High-speed pressure clamp

Stephen R. Besch; Thomas Suchyna; Frederick Sachs

doi:10.1007/s00424-002-0903-0

High-speed pressure clamp

Stephen R. Besch
, Thomas Suchyna
, Frederick Sachs

Physiology and Biophysics

SUNY Buffalo

Research output: Contribution to journal › Article › peer-review

73 Scopus citations

Abstract

We built a high-speed, pneumatic pressure clamp to stimulate patch-clamped membranes mechanically. The key control element is a newly designed differential valve that uses a single, nickel-plated piezo-electric bending element to control both pressure and vacuum. To minimize response time, the valve body was designed with minimum dead volume. The result is improved response time and stability with a threefold decrease in actuation latency. Tight valve clearances minimize the steady-state air flow, permitting us to use small resonant-piston pumps to supply pressure and vacuum. To protect the valve from water contamination in the event of a broken pipette, an optical sensor detects water entering the valve and increases pressure rapidly to clear the system. The open-loop time constant for pressure is 2.5 ms for a 100-mmHg step, and the closed-loop settling time is 500-600 μs. Valve actuation latency is 120 μs. The system performance is illustrated for mechanically induced changes in patch capacitance.

Original language	English
Pages (from-to)	161-166
Number of pages	6
Journal	Pflugers Archiv European Journal of Physiology
Volume	445
Issue number	1
DOIs	https://doi.org/10.1007/s00424-002-0903-0
State	Published - Oct 1 2002

Keywords

Mechanotransduction
Membrane capacitance
Pressure clamp
Stretch-activated channels
Techniques

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10.1007/s00424-002-0903-0

Cite this

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abstract = "We built a high-speed, pneumatic pressure clamp to stimulate patch-clamped membranes mechanically. The key control element is a newly designed differential valve that uses a single, nickel-plated piezo-electric bending element to control both pressure and vacuum. To minimize response time, the valve body was designed with minimum dead volume. The result is improved response time and stability with a threefold decrease in actuation latency. Tight valve clearances minimize the steady-state air flow, permitting us to use small resonant-piston pumps to supply pressure and vacuum. To protect the valve from water contamination in the event of a broken pipette, an optical sensor detects water entering the valve and increases pressure rapidly to clear the system. The open-loop time constant for pressure is 2.5 ms for a 100-mmHg step, and the closed-loop settling time is 500-600 μs. Valve actuation latency is 120 μs. The system performance is illustrated for mechanically induced changes in patch capacitance.",

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AU - Suchyna, Thomas

AU - Sachs, Frederick

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KW - Mechanotransduction

KW - Membrane capacitance

KW - Pressure clamp

KW - Stretch-activated channels

KW - Techniques

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High-speed pressure clamp

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Keywords

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