Title :
High-speed solution switching using piezo-based micropositioning stages
Author :
Stilson, Shane ; McClellan, Annette ; Devasia, Santosh
Author_Institution :
Dept. of Mech. Eng., Utah Univ., Salt Lake City, UT, USA
fDate :
7/1/2001 12:00:00 AM
Abstract :
Motion-induced vibration is a critical limitation in high-speed micropositioning stages used to achieve solution switching. Controlled rapid solution switching is used to study the fast activation and deactivation kinetics of ligand-gated ion-channel populations isolated in excised membrane patches-such studies are needed to understand fundamental mechanisms that mediate synaptic elicitation and inhibition in the central nervous system. However, as the solution-switching speed is increased, vibration induced in the piezo-based positioning stages can result in undesired, repeated, ligand application to the excised patch. The article describes a method to use knowledge of the piezo-stage´s vibrational dynamics to compensate for and reduce these unwanted vibrations. The method was experimentally verified using an open-electrode technique, and fast solution switching (100 μs range) was achieved.
Keywords :
biological techniques; biomembrane transport; micropositioning; neurophysiology; piezoelectric actuators; switching; 100 mus; biological research instrumentation; central nervous system; excised membrane patches; high-speed solution switching; induced vibration; ligand-gated ion-channel populations kinetics; piezo-based micropositioning stages; piezo-based positioning stages; receptor kinetics; synaptic elicitation; synaptic inhibition; unwanted vibrations reduction; Biomembranes; Central nervous system; Centralized control; Cities and towns; Drugs; Kinetic theory; Mechanical engineering; Neurotransmitters; Proteins; Vibrations; Models, Neurological; Patch-Clamp Techniques; Signal Processing, Computer-Assisted; Vibration;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
