TY - GEN
T1 - MEMS biofluidic device concept based on a supramolecular motor
AU - Knieser, M. J.
AU - Pidaparti, R.
AU - Kadioglu, F.
AU - Harris, R. D.
AU - Knieser, M. R.
AU - Hsu, A.
PY - 2004
Y1 - 2004
N2 - The supramolecular machine, called the nuclear pore complex (NPC), controls the transport of all cellular material between the cytoplasm and the nucleus that occurs naturally in all biological cells. In the presence of appropriate chemical or geometrical stimuli, the NPC opens or closes, like a gate, and permits the flow of material into, and out of, the nucleus. Given the natural design of the nuclear pore complexes, their motor like function, and their direct engineering relevance to bio-molecular motors technology, our approach is to understand its design and mimic the supramolecular motor in an example of a biofluidic device through MEMS. A proof-of-concept based on a MEMS fluid pump will be designed and fabricated to demonstrate the applicability of the bio-inspired motor. The in Chen, D.P., Lear, J., Eisenberg, R.S.,spiration comes from the bio-inspired motor (Nuclear Pore Complex) which acts like a bi-directional pump for specific substances. While the NPC is about 200 nanometers in size, our proof-of-concept will be about 100,000 times larger in size. After fabrication of each MEMS component, process characterization, prototype evaluation and design evaluation will occur to iterate the modeling and simulation aspects of the project. The evaluations of the MEMS component will be done within a test fluid pumping environment.
AB - The supramolecular machine, called the nuclear pore complex (NPC), controls the transport of all cellular material between the cytoplasm and the nucleus that occurs naturally in all biological cells. In the presence of appropriate chemical or geometrical stimuli, the NPC opens or closes, like a gate, and permits the flow of material into, and out of, the nucleus. Given the natural design of the nuclear pore complexes, their motor like function, and their direct engineering relevance to bio-molecular motors technology, our approach is to understand its design and mimic the supramolecular motor in an example of a biofluidic device through MEMS. A proof-of-concept based on a MEMS fluid pump will be designed and fabricated to demonstrate the applicability of the bio-inspired motor. The in Chen, D.P., Lear, J., Eisenberg, R.S.,spiration comes from the bio-inspired motor (Nuclear Pore Complex) which acts like a bi-directional pump for specific substances. While the NPC is about 200 nanometers in size, our proof-of-concept will be about 100,000 times larger in size. After fabrication of each MEMS component, process characterization, prototype evaluation and design evaluation will occur to iterate the modeling and simulation aspects of the project. The evaluations of the MEMS component will be done within a test fluid pumping environment.
KW - Biofluidic
KW - MEMS
KW - Motor
KW - Supramolecular
UR - http://www.scopus.com/inward/record.url?scp=6344277187&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:6344277187
SN - 0972842276
T3 - 2004 NSTI Nanotechnology Conference and Trade Show - NSTI Nanotech 2004
SP - 118
EP - 121
BT - 2004 NSTI Nanotechnology Conference and Trade Show - NSTI Nanotech 2004
A2 - Laudon, M.
A2 - Romanowicz, B.
T2 - 2004 NSTI Nanotechnology Conference and Trade Show - NSTI Nanotech 2004
Y2 - 7 March 2004 through 11 March 2004
ER -