Enhanced long-term stability for single ion channel recordings using suspended poly(lipid) bilayers

Benjamin A. Heitz; Juhua Xu; Henry K. Hall; Craig A. Aspinwall; S. Scott Saavedra

doi:10.1021/ja901442t

Enhanced long-term stability for single ion channel recordings using suspended poly(lipid) bilayers

Benjamin A. Heitz, Juhua Xu, Henry K. Hall, Craig A. Aspinwall, S. Scott Saavedra

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

27 Scopus citations

Abstract

(Figure Presented) Black lipid membranes (BLMs) are widely used for recording the activity of incorporated ion channel proteins. However, BLMs are inherently unstable structures that typically rupture within a few hours after formation. Here, stabilized BLMs were formed using the polymerizable lipid bis-dienoyl phosphatidylcholine (bis-DenPC) on glass pipettes of ∼10 μm (I.D.). After polymerization, these BLMs maintained steady conductance values for several weeks, as compared to a few hours for unpolymerized membranes. The activity of an ion channel, A-hemolysin, incorporated into bis-DenPC BLMs prior to polymerization, was maintained for 1 week after BLM formation and polymerization. These lifetimes are a substantial improvement over those achievable with conventional BLM technologies. Polymerized BLMs containing functional ion channels may represent an enabling technology for development of robust biosensors and drug screening devices.

Original language	English (US)
Pages (from-to)	6662-6663
Number of pages	2
Journal	Journal of the American Chemical Society
Volume	131
Issue number	19
DOIs	https://doi.org/10.1021/ja901442t
State	Published - May 20 2009

ASJC Scopus subject areas

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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title = "Enhanced long-term stability for single ion channel recordings using suspended poly(lipid) bilayers",

abstract = "(Figure Presented) Black lipid membranes (BLMs) are widely used for recording the activity of incorporated ion channel proteins. However, BLMs are inherently unstable structures that typically rupture within a few hours after formation. Here, stabilized BLMs were formed using the polymerizable lipid bis-dienoyl phosphatidylcholine (bis-DenPC) on glass pipettes of ∼10 μm (I.D.). After polymerization, these BLMs maintained steady conductance values for several weeks, as compared to a few hours for unpolymerized membranes. The activity of an ion channel, A-hemolysin, incorporated into bis-DenPC BLMs prior to polymerization, was maintained for 1 week after BLM formation and polymerization. These lifetimes are a substantial improvement over those achievable with conventional BLM technologies. Polymerized BLMs containing functional ion channels may represent an enabling technology for development of robust biosensors and drug screening devices.",

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T1 - Enhanced long-term stability for single ion channel recordings using suspended poly(lipid) bilayers

AU - Heitz, Benjamin A.

AU - Xu, Juhua

AU - Hall, Henry K.

AU - Aspinwall, Craig A.

AU - Saavedra, S. Scott

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Y1 - 2009/5/20

N2 - (Figure Presented) Black lipid membranes (BLMs) are widely used for recording the activity of incorporated ion channel proteins. However, BLMs are inherently unstable structures that typically rupture within a few hours after formation. Here, stabilized BLMs were formed using the polymerizable lipid bis-dienoyl phosphatidylcholine (bis-DenPC) on glass pipettes of ∼10 μm (I.D.). After polymerization, these BLMs maintained steady conductance values for several weeks, as compared to a few hours for unpolymerized membranes. The activity of an ion channel, A-hemolysin, incorporated into bis-DenPC BLMs prior to polymerization, was maintained for 1 week after BLM formation and polymerization. These lifetimes are a substantial improvement over those achievable with conventional BLM technologies. Polymerized BLMs containing functional ion channels may represent an enabling technology for development of robust biosensors and drug screening devices.

AB - (Figure Presented) Black lipid membranes (BLMs) are widely used for recording the activity of incorporated ion channel proteins. However, BLMs are inherently unstable structures that typically rupture within a few hours after formation. Here, stabilized BLMs were formed using the polymerizable lipid bis-dienoyl phosphatidylcholine (bis-DenPC) on glass pipettes of ∼10 μm (I.D.). After polymerization, these BLMs maintained steady conductance values for several weeks, as compared to a few hours for unpolymerized membranes. The activity of an ion channel, A-hemolysin, incorporated into bis-DenPC BLMs prior to polymerization, was maintained for 1 week after BLM formation and polymerization. These lifetimes are a substantial improvement over those achievable with conventional BLM technologies. Polymerized BLMs containing functional ion channels may represent an enabling technology for development of robust biosensors and drug screening devices.

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Enhanced long-term stability for single ion channel recordings using suspended poly(lipid) bilayers

Abstract

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