gramicidin-a and silicon-nitride

gramicidin-a has been researched along with silicon-nitride* in 2 studies

Other Studies

2 other study(ies) available for gramicidin-a and silicon-nitride

Article	Year
Nanopore-spanning lipid bilayers on silicon nitride membranes that seal and selectively transport ions. Langmuir : the ACS journal of surfaces and colloids, 2013, Apr-09, Volume: 29, Issue:14 We report the formation of POPC lipid bilayers that span 130 nm pores in a freestanding silicon nitride film supported on a silicon substrate. These solvent-free lipid membranes self-assemble on organosilane-treated Si3N4 via the fusion of 200 nm unilamellar vesicles. Membrane fluidity is verified by fluorescence recovery after photobleaching (FRAP), and membrane resistance in excess of 1 GΩ is demonstrated using electrical impedance spectroscopy (EIS). An array of 40,000 membranes maintained high impedance over 72 h, followed by rupture of most of the membranes by 82 h. Membrane incorporation of gramicidin, a model ion channel, resulted in increased membrane conductance. This membrane conductance was diminished when the gramicidin channels were blocked with CaCl2, indicating that the change in membrane conductance results from gramicidin-mediated ion transport. These very stable, biologically functional pore-spanning membranes open many possibilities for silicon-based ion-channel devices for applications such as biosensors and high-throughput drug screening. Topics: Biological Transport; Cell Membrane; Gramicidin; Ions; Lipid Bilayers; Nanopores; Silicon; Silicon Compounds; Surface Properties	2013
Free-standing lipid bilayers in silicon chips-membrane stabilization based on microfabricated apertures with a nanometer-scale smoothness. Langmuir : the ACS journal of surfaces and colloids, 2010, Feb-02, Volume: 26, Issue:3 In the present study, we propose a method for preparing stable free-standing bilayer lipid membranes (BLMs). The BLMs were prepared in a microfabricated aperture with a smoothly tapered edge, which was prepared in a nanometer-thick Si(3)N(4) septum by the wet etching method. Owing to this structure, the stress on lipid bilayers at the contact with the septum was minimized, leading to remarkable membrane stability. The BLMs were not broken by applying a constant voltage of +/-1 V. The membrane lifetime was 15-45 h with and without an incorporated gramicidin channel. Gramicidin single-channel currents were recorded from the same BLM preparation when the aqueous solutions surrounding the BLM were repeatedly exchanged, demonstrating the tolerance of the present BLM to repetitive solution exchanges. Such stable membranes enable analysis of channel functions under various solution conditions from the same BLM, which will open up a variety of applications including a high throughput drug screening for ion channels. Topics: Cell Membrane; Electric Conductivity; Gramicidin; Ion Channels; Lipid Bilayers; Microscopy, Electron, Scanning; Microtechnology; Nanostructures; Silicon Compounds; Solvents	2010

Article

Year

Nanopore-spanning lipid bilayers on silicon nitride membranes that seal and selectively transport ions.

Langmuir : the ACS journal of surfaces and colloids, 2013, Apr-09, Volume: 29, Issue:14

We report the formation of POPC lipid bilayers that span 130 nm pores in a freestanding silicon nitride film supported on a silicon substrate. These solvent-free lipid membranes self-assemble on organosilane-treated Si3N4 via the fusion of 200 nm unilamellar vesicles. Membrane fluidity is verified by fluorescence recovery after photobleaching (FRAP), and membrane resistance in excess of 1 GΩ is demonstrated using electrical impedance spectroscopy (EIS). An array of 40,000 membranes maintained high impedance over 72 h, followed by rupture of most of the membranes by 82 h. Membrane incorporation of gramicidin, a model ion channel, resulted in increased membrane conductance. This membrane conductance was diminished when the gramicidin channels were blocked with CaCl2, indicating that the change in membrane conductance results from gramicidin-mediated ion transport. These very stable, biologically functional pore-spanning membranes open many possibilities for silicon-based ion-channel devices for applications such as biosensors and high-throughput drug screening.

Topics: Biological Transport; Cell Membrane; Gramicidin; Ions; Lipid Bilayers; Nanopores; Silicon; Silicon Compounds; Surface Properties

2013

Free-standing lipid bilayers in silicon chips-membrane stabilization based on microfabricated apertures with a nanometer-scale smoothness.

Langmuir : the ACS journal of surfaces and colloids, 2010, Feb-02, Volume: 26, Issue:3

In the present study, we propose a method for preparing stable free-standing bilayer lipid membranes (BLMs). The BLMs were prepared in a microfabricated aperture with a smoothly tapered edge, which was prepared in a nanometer-thick Si(3)N(4) septum by the wet etching method. Owing to this structure, the stress on lipid bilayers at the contact with the septum was minimized, leading to remarkable membrane stability. The BLMs were not broken by applying a constant voltage of +/-1 V. The membrane lifetime was 15-45 h with and without an incorporated gramicidin channel. Gramicidin single-channel currents were recorded from the same BLM preparation when the aqueous solutions surrounding the BLM were repeatedly exchanged, demonstrating the tolerance of the present BLM to repetitive solution exchanges. Such stable membranes enable analysis of channel functions under various solution conditions from the same BLM, which will open up a variety of applications including a high throughput drug screening for ion channels.

Topics: Cell Membrane; Electric Conductivity; Gramicidin; Ion Channels; Lipid Bilayers; Microscopy, Electron, Scanning; Microtechnology; Nanostructures; Silicon Compounds; Solvents

2010