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Membrane Insertion of Potential Sensing Nanorods

Technology Benefits

Records membrane potential with single-particle sensitivity Can potentially record electrical signals on the nanoscale Can potentially record large number of signals with high throughput

Technology Application

Voltage nanosensors Inducing action potential Characterization of high density fast integrated circuits Energy harvesting by membrane-inserted artificial light harvesting Membrane-based hybrid materials

Detailed Technology Description

Researchers at UCLA have developed membrane voltage nanosensors that are based on inorganic semiconductor nanoparticles. These voltage nanosensors are designed to optically record the membrane potential with single-particle sensitivity. The semiconductor nanoparticles would allow for simultaneous recording of action potentials from multiple neurons in a large field-of-view over a long duration and for recording electrical signals on the nanoscale. Moreover, these sensors would have the potential to report and resolve voltage signals on the nanoscale. These high sensitivity nanosensors can be applied in the study of electrical activities in neuronal, neuromuscular, and visual systems on the nanoscale (e.g., across a single synapse) or to record a large number of signals from a large-field of view (e.g., high throughput recording).

Others

Background

Integrating inorganic nanomaterials with naturally evolved or synthetically evolved biological machineries have the potential to yield highly sophisticated hybrid nanobiomaterials that could outperform purely biological or purely inorganic materials. Such materials have been used for in vitro biosensing, intra-cellular biological imaging, single protein tracking in live cells, and in vivo molecular imaging. However, there has been limited work towards the functionalization of these nanomaterials to allow for integration into the membrane. Moreover, no attempts have allowed for the targeted insertion of rod-shaped nanoparticles into the lipid bilayer, which would be particularly useful for measuring membrane voltage.

Related Materials

K. Park, Y. Kuo, V. Shvadchak, A. Ingargiola, X. Dai, L. Hsiung, W. Kim, Z. H. Zhou, P. Zou, A. J. Levine, J. Li, and S. Weiss, Membrane insertion of—and membrane potential sensing by—semiconductor voltage nanosensors: Feasibility demonstration, Science Advances, 2018.
K. Yung, J. Li, N. Meir, X. Michalet, E. Chan, D. Oron, and S. Weiss, Optimizing the Quantum Confined Stark Effect in Nanorods for Single-Molecule Electrophysiology, arXiv preprint arXiv:1802.09170, 2018.

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• Ultrahigh Resolution Multicolor Colocalization of Single Fluoresecent Probes
• Method and Apparatus for Photon Arrival Time Interval Distribution (Paid) Analysis in Fluorescence Correlation Spectroscopy
• Bioactivation and Surface Properties Modulation of Inorganic Nanoparticles

Tech ID/UC Case

29515/2017-710-0

Related Cases

2017-710-0

*Abstract

UCLA researchers in the Department of Chemistry have developed inorganic semiconductor nanosensors that measure membrane voltage.

*Principal Investigator

Name: Sunny Chang

Department:

Name: Yung Kuo

Department:

Name: Jianqing Li

Department:

Name: KyoungWon Park

Department:

Name: Shimon Weiss

Department:

Name: Volodymyr Shvadchak

Department:

Country/Region

USA