, Talanta.

[20]  宁北芳,et al.  疟原虫var基因转换速率变化导致抗原变异[英]/Paul H, Robert P, Christodoulou Z, et al//Proc Natl Acad Sci U S A , 2005 .